Methods and compositions of nucleic acid ligands for detection of foodborne and waterborne pathogens
US20160258948A9
2016-09-08
13/136,820
2011-08-11
✅ Patent granted
US 9,562,900 B2
2017-02-07
-
-
Robert A Zeman
William H. Quirk | Jesse L. Frizzell | Rosenthal Pauerstein Sandoloski Agather LLP
2032-11-11
Abstract:
Specific DNA sequences for binding various foodborne and waterborne pathogens and biotoxins are described. Each of these sequences can function in varying assay and sensor formats with varying degrees of success.
Inventors:
- John G. Bruno 18 🇺🇸 San Antonio, TX, United States
- John G. Bruno 1 🇺🇸 Boerne, TX, United States
Assignee:
- OTC BIOTECHNOLOGIES, LLC 5 🇺🇸 San Antonio, TX, United States
Applicant:
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Classification:
G01N33/56922 » CPC further
Investigating or analysing materials by specific methods not covered by groups -; Biological material, e.g. blood, urine ; Haemocytometers; Chemical analysis of biological material, e.g. blood, urine; Testing involving biospecific ligand binding methods; Immunological testing; Immunoassay; Biospecific binding assay; Materials therefor for microorganisms, e.g. protozoa, bacteria, viruses; Bacteria Campylobacter
G01N33/569 IPC
Investigating or analysing materials by specific methods not covered by groups -; Biological material, e.g. blood, urine ; Haemocytometers; Chemical analysis of biological material, e.g. blood, urine; Testing involving biospecific ligand binding methods; Immunological testing; Immunoassay; Biospecific binding assay; Materials therefor for microorganisms, e.g. protozoa, bacteria, viruses
C12Q1/689 » CPC further
Measuring or testing processes involving enzymes, nucleic acids or microorganisms ; Compositions therefor; Processes of preparing such compositions involving nucleic acids; Nucleic acid products used in the analysis of nucleic acids, e.g. primers or probes for detection or identification of organisms for bacteria
C12N2310/16 » CPC further
Structure or type of the nucleic acid; Type of nucleic acid Aptamers
C07H21/04 IPC
Compounds containing two or more mononucleotide units having separate phosphate or polyphosphate groups linked by saccharide radicals of nucleoside groups, e.g. nucleic acids with deoxyribosyl as saccharide radical
C12N15/115 » CPC further
Mutation or genetic engineering; DNA or RNA concerning genetic engineering, vectors, e.g. plasmids, or their isolation, preparation or purification; Use of hosts therefor; Recombinant DNA-technology; DNA or RNA fragments; Modified forms thereof Aptamers, i.e. nucleic acids binding a target molecule specifically and with high affinity without hybridising therewith ; Nucleic acids binding to non-nucleic acids, e.g. aptamers
G01N33/56916 » CPC main
Investigating or analysing materials by specific methods not covered by groups -; Biological material, e.g. blood, urine ; Haemocytometers; Chemical analysis of biological material, e.g. blood, urine; Testing involving biospecific ligand binding methods; Immunological testing; Immunoassay; Biospecific binding assay; Materials therefor for microorganisms, e.g. protozoa, bacteria, viruses; Bacteria Enterobacteria, e.g. shigella, salmonella, klebsiella, serratia
C12Q1/68 IPC
Measuring or testing processes involving enzymes, nucleic acids or microorganisms ; Compositions therefor; Processes of preparing such compositions involving nucleic acids
Description
PRIORITY INFORMATION
This application is based upon and claims priority from U.S. Provisional application Ser. No. 61/372,649 filed on Aug. 11, 2010, which is incorporated herein by reference.
BACKGROUND OF THE INVENTION
1. Field of the Invention
The present invention pertains to the field of aptamer- and nucleic acid ligand (DNA and RNA ligand)-based diagnostics. More particularly, it relates to single-stranded Deoxyribonucleic acid (“DNA”) and Ribonucleic acid (“RNA”) ligand sequences, whether individual or linked together to form longer multiple binding site “receptors,” that specifically target and bind to foodborne and waterborne pathogenic bacteria or parasites such as Campylobacter jejuni, pathogenic Escherichia coli, Listeria monocytogenes, Salmonella enterica serovar Typhimurium (formerly S. typhimurium), molds or other pathogenic fungi, Cryptosporidium and Giardia parasites and related toxins produced by some bacteria (e.g., Shiga or Vero toxins) and other virulence factors (intimins, adhesions, capsules, etc.) indicating the presence of the pathogens.
These individual or linked DNA ligand (aptamer) sequences represent valuable target analyte-responsive components of diagnostic devices or biosensors. A biosensor can be defined as any device that employs a biologically-derived molecule as the sensing component and transduces a target analyte binding event into a detectable physical signal (including, but not limited to, changes in light intensity, absorbance, emission, wavelength, color, electrical conduction, electrical resistance, or other electrical properties, etc). Once bonded with the target, these DNA ligand sequences can be used to qualitatively determine the presence of target analyte, as well as to quantify the target analyte amount, in a sample using a broad variety of assay types and diagnostic or sensor platforms including, but not limited to, affinity-based lateral flow test strips, membrane blotting, surface plasmon resonance (“SPR”), magnetic bead (“MB”)-based capture, plastic-adherent sandwich assays (“PASA”), chemiluminescence (“CL”), electrochemiluminescence (“ECL”), radioisotopic, fluorescence intensity, including quantum dot (“QD”) or other fluorescent nanoparticle (“FNP”) of dye-based, fluorescence lifetime, and fluorescence polarization (“FP”) assays or enzyme-linked (ELISA-like) microplate assays. ELISA-like assays refer to microwell or microplate assays similar to traditional “Enzyme-Linked Immunosorbent Assays” or “ELISA” in which an aptamer or nucleic acid ligand is substituted for the antibody component or components, but the other components such as peroxidase or alkaline phosphatase enzymes and color-producing substrates remain the same.
In addition, these DNA ligand sequences are valuable in competitive displacement assays which are not solely dependent on high affinity (strong attractive forces between a receptor and its ligand) or high avidity (high tensile or physical strength of receptor-ligand bonds) to produce sensitive detection (sub-nanoMolar or sub-nanogram levels), because the equilibrium constant (generally Ka=106 to 108 to enable competition) must allow reasonable displacement of previously bound target materials to detect a change at or below nanogram or nanoMolar levels. In a competitive displacement assay, labeled DNA ligand plus labeled analyte complexes compete with unlabeled analyte to bind with the labeled DNA. After allowing the labeled and unlabeled analytes to come to equilibrium with the labeled DNA, the unlabeled target analyte may be quantitatively assayed by fluorescence intensity or other methods. Such assays would include competitive displacement fluorescence resonance energy transfer (“FRET”) assays or DNA ligand “beacon” FRET assays. Each of these types of assays and detection platforms has different applications in either central laboratories or as portable detectors to identify tainted foods and water either in the field (e.g. on farms or in water supplies) or in the food processing chain progressing toward the human or animal consumer.
2. Background Information
The DNA ligand sequences listed in Table 1 herein were derived by iterative cycles of affinity-based selection, washing, heated elution, and polymerase chain reaction (“PCR”) amplification of bound DNA ligands from a randomized library using immobilized target analytes for affinity selection and PCR amplification followed by cloning and Sanger dideoxynucleotide DNA sequencing. Sanger dideoxynucleotide sequencing refers to DNA chain termination due to lack of a 3′-OH to link incoming bases with during DNA synthesis followed by automated fluorescence reading of the DNA sequence from an electrophoresis gel containing all of the terminated DNA fragments. DNA sequencing may be accomplished by PCR doped with dideoxynucleotides lacking hydroxyl groups at the 2′ and 3′ sugar ring positions and thereby disallowing chain formation. PCR refers to the enzymatic amplification or copying of DNA molecules with a thermo-stable DNA polymerase such as Thermus aquaticus polymerase (“Taq”) with known “primer” regions or short oligonucleotides of known sequence that can hybridize to a longer target DNA sequence to enable priming of the chain reaction (exponential doubling of the DNA target copy number with each round of amplification). A randomized library can be chemically synthesized by linking together the four deoxynucleotide triphosphate bases (adenine; A, cytosine; C, guanine; G, and thymine; T) in equal amounts (25% each), so that a combinatorial oligonucleotide arises with sequence diversity equal to 4 raised to the nth power (4n) where n is the desired length of the randomized region in bases. In other words, if position 1 in an oligonucleotide is allowed to consist of A, C, G, or T (diversity=4) by equal availability of all 4 bases and these 4 possibilities are multiplied by each base linking to 4 more possible bases at position 2, then this process yields 16 possible 2-base oligonucleotides (i.e., AA, AC, AG, AT, CA, CC, CG, CT, GA, GC, GG, GT, TA, TC, TG, TT) and so on for the entire chosen length (n) of the randomized region. This combinatorial progression displays immense diversity as a function of oligonucleotide chain length. For example, an oligonucleotide decamer of 10 base length could be expected to contain 4n=410 or 1,048,576 unique DNA sequences from which to chose or select by affinity one or more sequences that bind a given immobilized target analyte. The randomized oligonucleotide or DNA is designed to be flanked on either side by short primer regions of known and fixed sequences to enable PCR amplification (exponential copying) of the rare sequences that are selected from the random library by binding to the target after the non-binding members of the random library are washed away (not selected).
Additional assays, such as ELISA-like plate assays or fluorescence (intensity and FRET) assays, may be used to screen or verify the value of particular DNA and RNA ligands or aptamer sequences for detection of a given target analyte in a given assay format or type of biosensor. Some of the sequences operate (bind and transduce the binding signal) more effectively in affinity-based (ELISA-like or fluorescence intensity) assays, while other DNA ligand sequences against the same targets function better in competitive or other assays, thereby leading to more sensitive detection with lower limits of detection (sub-nanoMolar or sub-nanogram) and less cross-reactivity or more specificity for the target analyte. Specificity means the ability to selectively exclude molecules similar in structure to the true target analyte that may interfere with the assay and give false readings. All of the listed DNA ligand nucleotide sequences have potential applications in some type of assay format, because they have survived at least 5 rounds of affinity-based selection and enrichment (by PCR amplification), although some of the sequences will undoubtedly perform better in certain assay formats or configurations (in tubes, square cuvettes, membranes, or on biochips) than others.
Combinations of the DNA ligands whether in whole or in part (i.e., their binding sites of 5-10 or more nucleotides or bases) could be linked together in a linear or 2-dimensional or 3-dimensional fashion similar to dendrimers to bind multiple epitopes or binding sites on a complex target analyte (Ag or antigen). The advantage of linking aptamers or their shorter binding pockets, loops or binding sites is that the nascent linear, 2-D or 3-D aptamer construct will likely have improved affinity or “avidity” (tensile binding strength) making it more difficult to remove or dissociate from the target antigen. The linked aptamer complex will be likely to gain specificity as well since the probability of binding to multiple epitopes with any degree of success is multiplicative. Thus, the ability to bind to epitopes A, B and C equals the product of the probability of binding to A with high affinity times the probability of binding to B with high affinity times the probability of binding to C with high affinity and that probability is clearly much less than binding to only A, B, or C or any combination of the two epitopes therein. In this way, the specificity of aptamers or DNA ligands can be increased. This approach to binding site linkage emulates that of nature in that antibodies demonstrate linkage of their “hypervariable” (HV) regions on the antigen combining sites of the immunoglobulin light and heavy chains. In the HV regions, the variability of the 20 amino acid types is quite high and essentially represents a selection of one combination from a large combinatorial library in the protein realm. The trait of HV region linkage contributes to antibody affinity, avidity and specificity. Similarly, linking aptamers or aptamer binding sites for various epitopes in one, two or three dimensions will enhance larger aptamer or DNA ligand construct affinity, avidity, and selectivity or specificity.
All of the listed DNA ligand nucleotide sequences have potential utility in some assay format, although some of the candidate sequences will perform better in certain assay formats or configurations (in tubes, cuvettes, membranes, or on biochips) than others. Assays such as ELISA-like plate assays or fluorescence (intensity and FRET) assays, may be used to verify the utility of the DNA ligand sequences. Some of the sequences function more effectively in affinity-based (ELISA-like or fluorescence intensity) assays, while other DNA ligand sequences against the same bacterial targets or analytes function better in competitive FRET assays.
SUMMARY OF THE INVENTION
The present invention provides specific DNA sequence information as shown in Table 1 for nucleic acid ligands selected from randomized pools to bind targeted foodborne and waterborne pathogenic bacteria and toxins, which can be put into a composition useful in a variety of assay formats and sensor or diagnostic platforms to detect or quantify the targeted bacteria or toxin. While all of the candidate sequences have been shown to bind their cognate targets, some are shown to function more effectively in affinity-based assays versus fluorescence resonance energy transfer (FRET) or other assay formats that rely more on physical parameters other than affinity such as fluorophore-quencher proximity (i.e., the Förster distance). Therefore, all of the sequences are potentially valuable for detection or quantitative assays, but some may function better than others in particular assay formats.
BRIEF DESCRIPTION OF THE DRAWINGS
FIG. 1 is a graph and table comparing the FRET responses of specific DNA ligands.
FIG. 2 shows the secondary structures of two DNA ligands which both bind E. coli strain ATCC 8739, but only one loop structure in the EcO 4R DNA ligand (SEQ ID No. 88) yielded competitive FRET as illustrated by the fluorescence spectra.
FIG. 3 is a graph plotting relative fluorescence intensity against the concentration of Campylobacter jejuni bacteria detected in chicken juice by plastic-adherent DNA sandwich assay.
FIG. 4 shows graphs demonstrating detection of Salmonella enterica ATCC strain 13311 by plastic-adherent DNA sandwich assay.
FIG. 5 shows graphs demonstrating detection of Shiga toxin type 1 by plastic-adherent DNA sandwich assay.
DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS
There is no single preferred embodiment for use of the DNA aptamer ligand sequences or linked aptamer constructs identified herein. Rather, the sequences are useful to varying extents in a variety of assay formats and sensors or diagnostic devices chosen from at least the following list: lateral flow test strips, ELISA-like or enzyme-linked microplate assays, magnetic bead-based capture assays, ECL or other chemiluminescence assays, radioisotopic assays and a variety of fluorescence assays including, but not limited to, fluorescence intensity, fluorescence lifetime, FP assays, and FRET assays (both beacon and competitive FRET in round tubes, square or flat cuvettes, or immobilized on magnetic beads, other types of microbeads, or flat surfaces such as nitrocellulose, nylon, or other membranes or on glass or plastic DNA microarrays or “biochips.”
While there may appear to be considerable variability among sequences that bind the same clinical analyte targets, “epitopes” or binding sites are usually quite small (e.g., 5-10 bases) and a single target may contain numerous individual binding sites or epitopes for multiple aptamer binding. In addition, however, there is often a common or consensus sequence or common segments of 5-10 or more nucleotides in a row within otherwise different aptamer sequences that can bind a specific target epitope that may dominate the other binding sites by being more physically accessible or having stronger electrostatic, hydrogen bonding, or other attractive forces (summation of van der Waals or other weak forces). Variations in nucleotide sequences around these consensus segments or common binding sequence segments may serve to modulate the binding segment's affinity or specificity or may have no effect at all.
DNA Ligand (Aptamer) Selection and Generation
General methods for developing DNA ligands or aptamers to the immobilized proteins, peptides, or small molecules (defined as less than 1,000 Daltons) are as follows. The protein, peptide or an amino-derivative of the small molecule (such as glucosamine in the case of D-glucose or dextrose) is then added to 2×109 tosyl-coated magnetic beads (MBs; e.g., Dynal brand from Invitrogen Corp. Carlsbad, Calif., 2.8 micron size) for 2 hours at 37° C. The tosyl group is a “leaving” group that allows the formation of a very stable covalent bond between primary amine groups in the target protein, peptide or amino-derivatized small molecule and therefore immobilizes the target on the surfaces of the MBs so that they can be used to probe the randomized DNA library for DNA ligands. Target molecule-conjugated MBs (or target-MBs) are collected for 2 minutes in a magnetic collection device using an external magnet and the supernate is carefully withdrawn with a pipette tip. Target-MBs are then resuspended by vortexing briefly in 1× Binding Buffer (1XBB; 0.5M NaCl, 10 mM Tris-HCl, and 1 mM MgCl2, pH 7.5-7.6) and washed by agitation for 5 minutes. MBs are collected and washed three times in this manner and then resuspended in 1 ml of 1XBB.
MB-based DNA ligand or aptamer development is then performed using a template library sequence such as: 5′-ATCCGTCACACCTGCTCT-N36-TGGTGTTGGCTCCCGTAT-3′, where N36 represents the randomized 36-base region of the DNA library (maximal sequence diversity=436 in theory). Primer sequences are: 5′-ATACGGGAGCCAACACCA-3′ (designated forward) and 5′-ATCCGTCACACCTGCTCT-3′ (designated reverse) to prime the template and nascent strands for PCR, respectively. The random library is reconstituted in 500 μl of sterile nuclease-free water and heated to 95° C. for 5 minutes to ensure that the DNA library is completely single-stranded and linear. The hot DNA library solution is added to 100 μl of target-MBs (2×108 beads) with 600 μl of sterile 2× Binding Buffer (2XBB). The DNA library and target-MB suspension (1.2 ml) is mixed at room temperature (RT, approximately 25° C.) for 1 hour. Target-MBs with any bound DNA (round 1 aptamers) are magnetically collected. The DNA-target-MB complexes are washed three times in 400 μl of sterile 1 XBB. Following the third wash, the DNA-target-MB pellet (about 75 μl) is used in a PCR reaction to amplify the bound DNA as follows. The MB pellet is split into 15 μl aliquots and added to five pre-made PCR tubes which contain most of the nonperishable ingredients of a PCR reaction beneath a wax seal. A total of 3 μl of 1:10 primer mix (10% forward primer plus 10% reverse primer) in nuclease-free deionized water or ˜20 nanomoles of each primer per ml plus 1 μl (5 U) of Taq DNA polymerase and 5 μl of 2 mM MgCl2 are added to each of the five tubes. PCR reactions are supplemented with 0.5 μl of E. coli single-strand binding protein (SSBP, Stratagene Inc., La Jolla, Calif.) to inhibit high molecular weight concatamer (end to end aggregates of the DNA ligands) formation. PCR is carried out as follows: an initial 95° C. phase for 5 minutes, followed by 20 cycles of 1 minute at 95° C., 1 minute at 53° C., and 1 minute at 72° C. followed by a 72° C. completion stage for 7 minute, and refrigeration at 4° C. This constitutes the first of multiple rounds of MB-atpamer development. Iterations of the MB-aptamer development process are repeated until the desired affinity or assay sensitivity and specificity are achieved. Typically, 5-10 rounds of the MB-aptamer development process are required to achieve low ng/ml detection of target analytes. To begin the second round and all subsequent rounds, 4 complete tubes of the 5 original PCR tubes are heated to 95° C. for 5 minutes to release bound DNA from the target-MBs. The fifth tube is always retained and refrigerated as a back-up for that round of the aptamer generation process. All available DNA (25 μl per tube) is siphoned out of the hot tubes without removing the target-MBs before the tubes cool significantly and the DNA is pooled. The 100 μl of hot DNA is added to 100 μl of fresh target-MBs in 200 μl of 2XBB and allowed to mix for 1 hr at RT. Thereafter, the selection and amplification process are repeated for 3-8 more rounds with checking for 72 bp aptamer PCR products by ethidium bromide-stained 2% agarose electrophoresis after each round. Following the last round of aptamer development, aptamers are cloned into chemically competent E. coli and are sequenced.
Screening of Aptamers for Highest Affinity, Lowest Cross-Reactivity and to Determine Lower Limit of Detection by Target Titration in ELISA-like Plate Assay (“ELASA”)
To evaluate, screen, and rank aptamers based on affinity against clinically relevant targets, an enzyme-linked plate assay is conducted by first immobilizing 100 μl of 1:10 diluted target (about 0.1 mg of total protein, peptide or small molecule) in 0.1M NaHCO3 (pH 8.5) overnight at 4° C. in a covered polystyrene 96-well plate. The plate is decanted and washed three times in 250 μl of 1XBB. Each of the different 5′-biotinylated aptamers raised against the target is dissolved in 1XBB at 1.00 nmoles to 4.50 nmoles per 100 microliters and applied to their corresponding plate wells for 1 hour at room temperature (RT; ˜25° C.) with gentle mixing on an orbital shaker. The plate is decanted and washed three times in 250 μl of 1XBB for at least 5 minutes per wash with gentle mixing. One hundred μl of a 1:2,000 dilution of streptavidin-peroxidase from a 5 mg/ml stock solution in 1XBB is added per well for 30 minutes at RT with gentle mixing. The plate is decanted and washed three times with 250 μl of 1XBB per well as before. One hundred μl of ABTS (2,2′-azino-bis(3-ethylbenzthiazoline-6-sulphonic acid) substrate with stabilized hydrogen peroxide is added per well for 10 minute at room temperature. Finally absorbance is quantified using a microplate reader with 405 nm optical filter.
Aptamer Beacons and Competitive FRET-Aptamer Assays
Once key aptamers have been identified by the commonality of their sequences or their secondary stem-loop structures, the assay developer decides upon secondary structure loops (potential binding pockets) to label with an F or Q. Secondary stem-loop structures are generated by Gibbs free energy minimization with common software. At this point, one can assess aptamer “beacon” potential in FRET analyte titration experiments. The suspected short aptamer beacon loop is synthesized again with a fluorophore (F) such as TYE 665 attached to the 5′ end and quencher (Q) such as Iowa Black attached to the 3′ end (or vice versa), purified by HPLC or other form of chromatography and assessed for fluorescence output or intensity as a function of different levels of the target analyte.
Alternatively, one may label the suspected binding loops internally and place an F or a Q somewhere in the mid-section of the suspected loop other than the 3′ or 5′ end (i.e., intrachain FRET). Attachment of F or Q is usually accomplished via succinimide linkage of F- or Q-succinimides added to amino-modified aptamers at specifically chosen locations in the binding pockets. Primary amine linker moieties, such as UniLink™, can be added internally at the time of chemical synthesis of aptamers. Typically 1 mg or more of an aptamer sequence is synthesized with a primary amine linker moiety located at the approximate center of each loop structure (suspected binding pockets). Each of these internally amine-labeled aptamers is then labeled with 100 μl (0.1 mg) of F-succinimide (or alternatively Q-succinimide) for 2 hours in a 37° C. incubator, followed by purification through a 1XBB-equilibrated PD-10 (Sephadex G-25; GE Healthcare) column. In the meantime, an equal molar amount of amino-modified target molecule is labeled with 0.1 mg of spectrally matched Q-succinimide (to accept photons from F) at 37° C. for 2 hours and then washed three times by centrifugation at 14,000 rpm for 10 minutes per wash and resuspension in 1 ml of 1XBB. “Spectrally matched” means that most of the wavelengths of light emitted by F can be effectively absorbed by Q because its absorbance spectrum largely overlaps the emission spectrum of F. Naturally, if the aptamer is labeled with a Q-succinimide in the alternate form of the assay, the amino-target must be labeled with an appropriately matched F-succinimide to be quenched when bound to the Q-labeled aptamer. Pooled one ml fractions of purified F-labeled DNA aptamers are mixed with an equimolar amount of Q-labeled-amino-target analyte (or vice versa in the alternate embodiment) for 30 minutes at RT with mixing in 1 XBB and then purified through an appropriate size-exclusion chromatography column (according to molecular weight of the combined F-aptamer plus Q-target complex) to produce a “FRET complex” consisting of bound F-aptamer plus Q-labeled target.
Generally, the aptamer beacons or FRET-aptamer complexes are then diluted to a final concentration of 1-5 μg/ml in 1XBB and equally dispensed to polystyrene or methacrylate cuvettes in which 1 ml of unlabeled target at various concentrations in 1 XBB or diluted blood, plama, serum, saliva, aspirate or urine has been added already. Cuvettes are gently mixed for 15 to 20 minutes at RT prior to reading their fluorescence in the homogeneous beacon or competitive-displacement FRET assay formats using a spectrofluorometer having gratings to vary the excitation wavelength and emission scanning ability or handheld or otherwise portable fluorometer having a more restricted or fixed excitation and emission optical filter set with a range of wavelengths for excitation and emission.
Aptamer or Aptamer Binding Site Linkage in One or More Dimensions
The linkage of binding sites is beneficial in terms of enhancing receptor affinity, avidity (tensile binding strength), and selectivity versus complex targets with two or more distinct epitopes. This linkage can be sequential and linear (one-dimensional as in antibody heavy and light chain linkage of HV regions) or could be expanded into two or three dimensions much like DNA dendrimers or other more complex structures known to those skilled in the art. Linear linkage by chemical synthesis is quite facile, if one knows that aptamer DNA sequences or shorter (5-10 base) binding site sequences to be linked. One long sequence can be designed to incorporate the desired aptamers or binding sites with repetitive poly-adenine, poly-cytosine, poly-guanine, poly-thymine, poly-uridine, or other intervening sequences that are unlikely to bind the target. The length of the composite aptamer construct will be limited to about 200 bases by current chemical synthesis technology. However, biosynthesis or enzymatic synthesis by PCR or asymmetric PCR (producing predominately single-stranded DNA from a template) would not be so limited and should produce aptamer constructs up to 2,000 bases before the Taq polymerase falls off the template. In this way, very lengthy 2 kilobase aptamer constructs could be made from complementary DNA templates that would enable binding of different epitopes that are distal on the surface of relatively large objects such as whole bacterial or eukaryotic cells. Again, poly-A, C, G, T, or U or other linker nucleotide segments could be designed into the cDNA template and the resultant nascent strand to ligate aptamers or aptamer binding sites together into one contiguous linear chain.
For 2-D or 3-D linked aptamer structures a variety of linker chemistries are available, but the preferred embodiment is probably addition of a primary amine group somewhere in the mid-section of a larger multi-aptamer construct followed by covalent linkage of two or more such mulit-aptamer constructs by means of bifunctional linkers such as low levels (≦1%) glutaraldehyde, carbodiimides, sulfo-EGS, sulfo-SMCC or other such bifunctional linkers familiar to those skilled in conjugate chemistry.
Referring to the figures, FIG. 1 is a comparison of ELISA-like affinity-based and competitive FRET assays using the same DNA ligands. It provides a graphical comparison of the same selected family of DNA ligands that bind E. coli OMPs in an ELISA-like affinity-based plate assay (data table in FIG. 1) with competitive FRET response spectra for the same population of DNA ligand sequences. It further is an illustration of how anti-E. coli OMP DNA ligands are useful in an ELISA-like assay format (tabled absorbance values) and how some candidate DNA ligand sequences show greater affinity than others (i.e., have higher absorbance values approaching 1.9) for the Crook's strain (ATCC 8739) of E. coli. The figure also demonstrates that some DNA ligand sequences with generally lower affinities (some of the shaded boxes in FIG. 1) from the same population yield a greater competitive FRET response to E. coli 8739 (i.e., are more useful in a FRET assay format, but not as useful for affinity-based assays like ELISA). The boxed values in the table of FIG. 1 show all of the highest affinity DNA ligand sequences or wells with absorbance values greater than 1.5. The shaded values indicate wells with the greatest competitive FRET responses (wells A8, A10, B2, B8, C12, and D6). It is clear from FIG. 1 that only two of the highest affinity DNA ligands in wells D6 and C12 also gave strong FRET responses, thereby illustrating the varied utility of different members of the same general DNA ligand family that binds E. coli OMPs.
FIG. 2 shows the secondary structures of two DNA ligands (as determined by Vienna RNA free energy minimization software using DNA mathematical parameters at room temperature (25° C.)) shown to bind the OMPs of E. coli strain ATCC 8739 with moderate to high affinity by ELISA-like assay. However, only the loop or binding pocket of the DNA ligand designated EcO 4R (SEQ ID No. 88) was useful for competitive FRET as illustrated by the fluorescence spectra at the bottom of the figure when AlexaFluor 647-succinimide is used to label the putative binding pocket via a UniLink™ amine linker between bases 42 and 43 (numbered from the 5′ end) and the fluorophore-labeled EcO 4R DNA molecules is bound to Black Hole Quencher (BHQ)-3-succinimide labeled E. coli ATCC 8739 and competed against decreasing levels or concentrations of unlabeled E. coli ATCC 8739 in neat buffer. None of the other loop structures in EcO 4R or EcO 5R (SEQ ID No. 90) DNA ligands were capable of producing a FRET response in this competitive FRET format.
FIG. 3 graphically illustrates an ultrasensitive detection of Campylobacter jejuni by a plastic-adherent sandwich assay. The graph plots relative fluorescence intensity against the concentration of the targeted, Campylobacter jejuni, bacteria detected in chicken juice down to a level of approximately 10 bacterial cells using a one-step plastic-adherent DNA ligand-MB/DNA ligand red QD (Q-dot 655 nm) sandwich assay. Five independent readings were taken per data point with the green (Rhodamine) channel of a fluorometer. The DNA ligand sequences may be used to detect as few as 2 live or dead C. jejuni bacterial cells (a well-known foodborne pathogen) in neat buffer and various food matrices including diluted whole milk and poultry rinsate.
In this assay, two different C. jejuni sequences (C2 and C3) from the SEQ ID NO's 1-6 were 5′-amine modified upon synthesis and attached to either 1,000 tosyl-M280 (2.8 micron diameter) Dynal (Invitrogen, Inc.) MB's or 0.24 picoliters of Q-dot 655 ITK reagent (Invitrogen, Inc.) per test. The C2 DNA ligand was used for capture on the surface of tosyl-MB's and the C3 DNA ligand was used as the reporter reagent after attachment to the Q-dot 655 ITK reagent via BS3 (bis-suberate bifunctional linker from Pierce Chemical Co.). The reagents were purified, mixed together and lyophilized in plastic cuvettes. The powered assays were later back-flushed with nitrogen and capped. Upon rehydration, the adherent one-step sandwich assays were used to detect live or dead C. jejuni cells with the very sensitive results depicted in FIG. 2 in chicken juice.
FIG. 4 demonstrates sensitive detection of the targeted Salmonella species by plastic-adherent sandwich assay in the range of 10 to 1,000 bacteria per mL. The graphs show the detection of Salmonella enterica ATCC strain 13311 in two separate trials using specific DNA ligands in a plastic-adherent DNA ligand-MB plus DNA ligand-QD dot sandwich assay format in neat buffer The particular high affinity DNA ligand sequence used for MB conjugate formation and capture was Sal 4/14R and the DNA ligand used for QD coupling and reporting was designated Sal 19F and selected from SEQ ID NO's 81-218. However, other DNA ligands from the same family give similar affinity-based results and may be useful for detection of different species or strains of Salmonella.
FIG. 5 demonstrates the ultrasensitive detection of E. coli Shiga toxins by plastic-adherent sandwich assay. The graphs show the detection of Shiga toxin type 1. from two separate trials using specific DNA ligands in a plastic-adherent DNA ligand-magnetic bead plus DNA ligand quantum dot sandwich assay format. Using the plastic-adherent aptamer-MB plus aptamer-QD conjugate sandwich assay described in FIGS. 3 and 4, similar ultrasensitive detection of Shiga or Shiga-like toxin 1 to a level of 10 ng per mL was achieved in neat buffer as shown in FIG. 5. The particular high affinity DNA ligand sequence used for MB conjugate formation and capture was Shiga 8/21F in one trial and 16F in the other and the DNA ligand used for QD coupling and reporting was designated Shiga 16F in both cases. All three of these DNA ligand sequences were selected from SEQ ID NO's 544-574. However, other DNA ligands from the same family give similar results and may be useful for detection of different species or strains of Shiga-like or Vero toxins.
Although the invention and DNA ligand sequences have been described with reference to specific embodiments, this description is not meant to be construed in a limited sense. Various modifications of the disclosed embodiments, as well as alternative embodiments of the inventions will become apparent to persons skilled in the art upon the reference to the description of the invention. It is, therefore, contemplated that the appended claims will cover such modifications that fall within the scope of the invention.
| TABLE 1 |
| DNA ligand Sequence ID Nos. |
| Campylobacter jejuni OMPs - Fresh bacteria |
| SEQ ID NO. 1 (C1) - CATCCGTCACACCTGCTCTGGGGAGGGTGGCGCCCGTCTCGGT |
| GGTGTTGGCTCCCGTATCA |
| SEQ ID NO. 2 (C2) - CATCCGTCACACCTGCTCTGGGATAGGGTCTCGTGCTAGATGTG |
| GTGTTGGCTCCCGTATCA |
| SEQ ID NO. 3 (C3) - CATCCGTCACACCTGCTCTGGACCGGCGCTTATTCCTGCTTGTG |
| GTGTTGGCTCCCGTATCA |
| SEQ ID NO. 4 (C4) - CATCCGTCACACCTGCTCTGGAGCTGATATTGGATGGTCCGGTG |
| GTGTTGGCTCCCGTATCA |
| SEQ ID NO. 5 (C5) - CATCCGTCACACCTGCTCTGCCCAGAGCAGGTGTGACGGATGTG |
| GTGTTGGCTCCCGTATCA |
| SEQ ID NO. 6 (C6) - CATCCGTCACACCTGCTCTGCCGGACCATCCAATATCAGCTGTG |
| GTGTTGGCTCCCGTATCA |
| Aged Campylobacter jejuni (ACj; Greater than one month at 4° C.) |
| SEQ ID NO. 7 (ACj-1 For) - ATACGGGAGCCAACACCAGGACCAAAATAAATAATCAC |
| AATAAAAATGCTTCCTAGAGCAGGTGTGACGGAT |
| SEQ ID NO. 8 (ACj-1 Rev) - ATCCGTCACACCTGCTCTAGGAAGCATTTTTATTGTGAT |
| TATTTATTTTGGTCCTGGTGTTGGCTCCCGTAT |
| SEQ ID NO. 9 (ACj-2 For) - ATACGGGAGCCAACACCACGCCGGGCCATAGGCGTGTG |
| GTAGCATACTCGTACTAGAGCAGGTGTGACGGAT |
| SEQ ID NO. 10 (ACj-2 Rev) - ATCCGTCACACCTGCTCTAGTACGAGTATGCTACCACA |
| CGCCTATGGCCCGGCGTGGTGTTGGCTCCCGTAT |
| SEQ ID NO. 11 (ACj-3 For) - ATACGGGAGCCAACACCATAGTATAAAGACCCAATTG |
| ACAGACTATCCTAGGCTAGAGCAGGTGTGACGGAT |
| SEQ ID NO. 12 (ACj-3 Rev) - ATCCGTCACACCTGCTCTAGCCTAGGATAGTCTGTCAA |
| TTGGGTCTTTATACTATGGTGTTGGCTCCCGTAT |
| SEQ ID NO. 13 (ACj-4 For) - ATACGGGAGCCAACACCAAGAGGGGACAGAGGGTATA |
| AGACAACTATTCTCCCCAGAGCAGGTGTGACGGAT |
| SEQ ID NO. 14 (ACj-4 Rev) - ATCCGTCACACCTGCTCTGGGGAGAATAGTTGTCTTAT |
| ACCCTCTGTCCCCTCTTGGTGTTGGCTCCCGTAT |
| SEQ ID NO. 15 (ACj-7 For) - ATACGGGAGCCAACACCAGGCGGCCGCAACTTGGTCC |
| CCTCTTCATCCTCGGATAGAGCAGGTGTGACGGAT |
| SEQ ID NO. 16 (ACj-7 Rev) - ATCCGTCACACCTGCTCTATCCGAGGATGAAGAGGGG |
| ACCAAGTTGCGGCCGCCTGGTGTTGGCTCCCGTAT |
| SEQ ID NO. 17 (ACj-8 For (69)) - ATACGGGAGCCAACACCATAGTGTTGGACCAA |
| TACGGTAACGTGTCCTTGGAGAGCAGGTGTGACGGAT |
| SEQ ID NO. 18 (ACj-8 Rev (69)) - ATCCGTCACACCTGCTCTCCAAGGACACGTTA |
| CCGTATTGGTCCAACACTATGGTGTTGGCTCCCGTAT |
| SEQ ID NO. 19 (ACj-9 For) - ATACGGGAGCCAACACCACGCGATACAATGTGCTAAA |
| AAAGTTCGTGCCCCTGCAGAGCAGGTGTGACGGAT |
| SEQ ID NO. 20 (ACj-9 Rev) - ATCCGTCACACCTGCTCTGCAGGGGCACGAACTTTTTT |
| AGCACATTGTATCGCGTGGTGTTGGCTCCCGTAT |
| SEQ ID NO. 21 (ACj-10 For) - ATACGGGAGCCAACACCACGCCGAATAGTGTTCGTAT |
| GCCACCCGCACGTGTCTAGAGCAGGTGTGACGGAT |
| SEQ ID NO. 22 (ACj-10 Rev) - ATCCGTCACACCTGCTCTAGACACGTGCGGGTGGCAT |
| ACGAACACTATTCGGCGTGGTGTTGGCTCCCGTAT |
| SEQ ID NO. 23 (ACj-11 For) - ATACGGGAGCCAACACCAGGCATGACTAAAAAGGAT |
| AACCTAATCTCTTGTTCCAGAGCAGGTGTGACGGAT |
| SEQ ID NO. 24 (ACj-11 Rev) - ATCCGTCACACCTGCTCTGGAACAAGAGATTAGGTTA |
| TCCTTTTTAGTCATGCCTGGTGTTGGCTCCCGTAT |
| SEQ ID NO. 25 (ACj-15 For) - ATACGGGAGCCAACACCATACAGTCCACCGTATACTA |
| GTGGTACCCAGGCGTCGAGAGCAGGTGTGACGGAT |
| SEQ ID NO. 26 (ACj-15 Rev) - ATCCGTCACACCTGCTCTCGACGCCTGGGTACCACTA |
| GTATACGGTGGACTGTATGGTGTTGGCTCCCGTAT |
| SEQ ID NO. 27 (ACj-16 For) - ATACGGGAGCCAACACCAGGGGGCGAACAGTTACCC |
| TTGGTCTGGACCACTGCCAGAGCAGGTGTGACGGAT |
| SEQ ID NO. 28 (ACj-16 Rev) - ATCCGTCACACCTGCTCTGGCAGTGGTCCAGACCAAG |
| GGTAACTGTTCGCCCCCTGGTGTTGGCTCCCGTAT |
| SEQ ID NO. 29 (ACj-17 For) - ATACGGGAGCCAACACCAGGGGCGTCGGGCCAGGCG |
| ACGGCCGCCGTTTCCGGCAGAGCAGGTGTGACGGAT |
| SEQ ID NO. 30 (ACj-17 Rev) - ATCCGTCACACCTGCTCTGCCGGAAACGGCGGCCGTC |
| GCCTGGCCCGACGCCCCTGGTGTTGGCTCCCGTAT |
| SEQ ID NO. 31 (ACj-18 For) - ATACGGGAGCCAACACCACGGGCCGTCCCTGGCCCG |
| GGGGGGCGAAACGCGCTGAGAGCAGGTGTGACGGAT |
| SEQ ID NO. 32 (ACj-18 Rev) - ATCCGTCACACCTGCTCTCAGCGCGTTTCGCCCCCCC |
| GGGCCAGGGACGGCCCGTGGTGTTGGCTCCCGTAT |
| SEQ ID NO. 33 (ACj-19 For) - ATACGGGAGCCAACACCAGGCGATTACTAAGGGAAA |
| AAAGTGTAAAACCTACCCAGAGCAGGTGTGACGGAT |
| SEQ ID NO. 34 (ACj-19 Rev) - ATCCGTCACACCTGCTCTGGGTAGGTTTTACACTTTT |
| TTCCCTTAGTAATCGCCTGGTGTTGGCTCCCGTAT |
| SEQ ID NO. 35 (ACj-24 For) - ATACGGGAGCCAACACCACCACCCACTGGCCCGGTC |
| CGCGGCCGCGCGCGCCCCAGAGCAGGTGTGACGGAT |
| SEQ ID NO. 36 (ACj-24 Rev) - ATCCGTCACACCTGCTCTGGGGCGCGCGCGGCCGCG |
| GACCGGGCCAGTGGGTGGTGGTGTTGGCTCCCGTAT |
| SEQ ID NO. 37 (ACj-25 For) - ATACGGGAGCCAACACCAACGATATCCCTGACCAAA |
| GACGTTAAATGCTTCCATAGAGCAGGTGTGACGGAT |
| SEQ ID NO. 38 (ACj-25 Rev) - ATCCGTCACACCTGCTCTATGGAAGCATTTAACGTCT |
| TTGGTCAGGGATATCGTTGGTGTTGGCTCCCGTAT |
| SEQ ID NO. 39 (ACj-26 For) - ATACGGGAGCCAACACCAGGGCGGGGGGTTGGCGAG |
| CAGGAATCGAGAGAGGTGAGAGCAGGTGTGACGGAT |
| SEQ ID NO. 40 (ACj-26 Rev) - ATCCGTCACACCTGCTCTCACCTCTCTCGATTCCTG |
| CTCGCCAACCCCCCGCCCTGGTGTTGGCTCCCGTAT |
| SEQ ID NO. 41 (ACj-27 For) - ATACGGGAGCCAACACCAGATGCGCTTCCTGTAATGA |
| ACAGATCATATTTATGTAGAGCAGGTGTGACGGAT |
| SEQ ID NO. 42 (ACj-27 Rev) - ATCCGTCACACCTGCTCTACATAAATATGATCTGTTC |
| ATTACAGGAAGCGCATCTGGTGTTGGCTCCCGTAT |
| SEQ ID NO. 43 (ACj-28 For) - ATACGGGAGCCAACACCAAGGTAGGTTGCCGCAGGT |
| TGGCGACAAACCAGGTTGAGAGCAGGTGTGACGGAT |
| SEQ ID NO. 44 (ACj-28 Rev) - ATCCGTCACACCTGCTCTCAACCTGGTTTGTCGCCAA |
| CCTGCGGCAACCTACCTTGGTGTTGGCTCCCGTAT |
| SEQ ID NO. 45 (ACj-30 For (69)) - ATACGGGAGCCAACACCATAGTGTTGGACCA |
| ATACGGTAACGTGTCCTTGGAGAGCAGGTGTGACGGAT |
| SEQ ID NO. 46 (ACj-30 Rev (69)) - ATCCGTCACACCTGCTCTCCAAGGACACGTT |
| ACCGTATTGGTCCAACACTATGGTGTTGGCTCCCGTAT |
| SEQ ID NO. 47 (ACj-33 For) - ATACGGGAGCCAACACCACCCGGGTGGCGGGGTGGG |
| TGTGGGTCGACGTTCTGGAGAGCAGGTGTGACGGAT |
| SEQ ID NO. 48 (ACj-33 Rev) - ATCCGTCACACCTGCTCTCCAGAACGTCGACCCACAC |
| CCACCCCGCCACCCGGGTGGTGTTGGCTCCCGTAT |
| SEQ ID NO. 49 (ACj-34 For) - ATACGGGAGCCAACACCAGGGGGGGGTGGCCGCAGG |
| AAATATGCAGTCCACTATAGAGCAGGTGTGACGGAT |
| SEQ ID NO. 50 (ACj-34 Rev) - ATCCGTCACACCTGCTCTATAGTGGACTGCATATTTC |
| CTGCGGCCACCCCCCCCTGGTGTTGGCTCCCGTAT |
| SEQ ID NO. 51 (ACj-35 For) - ATACGGGAGCCAACACCACACACCGGGCCCGCCCCC |
| AGCGCCCCCCTACGCACAAGAGCAGGTGTGACGGAT |
| SEQ ID NO. 52 (ACj-35 Rev) - ATCCGTCACACCTGCTCTTGTGCGTAGGGGGGCGCTG |
| GGGGCGGGCCCGGTGTGTGGTGTTGGCTCCCGTAT |
| SEQ ID NO. 53 (ACj-38 For) - ATACGGGAGCCAACACCATGAAGGAAACCTTGATAG |
| CAGGAATAGTCCATTCCCAGAGCAGGTGTGACGGAT |
| SEQ ID NO. 54 (ACj-38 Rev) - ATCCGTCACACCTGCTCTGGGAATGGACTATTCCTGC |
| TATCAAGGTTTCCTTCATGGTGTTGGCTCCCGTAT |
| SEQ ID NO. 55 (ACj-39 For) - ATACGGGAGCCAACACCACCCGGGTGGCGGGGTGGG |
| TGTGGGTCGACGTTCTGGAGAGCAGGTGTGACGGAT |
| SEQ ID NO. 56 (ACj-39 Rev) - ATCCGTCACACCTGCTCTCCAGAACGTCGACCCACA |
| CCCACCCCGCCACCCGGGTGGTGTTGGCTCCCGTAT |
| SEQ ID NO. 57 (ACj-40 For) - ATACGGGAGCCAACACCACGCCCGCCGGCGACTCGC |
| TCCACTCCGTCCCGCTCCAGAGCAGGTGTGACGGAT |
| SEQ ID NO. 58 (ACj-40 Rev) - ATCCGTCACACCTGCTCTGGAGCGGGACGGAGTGGA |
| GCGAGTCGCCGGCGGGCGTGGTGTTGGCTCCCGTAT |
| Enterococcus faecalis Teichoic Acid (TA) DNA ligands |
| SEQ ID NO. 59 (TA5F) - CATTCACCACACCTCTGCTGGCTTGGCTAGCCTTGATGCTA |
| AACGACCCATAGTGTGGTGTCGTCCCGTATC |
| SEQ ID NO. 60 (TA5R) - GATACGGGACGACACCACACTATGGGTCGTTTAGCATCAA |
| GGCTAGCCAAGCCAGCAGAGGTGTGGTGAATG |
| SEQ ID NO. 61 (TA6F) - CATTCACCACACCTCTGCTGGAGGAGGAAGTGGTCTGGAG |
| TTACTTGACATAGTGTGGTGTCGTCCCGTATC |
| SEQ ID NO. 62 (TA6R) - GATACGGGACGACACCACACTATGTCAAGTAACTCCAGAC |
| CACTTCCTCCTCCAGCAGAGGTGTGGTGAATG |
| SEQ ID NO. 63 (TA7F) - CATTCACCACACCTCTGCTGGACGGAAACAATCCCCGGGTA |
| CGAGAATCAGGGTGTGGTGTCGTCCCGTATC |
| SEQ ID NO. 64 (TA7R) - GATACGGGACGACACCACACCCTGATTCTCGTACCCGGGGA |
| TTGTTTCCGTCCAGCAGAGGTGTGGTGAATG |
| SEQ ID NO. 65 (TA9F) - CATTCACCACACCTCTGCTGGAAACCTACCATTAATGAGAC |
| ATGATGCGGTGGTGTGGTGTCGTCCCGTATC |
| SEQ ID NO. 66 (TA9R) - GATACGGGACGACACCACACCACCGCATCATGTCTCATTAA |
| TGGTAGGTTTCCAGCAGAGGTGTGGTGAATG |
| E. coli O157 Lipopolysaccharide (LPS) DNA ligands |
| SEQ ID NO. 67 (E-5F) - ATCCGTCACACCTGCTCTGGTGGAATGGACTAAGCTAGCTAG |
| CGTTTTAAAAGGTGGTGTTGGCTCCCGTAT |
| SEQ ID NO. 68 (E-11F) - ATCCGTCACACCTGCTCTGTAAGGGGGGGGAATCGCTTTCG |
| TCTTAAGATGACATGGTGTTGGCTCCCGTAT |
| SEQ ID NO. 69 (E-12F) - ATCCGTCACACCTGCTCTGCCGGACCATCCAATATCAGCTG |
| TGGTGTTGGCTCCCGTAT |
| SEQ ID NO. 70 (E-16F) - ATCCGTCACACCTGCTCTATCCGTCACGCCTGCTCTATCCG |
| TCACACCTGCTCTGGTGTTGGCTCCCGTAT |
| SEQ ID NO. 71 (E-17F) - ATCCGTCACACCTGCTCTATCAAATGTGCAGATATCAAGA |
| CGATTTGTACAAGATGGTGTTGGCTCCCGTAT |
| SEQ ID NO. 72 (E-18F) - ATCCGTCACACCTGCTCTGTAGATGGCAAGGCATAAGCGT |
| CCGGAACGATAGAATGGTGTTGGCTCCCGTAT |
| SEQ ID NO. 73 (E-19F) - ATCCGTCACACCTGCTCTGTAGATGGCAAGGCATAAGCGTC |
| CGGAACGATAGAATGGTGTTGGCTCCCGTAT |
| SEQ ID NO. 74 (E-5R) - ATACGGGAGCCAACACCACCTTTTAAAACGCTAGCTAGCTT |
| AGTCCATTCCACCAGAGCAGGTGTGACGGAT |
| SEQ ID NO. 75 (E-11R) - ATACGGGAGCCAACACCATGTCATCTTAAGACGAAAGCGA |
| TTCCCCCCCCTTACAGAGCAGGTGTGACGGAT |
| SEQ ID NO. 76 (E-12R) - ATACGGGAGCCAACACCACAGCTGATATTGGATGGTCCGG |
| CAGAGCAGGTGTGACGGAT |
| SEQ ID NO. 77 (E-16R) - ATACGGGAGCCAACACCAGAGCAGGTGTGACGGATAGAGC |
| AGGCGTGACGGATAGAGCAGGTGTGACGGAT |
| SEQ ID NO. 78 (E-17R) - ATACGGGAGCCAACACCATCTTGTACAAATCGTCTTGATAT |
| CTGCACATTTGATAGAGCAGGTGTGACGGAT |
| SEQ ID NO. 79 (E-18R) - ATACGGGAGCCAACACCATTCTATCGTTCCGGACGCTTATG |
| CCTTGCCATCTACAGAGCAGGTGTGACGGAT |
| SEQ ID NO. 80 (E-19R) - ATACGGGAGCCAACACCATTCTATCGTTCCGGACGCTTAT |
| GCCTTGCCATCTACAGAGCAGGTGTGACGGAT |
| E. coli Outer Membrane Proteins (OMPs) - Fresh Bacteria |
| SEQ ID NO. 81 (EcO-1F) - ATACGGGAGCCAACACCATGGTACAAGCAAACCAATAT |
| TAGGGCCCAGACATCGAGAGCAGGTGTGACGGAT |
| SEQ ID NO. 82 (EcO-1R) - ATCCGTCACACCTGCTCTCGATGTCTGGGCCCTAATATT |
| GGTTTGCTTGTACCATGGTGTTGGCTCCCGTAT |
| SEQ ID NO. 83 (EcO-2F) - ATACGGGAGCCAACACCATGATACCCTAAGGTAGGGGA |
| GGCCTAAGCGCCACGTAGAGCAGGTGTGACGGAT |
| SEQ ID NO. 84 (EcO-2R) - ATCCGTCACACCTGCTCTACGTGGCGCTTAGGCCTCCCC |
| TACCTTAGGGTATCATGGTGTTGGCTCCCGTAT |
| SEQ ID NO. 85 (EcO-3F) - ATACGGGAGCCAACACCACGCATCCCCCGCCGGGCCC |
| GCGCCCCGCTCGCAGACAGAGCAGGTGTGACGGAT |
| SEQ ID NO. 86 (EcO-3R) - ATCCGTCACACCTGCTCTGTCTGCGAGCGGGGCGCGGGC |
| CCGGCGGGGGATGCGTGGTGTTGGCTCCCGTAT |
| SEQ ID NO. 87 (EcO-4F (73)) - ATACGGGAGCCAACACCATAATATGCCGTAAGGAG |
| AGGCCTGTTGGGAGCGCCGTAGAGCAGGTGTGACGGAT |
| SEQ ID NO. 88 (EcO-4R (73)) - ATCCGTCACACCTGCTCTACGGCGCTCCCAACAGGC |
| CTCTCCTTACGGCATATTATGGTGTTGGCTCCCGTAT |
| SEQ ID NO. 89 (EcO-5F) - ATACGGGAGCCAACACCAGGAAAAAAAGAGCCTGTGAA |
| GATTGTAATATCAGTTAGAGCAGGTGTGACGGAT |
| SEQ ID NO. 90 (EcO-5R) - ATCCGTCACACCTGCTCTAACTGATATTACAATCTTCAC |
| AGGCTCTTTTTTTCCTGGTGTTGGCTCCCGTAT |
| SEQ ID NO. 91 (EcO-7Fa) - ATCCGTCACACCTGCTCTCGGAGGTAGACTAGGATTGC |
| GGCGGGGGGTCAGGTATGGTGTTGGCTCCCGTAT |
| SEQ ID NO. 92 (EcO-7Fb) - ATACGGGAGCCAACACCACAAAAGCCTTACCTAACTGC |
| CAACAATGAATAGCAAGAGCAGGTGTGACGGAT |
| SEQ ID NO. 93 (EcO-7Ra) - ATCCGTCACACCTGCTCTTGCTATTCATTGTTGGCAGTT |
| AGGTAAGGCTTTTGTTGGTGTTGGCTCCCGTAT |
| SEQ ID NO. 94 (EcO-7Rb) - ATACGGGAGCCAACACCATACCTGACCCCCCGCCGCAA |
| TCCTAGTCTACCTCCGAGAGCAGGTGTGACGGAT |
| SEQ ID NO. 95 (EcO-8F) - ATACGGGAGCCAACACCACGACTAACACGACCGTTGGG |
| GGGGGCTCGCGCGGGCAGAGCAGGTGTGACGGAT |
| SEQ ID NO. 96 (EcO-8R) - ATCCGTCACACCTGCTCTGCCCGCGCGAGCCCCCCCCAA |
| CGGTCGTGTTAGTCGTGGTGTTGGCTCCCGTAT |
| SEQ ID NO. 97 (EcO-9F) - ATACGGGAGCCAACACCAGTCCCCGCCCAGCCGTGAGC |
| CGTACCCCCGCACACCAGAGCAGGTGTGACGGAT |
| SEQ ID NO. 98 (EcO-9R) - ATCCGTCACACCTGCTCTGGTGTGCGGGGGTACGGCTCA |
| CGGCTGGGCGGGGACTGGTGTTGGCTCCCGTAT |
| SEQ ID NO. 99 (EcO-10F) - ATCCGTCACACCTGCTCTCAAGGTTGGGCCTGCAAGAG |
| CAAAAACGGGGCGGGATGGTGTTGGCTCCCGTAT |
| SEQ ID NO. 100 (EcO-10R) - ATACGGGAGCCAACACCATCCCGCCCCGTTTTTGCTCT |
| TGCAGGCCCAACCTTGAGAGCAGGTGTGACGGAT |
| SEQ ID NO. 101 (EcO-11F) - ATCCGTCACACCTGCTCTACTTGGCTTGCGACTATTAT |
| TCACAGGGCCAAAGACTGGTGTTGGCTCCCGTAT |
| SEQ ID NO. 102 (EcO-11R) - ATACGGGAGCCAACACCAGTCTTTGGCCCTGTGAATA |
| ATAGTCGCAAGCCAAGTAGAGCAGGTGTGACGGAT |
| SEQ ID NO. 103 (EcO-12/37/60F (69)) - ATACGGGAGCCAACACCATAGTGTTGGA |
| CCAATACGGTAACGTGTCCTTGGAGAGCAGGTGTGACGGAT |
| SEQ ID NO. 104 (EcO-12/37/60R (69)) - ATCCGTCACACCTGCTCTCCAAGGACAC |
| GTTACCGTATTGGTCCAACACTATGGTGTTGGCTCCCGTAT |
| SEQ ID NO. 105 (EcO-17F) - ATCCGTCACACCTGCTCTTGGAATGTCGGTGTTTTTCC |
| AATTCCTTGGGTCGTGTGGTGTTGGCTCCCGTAT |
| SEQ ID NO. 106 (EcO-17R) - ATACGGGAGCCAACACCACACGACCCAAGGAATTGG |
| AAAAACACCGACATTCCAAGAGCAGGTGTGACGGAT |
| SEQ ID NO. 107 (EcO-18F) - ATCCGTCACACCTGCTCTGCGACGGCGACGCGGTCCG |
| GGCGGGGGTGGAGGACGTGGTGTTGGCTCCCGTAT |
| SEQ ID NO. 108 (EcO-18R) - ATACGGGAGCCAACACCACGTCCTCCACCCCCGCCCG |
| GACCGCGTCGCCGTCGCAGAGCAGGTGTGACGGAT |
| SEQ ID NO. 109 (EcO-19Fa) - ATACGGGAGCCAACACCAGAGGGTTCTAGGGTCACT |
| TCCATGAGAATGGCTCACAGAGCAGGTGTGACGGAT |
| SEQ ID NO. 110 (EcO-19Fb) - ATCCGTCACACCTGCTCTGGCCTGGGGACGCGAGGG |
| AGGCGGGGGGAGTCGTGGTGGTGTTGGCTCCCGTAT |
| SEQ ID NO. 111 (EcO-19Ra) - ATACGGGAGCCAACACCACCACGACTCCCCCCGCCT |
| CCCTCGCGTCCCCAGGCCAGAGCAGGTGTGACGGAT |
| SEQ ID NO. 112 (EcO-19Rb) - ATCCGTCACACCTGCTCTGTGAGCCATTCTCATGGAA |
| GTGACCCTAGAACCCTCTGGTGTTGGCTCCCGTAT |
| SEQ ID NO. 113 (EcO-20F)ATCCGTCACACCTGCTCTCACAGGGCCTCTTACTATACA |
| GTTCTCCAGCGCTGCTGGTGTTGGCTCCCGTAT |
| SEQ ID NO. 114 (EcO-20R) - ATACGGGAGCCAACACCAGCAGCGCTGGAGAACTGTA |
| TAGTAAGAGGCCCTGTG GAGCAGGTGTGACGGAT |
| SEQ ID NO. 115 (EcO-21F) - ATCCGTCACACCTGCTCTGCACGGGCTCAGTTTGGCTT |
| TGTATCCTAAGAGAGATGGTGTTGGCTCCCGTAT |
| SEQ ID NO. 116 (EcO-21R) - ATACGGGAGCCAACACCATCTCTCTTAGGATACAAAG |
| CCAAACTGAGCCCGTGCAGAGCAGGTGTGACGGAT |
| SEQ ID NO. 117 (EcO-22F) - ATACGGGAGCCAACACCAGGGGTGGCGAACATGGTAT |
| AACTTGATAAGTGTGAAGAGCAGGTGTGACGGAT |
| SEQ ID NO. 118 (EcO-22R) - ATCCGTCACACCTGCTCTTCACACTTATCAAGTTATAC |
| CATGTTCGCCACCCCCTGGTGTTGGCTCCCGTAT |
| SEQ ID NO. 119 (EcO-23F) - ATACGGGAGCCAACACCACTCCGACACCGGCCGCCGG |
| CACCACCCACTCCCCCTAGAGCAGGTGTGACGGAT |
| SEQ ID NO. 120 (EcO-23R) - ATCCGTCACACCTGCTCTAGGGGGAGTGGGTGGTGCC |
| GGCGGCCGGTGTCGGAGTGGTGTTGGCTCCCGTAT |
| SEQ ID NO. 121 (EcO-24F) - ATACGGGAGCCAACACCATCCGGCGCGCCCTCCTCCC |
| CCACTGCTCCCCGCCCGAGAGCAGGTGTGACGGAT |
| SEQ ID NO. 122 (EcO-24R) - ATCCGTCACACCTGCTCTCGGGCGGGGAGCAGTGGGG |
| GAGGAGGGCGCGCCGGATGGTGTTGGCTCCCGTAT |
| SEQ ID NO. 123 (EcO-25F) - ATACGGGAGCCAACACCATACGCAGAGGTCCCCTACC |
| CAGGCCAGCCGGATGCCAGAGCAGGTGTGACGGAT |
| SEQ ID NO. 124 (EcO-25R) - ATCCGTCACACCTGCTCTGGCATCCGGCTGGCCTGGG |
| TAGGGGACCTCTGCGTATGGTGTTGGCTCCCGTAT |
| SEQ ID NO. 125 EcO-26 F - ATACGGGAGCCAACACCACGAGGATTACAACTTTATGC |
| GTGCAACCAGACACCAAGAGCAGGTGTGACGGAT |
| SEQ ID NO. 126 EcO-26 R - ATCCGTCACACCTGCTCTTGGTGTCTGGTTGCACGCATA |
| AAGTTGTAATCCTCGTGGTGTTGGCTCCCGTAT |
| SEQ ID NO. 127 EcO-27 F - ATACGGGAGCCAACACCATATAAACGAGGAAATAAAA |
| CTGCAGAACACTTCCTCAGAGCAGGTGTGACGGAT |
| SEQ ID NO. 128 EcO-27 R - ATCCGTCACACCTGCTCTGAGGAAGTGTTCTGCAGTTTT |
| ATTTCCTCGTTTATATGGTGTTGGCTCCCGTAT |
| SEQ ID NO. 129 EcO-28 F(71) - ATACGGGAGCCAACACCATCACGGCAATGTCCCGA |
| TAATGTCTTGCTTCAGCGAGAGCAGGTGTGACGGAT |
| SEQ ID NO. 130 EcO-28 R(71) - ATCCGTCACACCTGCTCTCGCTGAAGCAAGACATTA |
| TCGGGACATTGCCGTGATGGTGTTGGCTCCCGTAT |
| SEQ ID NO. 131 EcO-29 F - ATACGGGAGCCAACACCAAGCAATCAGTATACCCACCC |
| GTCAAAAACATCATGCAGAGCAGGTGTGACGGAT |
| SEQ ID NO. 132 EcO-29 R - ATCCGTCACACCTGCTCTGCATGATGTTTTTGACGGGTG |
| GGTATACTGATTGCTTGGTGTTGGCTCCCGTAT |
| SEQ ID NO. 133 EcO-30 F - ATACGGGAGCCAACACCACGGCTTCTTGCGCCCCCCCG |
| CGCCCGCGCCCCCCCCAGAGCAGGTGTGACGGAT |
| SEQ ID NO. 134 EcO-30 R - ATCCGTCACACCTGCTCTGGGGGGGGCGCGGGCGCGG |
| GGGGGCGCAAGAAGCCGTGGTGTTGGCTCCCGTAT |
| SEQ ID NO. 135 EcO-31 F - ATACGGGAGCCAACACCAACGGAGGATGAAGAGATAA |
| AGTAAATATCCGGGGGCAGAGCAGGTGTGACGGAT |
| SEQ ID NO. 136 EcO-31 R - ATCCGTCACACCTGCTCTGCCCCCGGATATTTACTTTAT |
| CTCTTCATCCTCCGTTGGTGTTGGCTCCCGTAT |
| SEQ ID NO. 137 EcO-32 F - ATACGGGAGCCAACACCACCCGTGGCCTTCACCCAGCC |
| AGGGGCCCCGTCTCTGAGAGCAGGTGTGACGGAT |
| SEQ ID NO. 138 EcO-32 R - ATCCGTCACACCTGCTCTCAGAGACGGGGCCCCTGGCT |
| GGGTGAAGGCCACGGGTGGTGTTGGCTCCCGTAT |
| SEQ ID NO. 139 EcO-33 F - ATACGGGAGCCAACACCACACTACCGTCCCACCCCCTC |
| CCAGCTCCTCCGGCCGAGAGCAGGTGTGACGGAT |
| SEQ ID NO. 140 EcO-33 R - ATCCGTCACACCTGCTCTCGGCCGGAGGAGCTGGGAG |
| GGGGTGGGACGGTAGTGTGGTGTTGGCTCCCGTAT |
| SEQ ID NO. 141 EcO-34 F - ATACGGGAGCCAACACCAATCCCCCGCCTGCGACCGAT |
| GCACTCCCATATGTCGAGAGCAGGTGTGACGGAT |
| SEQ ID NO. 142 EcO-34 R - ATCCGTCACACCTGCTCTCGACATATGGGAGTGCATCG |
| G TCGCAGGCGGGGGATTGGTGTTGGCTCCCGTAT |
| SEQ ID NO. 143 EcO-35 F - ATACGGGAGCCAACACCATACATGCCCAAGGTTTCGGG |
| TGAGGCTACCGTGAGTAGAGCAGGTGTGACGGAT |
| SEQ ID NO. 144 EcO-35 R - ATCCGTCACACCTGCTCTACTCACGGTAGCCTCACCCG |
| AAACCTTGGGCATGTATGGTGTTGGCTCCCGTAT |
| SEQ ID NO. 145 EcO-36 F - ATACGGGAGCCAACACCATTTATGTTTCATACTTTAAAC |
| TTGGTCGTTTGCGATAGAGCAGGTGTGACGGAT |
| SEQ ID NO. 146 EcO-36 R - ATCCGTCACACCTGCTCTATCGCAAACGACCAAGTTTA |
| AAGTATGAAACATAAATGGTGTTGGCTCCCGTAT |
| SEQ ID NO. 147 EcO-38 F - ATACGGGAGCCAACACCAGGCGTTTAATAATCGGAGCG |
| ACAAATTCTACGCTGTAGAGCAGGTGTGACGGAT |
| SEQ ID NO. 148 EcO-38 R - ATCCGTCACACCTGCTCTACAGCGTAGAATTTGTCGCT |
| CCGATTATTAAACGCCTGGTGTTGGCTCCCGTAT |
| SEQ ID NO. 149 EcO-40/41B F - ATACGGGAGCCAACACCACGGCAACTTCAAACCCA |
| AGACTAAGAAAAGCTCGTGAGAGCAGGTGTGACGGAT |
| SEQ ID NO. 150 EcO-40/41B R - ATCCGTCACACCTGCTCTCACGAGCTTTTCTTAGTC |
| TTGGGTTTGAAGTTGCCGTGGTGTTGGCTCCCGTAT |
| SEQ ID NO. 151 EcO-41A F - ATACGGGAGCCAACACCATTGTAGGCGGATATTAGAC |
| AAGACCGAATTCCATGGAGAGCAGGTGTGACGGAT |
| SEQ ID NO. 152 EcO-41A R - ATCCGTCACACCTGCTCTCCATGGAATTCGGTCTTGTC |
| TAATATCCGCCTACAATGGTGTTGGCTCCCGTAT |
| SEQ ID NO. 153 EcO-42/43A F - ATACGGGAGCCAACACCAGTAGGCTAAAGTGAGG |
| TTAATTATGTCGACAAGGCCAGAGCAGGTGTGACGGAT |
| SEQ ID NO. 154 EcO-42/43A R - ATCCGTCACACCTGCTCTGGCCTTGTCGACATAATT |
| AACCTCACTTTAGCCTACTGGTGTTGGCTCCCGTAT |
| SEQ ID NO. 155 EcO-43B F - ATACGGGAGCCAACACCACCTCGCCCAGACGCCGGG |
| CCCTCCCCGCCCCACCCCAGAGCAGGTGTGACGGAT |
| SEQ ID NO. 156 EcO-43B R - ATCCGTCACACCTGCTCTGGGGTGGGGCGGGGAGGG |
| CCCGGCGTCTGGGCGAGGTGGTGTTGGCTCCCGTAT |
| SEQ ID NO. 157 EcO-44 F - ATACGGGAGCCAACACCAGGTATTGGAGCTATACACGT |
| TAACCACCGCTATTGCAGAGCAGGTGTGACGGAT |
| SEQ ID NO. 158 EcO-44 R - ATCCGTCACACCTGCTCTGCAATAGCGGTGGTTAACGT |
| GTATAGCTCCAATACCTGGTGTTGGCTCCCGTAT |
| SEQ ID NO. 159 EcO-45 F - ATACGGGAGCCAACACCACGCGGGGCGGGGGGGCTGG |
| TCGCGCGGGCCTGGCGGAGAGCAGGTGTGACGGAT |
| SEQ ID NO. 160 EcO-45 F - ATCCGTCACACCTGCTCTCCGCCAGGCCCGCGCGACCA |
| GCCCCCCCGCCCCGCGTGGTGTTGGCTCCCGTAT |
| SEQ ID NO. 161 EcO-46 F - ATACGGGAGCCAACACCAAACATTGGAACAACAAACG |
| CTAATACACGATCGCATAGAGCAGGTGTGACGGAT |
| SEQ ID NO. 162 EcO-46 R - ATCCGTCACACCTGCTCTATGCGATCGTGTATTAGCGTT |
| TGTTGTTCCAATGTTTGGTGTTGGCTCCCGTAT |
| SEQ ID NO. 163 EcO-47 F - ATACGGGAGCCAACACCAATAGATGGATAAGGGGGA A |
| ACTGCCATTCGGTTAGTAGAGCAGGTGTGACGGAT |
| SEQ ID NO. 164 EcO-47 R - ATCCGTCACACCTGCTCTACTAACCGAATGGCAGTTTC |
| CCCCTTATCCATCTATTGGTGTTGGCTCCCGTAT |
| SEQ ID NO. 165 EcO-48 F - ATACGGGAGCCAACACCAACCAACGAAGAAGGGTCAG |
| ACAAAAAGGAGTTCTCGAGAGCAGGTGTGACGGAT |
| SEQ ID NO. 166 EcO-48 R - ATCCGTCACACCTGCTCTCGAGAACTCCTTTTTGTCTGA |
| CCCTTCTTCGTTGGTTGGTGTTGGCTCCCGTAT |
| SEQ ID NO. 167 EcO-49 F - ATACGGGAGCCAACACCACAACAGTCAGATTGCAACT |
| GAGTAGTACATACGTTAAGAGCAGGTGTGACGGAT |
| SEQ ID NO. 168 EcO-49 R - ATCCGTCACACCTGCTCTTAACGTATGTACTACTCAGTT |
| GCAATCTGACTGTTGTGGTGTTGGCTCCCGTAT |
| SEQ ID NO. 169 EcO-50 F - ATACGGGAGCCAACACCATAAACCAAGGGTGTAACAG |
| AAATGATGTGACCAGGCAGAGCAGGTGTGACGGAT |
| SEQ ID NO. 170 EcO-50 R - ATCCGTCACACCTGCTCTGCCTGGTCACATCATTTCTGT |
| TACACCCTTGGTTTATGGTGTTGGCTCCCGTAT |
| SEQ ID NO. 171 EcO-51 F - ATACGGGAGCCAACACCATCATTGCGACATTGAATTCA |
| GAAGGAGGAGTGGTGTAGAGCAGGTGTGACGGAT |
| SEQ ID NO. 172 EcO-51 R - ATCCGTCACACCTGCTCTACACCACTCCTCCTTCTGAAT |
| TCAATGTCGCAATGATGGTGTTGGCTCCCGTAT |
| SEQ ID NO. 173 EcO-52 F (71) - ATACGGGAGCCAACACCAGAGAATTACAACAGGTT |
| AAGTAGTGTGACGATCATAGAGCAGGTGTGACGGAT |
| SEQ ID NO. 174 EcO-52 R (71) - ATCCGTCACACCTGCTCTATGATCGTCACACTACT |
| TAACCTGTTGTAATTCTCTGGTGTTGGCTCCCGTAT |
| SEQ ID NO. 175 EcO-53 F - ATACGGGAGCCAACACCACGGCGGAACACATGGAACA |
| CCGAATAATGTGGCTTAAGAGCAGGTGTGACGGAT |
| SEQ ID NO. 176 EcO-53 R - ATCCGTCACACCTGCTCTTAAGCCACATTATTCGGTGTT |
| CCATGTGTTCCGCCGTGGTGTTGGCTCCCGTAT |
| SEQ ID NO. 177 EcO-54 F - ATACGGGAGCCAACACCAGCGTGGTGGACGTATAACAA |
| GACAGAAGTAACCCGTAGAGCAGGTGTGACGGAT |
| SEQ ID NO. 178 EcO-54 R - ATCCGTCACACCTGCTCTACGGGTTACTTCTGTCTTGTT |
| ATACGTCCACCACGCTGGTGTTGGCTCCCGTAT |
| SEQ ID NO. 179 EcO-55 R (71) - ATACGGGAGCCAACACCATGACAAACATCAATGCA |
| GCAAAGACTAGCAACGTGAGAGCAGGTGTGACGGAT |
| SEQ ID NO. 180 EcO-55 F (71) - ATCCGTCACACCTGCTCTCACGTTGCTAGTCTTTG |
| CTGCATTGATGTTTGTCATGGTGTTGGCTCCCGTAT |
| SEQ ID NO. 181 EcO-56 F (71) - ATACGGGAGCCAACACCAGCCGGCAATGGCTGAG |
| AGAGAATAGAGCGTGGTATAGAGCAGGTGTGACGGAT |
| SEQ ID NO. 182 EcO-56 R (71) - ATCCGTCACACCTGCTCTATACCACGCTCTATTCT |
| CTCTCAGCCATTGCCGGCTGGTGTTGGCTCCCGTAT |
| SEQ ID NO. 183 EcO-57 F - ATACGGGAGCCAACACCAAGGGGGCGGCGAGTCGTAG |
| CGTCGATAATACTGGACAGAGCAGGTGTGACGGAT |
| SEQ ID NO. 184 EcO-57 R - ATCCGTCACACCTGCTCTGTCCAGTATTATCGACGCTA |
| CGACTCGCCGCCCCCTTGGTGTTGGCTCCCGTAT |
| SEQ ID NO. 185 EcO-58 F - ATACGGGAGCCAACACCAGCCCGGAGCCCTTCGTCTGC |
| CCGCAGTCCAGTGTATAGAGCAGGTGTGACGGAT |
| SEQ ID NO. 186 EcO-58 R - ATCCGTCACACCTGCTCTATACACTGGACTGCGGGCAG |
| ACGAAGGGCTCCGGGCTGGTGTTGGCTCCCGTAT |
| SEQ ID NO. 187 EcO-59 F - ATACGGGAGCCAACACCATCCGCGCCCCCGCGGCATCC |
| GCTCACGCGTCCCGGCAGAGCAGGTGTGACGGAT |
| SEQ ID NO. 188 EcO-59 R - ATCCGTCACACCTGCTCTGCCGGGACGCGTGAGCGGAT |
| GCCGCGGGGGCGCGGATGGTGTTGGCTCCCGTAT |
| SEQ ID NO. 189 EcO-60B F - ATACGGGAGCCAACACCATGCAGGACAAAGCGATGA |
| GATACGATCTACCGCTCGAGAGCAGGTGTGACGGAT |
| SEQ ID NO. 190 EcO-60B R - ATCCGTCACACCTGCTCTCGAGCGGTAGATCGTATCT |
| CATCGCTTTGTCCTGCATGGTGTTGGCTCCCGTAT |
| SEQ ID NO. 191 EcO-62 F - ATACGGGAGCCAACACCATGGAGAGGAAGACGGAAA |
| GTATGGAGTGGATGAAGGAGAGCAGGTGTGACGGAT |
| SEQ ID NO. 192 EcO-62 R - ATCCGTCACACCTGCTCTCCTTCATCCACTCCATACTTT |
| CCGTCTTCCTCTCCATGGTGTTGGCTCCCGTAT |
| SEQ ID NO. 193 EcO-63 F - ATACGGGAGCCAACACCACGAAGGAGTAAAGCATGCT |
| GTCCCTATGAGCTGGGAAGAGCAGGTGTGACGGAT |
| SEQ ID NO. 194 EcO-63 R - ATCCGTCACACCTGCTCTTCCCAGCTCATAGGGACAGC |
| ATGCTTTACTCCTTCGTGGTGTTGGCTCCCGTAT |
| SEQ ID NO. 195 EcO-64 F - ATACGGGAGCCAACACCACCCTGAGACATACCTAGTCA |
| AGTGGAACAGACAGGTAGAGCAGGTGTGACGGAT |
| SEQ ID NO. 196 EcO-64 R - ATCCGTCACACCTGCTCTACCTGTCTGTTCCACTTGACT |
| AGGTATGTCTCAGGGTGGTGTTGGCTCCCGTAT |
| SEQ ID NO. 197 EcO-65 F - ATACGGGAGCCAACACCAGTAGGGAGAAGTTCGAATG |
| AAAATACGCTACGAACAAGAGCAGGTGTGACGGAT |
| SEQ ID NO. 198 EcO-65 R - ATCCGTCACACCTGCTCTTGTTCGTAGCGTATTTTCATT |
| CGAACTTCTCCCTACTGGTGTTGGCTCCCGTAT |
| SEQ ID NO. 199 EcO-66 F - ATACGGGAGCCAACACCACTCCCTACCGGCTCTGCGGG |
| AAATATGTTTTGACCCAGAGCAGGTGTGACGGAT |
| SEQ ID NO. 200 EcO-66 R - ATCCGTCACACCTGCTCTGGGTCAAAACATATTTCCCG |
| CAGAGCCGGTAGGGAGTGGTGTTGGCTCCCGTAT |
| SEQ ID NO. 201 EcO-67 F - ATACGGGAGCCAACACCACCCGTGGCCTTCACCCAGCC |
| AGGGGCCCCGTCTCTGAGAGCAGGTGTGACGGAT |
| SEQ ID NO. 202 EcO-67 R - ATCCGTCACACCTGCTCTCAGAGACGGGGCCCCTGGCT |
| GGGTGAAGGCCACGGGTGGTGTTGGCTCCCGTAT |
| SEQ ID NO. 203 EcO-68 F - ATACGGGAGCCAACACCACAAAGTCCTCCCCCCTGGGC |
| GCCTTCACCCCACTGCAGAGCAGGTGTGACGGAT |
| SEQ ID NO. 204 EcO-68 R - ATCCGTCACACCTGCTCTGCGGTGGGGTGAAGGCGCCC |
| AGGGGGGAGGACTTTGTGGTGTTGGCTCCCGTAT |
| SEQ ID NO. 205 EcO-69 R - ATACGGGAGCCAACACCATGGTAGACAGCGTCGCCCT |
| GCCATCACTCCGGCCCCAGAGCAGGTGTGACGGAT |
| SEQ ID NO. 206 EcO-69 F - ATCCGTCACACCTGCTCTGGGGCCGGAGTGATGGCAGG |
| GCGACGCTGTCTACCATGGTGTTGGCTCCCGTAT |
| SEQ ID NO. 207 EcO-70 F - ATACGGGAGCCAACACCACGATCCCGGCGCGACGGAT |
| GTAAAATAAGTGTGCTCAGAGCAGGTGTGACGGAT |
| SEQ ID NO. 208 EcO-70 R - ATCCGTCACACCTGCTCTGAGCACACTTATTTTACATCC |
| GTCGCGCCGGGATCGTGGTGTTGGCTCCCGTAT |
| SEQ ID NO. 209 EcO-71 F - ATACGGGAGCCAACACCAGGGAAGATATGCAACAGAT |
| GGTGGACCGTAGTATGGAGAGCAGGTGTGACGGAT |
| SEQ ID NO. 210 EcO-71 R - ATCCGTCACACCTGCTCTCCATACTACGGTCCACCATCT |
| GTTGCATATCTTCCCTGGTGTTGGCTCCCGTAT |
| SEQ ID NO. 211 EcO-72 F - ATACGGGAGCCAACACCACAGCAGGGTACTGTAGTGG |
| TGGGGGGCCGGTCCGGGAGAGCAGGTGTGACGGAT |
| SEQ ID NO. 212 EcO-72 R - ATCCGTCACACCTGCTCTCCCGGACCGGCCCCCCACCA |
| CTACAGTACCCTGCTGTGGTGTTGGCTCCCGTAT |
| SEQ ID NO. 213 EcO-73 F - ATACGGGAGCCAACACCAAGACGGACAGGGGACGTCG |
| GTGAAGCGACGGATTGGAGAGCAGGTGTGACGGAT |
| SEQ ID NO. 214 EcO-73 R - ATCCGTCACACCTGCTCTCCAATCCGTCGCTTCACCGA |
| CGTCCCCTGTCCGTCTTGGTGTTGGCTCCCGTAT |
| SEQ ID NO. 215 EcO-74 F - ATACGGGAGCCAACACCACACGAGCCAGGTAAAAGTA |
| AGCCACACAAAGTGCTCAGAGCAGGTGTGACGGAT |
| SEQ ID NO. 216 EcO-74 R - ATCCGTCACACCTGCTCTGAGCACTTTGTGTGGCTTACT |
| TTTACCTGGCTCGTGTGGTGTTGGCTCCCGTAT |
| SEQ ID NO. 217 EcO-75 F - ATACGGGAGCCAACACCACCACGCGACACCCCCTCCT |
| GTCCCCCGCCCGCTTCCAGAGCAGGTGTGACGGAT |
| SEQ ID NO. 218 EcO-75 R - ATCCGTCACACCTGCTCTGGAAGCGGGCGGGGGACAG |
| GAGGGGGTGTCGCGTGGTGGTGTTGGCTCCCGTAT |
| Aged E. coli (AEc; Greater than one month at 4° C.) |
| SEQ ID NO. 219 AEc-47F - ATACGGGAGCCAACACCATCGAGAAGCATTGATAACAA |
| AATTTAAACCCCTGCCAGAGCAGGTGTGACGGAT |
| SEQ ID NO. 220 AEc-47R - ATCCGTCACACCTGCTCTGGCAGGGGTTTAAATTTTGTT |
| ATCAATGCTTCTCGATGGTGTTGGCTCCCGTAT |
| SEQ ID NO. 221 AEc-48 F - ATACGGGAGCCAACACCATCGAGAAGCATTGATAACA |
| AAATTTAAACCCCTGCCAGAGCAGGTGTGACGGAT |
| SEQ ID NO. 222 AEc-48R - ATCCGTCACACCTGCTCTGGCAGGGGTTTAAATTTTGTT |
| ATCAATGCTTCTCGATGGTGTTGGCTCCCGTAT |
| SEQ ID NO. 223 AEc-49 F - ATACGGGAGCCAACACCAGGATCCGTAGAATGATTTA |
| AATAAACACGAACACATAGAGCAGGTGTGACGGAT |
| SEQ ID NO. 224 AEc-49R - ATCCGTCACACCTGCTCTATGTGTTCGTGTTTATTTAAA |
| TCATTCTACGGATCCTGGTGTTGGCTCCCGTAT |
| LPS Core Antigen DNA ligands |
| SEQ ID NO. 225 (Glucosamine(G)1F) - ATCCGTCACACCTGCTCTAATTAGGATACG |
| GGGCAACAGAACGAGAGGGGGGAATGGTGTTGGCTCCCGTAT |
| SEQ ID NO. 226 (G2F) - ATCCGTCACACCTGCTCTCGGACCAGGTCAGACAAGCACAT |
| CGGATATCCGGCTGGTGTTGGCTCCCGTAT |
| SEQ ID NO. 227 (G5F) - ATCCGTCACACCTGCTCTTGAGTCAAAGAGTTTAGGGAGGA |
| GCTAACATAACAGTGGTGTTGGCTCCCGTAT |
| SEQ ID NO. 228 (G7F) - ATCCGTCACACCTGCTCTAACAACAATGCATCAGCGGGCTG |
| GGAACGCATGCGGTGGTGTTGGCTCCCGTAT |
| SEQ ID NO. 229 (G8F) - ATCCGTCACACCTGCTCTGAACAGGTTATAAGCAGGAGTGA |
| TAGTTTCAGGATCTGGTGTTGGCTCCCGTAT |
| SEQ ID NO. 230 (G9F) - ATCCGTCACACCTGCTCTCGGCGGCTCGCAAACCGAGTGGT |
| CAGCACCCGGGTTGGTGTTGGCTCCCGTAT |
| SEQ ID NO. 231 (G10F) - ATCCGTCACACCTGCTCTGCGCAAGACGTAATCCACAAGA |
| CCGTGAAAACATAGTGGTGTTGGCTCCCGTAT |
| SEQ ID NO. 232 (G1R) - ATACGGGAGCCAACACCATTCCCCCCTCTCGTTCTGTTGCC |
| CCGTATCCTAATTAGAGCAGGTGTGACGGAT |
| SEQ ID NO. 233 (G2R) - ATACGGGAGCCAACACCAGCCGGATATCCGATGTGCTTGTC |
| TGACCTGGTCCGAGAGCAGGTGTGACGGAT |
| SEQ ID NO. 234 (G5R) - ATACGGGAGCCAACACCACTGTTATGTTAGCTCCTCCCTAA |
| ACTCTTTGACTCAAGAGCAGGTGTGACGGAT |
| SEQ ID NO. 235 (G7R) - ATACGGGAGCCAACACCACCGCATGCGTTCCCAGCCCGCTG |
| ATGCATTGTTGTTAGAGCAGGTGTGACGGAT |
| SEQ ID NO. 236 (G8R) - ATACGGGAGCCAACACCAGATCCTGAAACTATCACTCCTG |
| CTTATAACCTGTTCAGAGCAGGTGTGACGGAT |
| SEQ ID NO. 237 (G9R) - ATACGGGAGCCAACACCAACCCGGGTGCTGACCACTCGGT |
| TTGCGAGCCGCCGAGAGCAGGTGTGACGGAT |
| SEQ ID NO. 238 (G10R) - ATACGGGAGCCAACACCACTATGTTTTCACGGTCTTGTGG |
| ATTACGTCTTGCGCAGAGCAGGTGTGACGGAT |
| SEQ ID NO. 239 (KDO (K) Antigen 2F) - ATCCGTCACACCTGCTCTAGGCGTAGTG |
| ACTAAGTCGCGCGAAAATCACAGCATTGGTGTTGGCTCCCGTAT |
| SEQ ID NO. 240 (K5F) - ATCCGTCACACCTGCTCTCAGCGGCAGCTATACAGTGAGAA |
| CGGACTAGTGCGTTGGTGTTGGCTCCCGTAT |
| SEQ ID NO. 241 (K7F) - ATCCGTCACACCTGCTCTGGCAAATAATACTAGCGATGATG |
| GATCTGGATAGACTGGTGTTGGCTCCCGTAT |
| SEQ ID NO. 242 (K8F) - ATCCGTCACACCTGCTCTGGGGGTGCGACTTAGGGTAAGTG |
| GGAAAGACGATGCTGGTGTTGGCTCCCGTAT |
| SEQ ID NO. 243 (K9F) - ATCCGTCACACCTGCTCTCAAGAGGAGATGAACCAATCTTA |
| GTCCGACAGGCGGTGGTGTTGGCTCCCGTAT |
| SEQ ID NO. 244 (K10F) - ATCCGTCACACCTGCTCTGGCCCGGAATTGTCATGACGTC |
| ACCTACACCTCCTGTGGTGTTGGCTCCCGTAT |
| SEQ ID NO. 245 (K2R) - ATACGGGAGCCAACACCAATGCTGTGATTTTCGCGCGACTT |
| AGTCACTACGCCTAGAGCAGGTGTGACGGAT |
| SEQ ID NO. 246 (K5R) - ATACGGGAGCCAACACCAACGCACTAGTCCGTTCTCACTGT |
| ATAGCTGCCGCTGAGAGCAGGTGTGACGGAT |
| SEQ ID NO. 247 (K7R) - ATACGGGAGCCAACACCAGTCTATCCAGATCCATCATCGC |
| TAGTATTATTTGCCAGAGCAGGTGTGACGGAT |
| SEQ ID NO. 248 (K8R) - ATACGGGAGCCAACACCAGCATCGTCTTTCCCACTTACCCT |
| AAGTCGCACCCCCAGAGCAGGTGTGACGGAT |
| SEQ ID NO. 249 (K9R) - ATACGGGAGCCAACACCACCGCCTGTCGGACTAAGATTGG |
| TTCATCTCCTCTTGAGAGCAGGTGTGACGGAT |
| SEQ ID NO. 250 (K10R) - ATACGGGAGCCAACACCACAGGAGGTGTAGGTGACGTCA |
| TGACAATTCCGGGCCAGAGCAGGTGTGACGGAT |
| SEQ ID NO. 251 (Whole LPS from E. coli O111:B4 (L)1F) - ATCCGTCAC |
| CCCTGCTCTCGTCGCTATGAAGTAACAAAGATAGGAGCAATCGGGTGGTGTTGGCTCCCGTAT |
| SEQ ID NO. 252 (L3F) - ATCCGTCACACCTGCTCTAACGAAGACTGAAACCAAAGCAG |
| TGACAGTGCTGAATGGTGTTGGCTCCCGTAT |
| SEQ ID NO. 253 (L4F) - ATCCGTCACACCTGCTCTCGGTGACAATAGCTCGATCAGCC |
| C AAAGTCGTCAGATGGTGTTGGCTCCCGTAT |
| SEQ ID NO. 254 (L6F) - ATCCGTCACACCTGCTCTAACGAAATAGACCACAAATCGAT |
| ACTTTATGTTATTGGTGTTGGCTCCCGTAT (71) |
| SEQ ID NO. 255 (L7F) - ATCCGTCACACCTGCTCTGTCGAATGCTCTGCCTGGAAGAG |
| TTGTTAGCAGGGATGGTGTTGGCTCCCGTAT |
| SEQ ID NO. 256 (L8F) - ATCCGTCACACCTGCTCTTAAGCCGAGGGGTAAATCTAGGA |
| CAGGGGTCCATGATGGTGTTGGCTCCCGTAT |
| SEQ ID NO. 256 (L9F) - ATCCGTCACACCTGCTCTACTGGCCGGCTCAGCATGACTAA |
| GAAGGAAGTTATGTGGTGTTGGCTCCCGTAT |
| SEQ ID NO. 258 (L10F) - ATCCGTCACACCTGCTCTGGTACGAATCACAGGGGATGCT |
| GGAAGCTTGGCTCTTGGTGTTGGCTCCCGTAT |
| SEQ ID NO. 259 (L1R) - ATACGGGAGCCAACACCACCCGATTGCTCCTATCTTTGTTA |
| CTTCATAGCGACGAGAGCAGGGGTGACGGAT |
| SEQ ID NO. 260 (L3R) - ATACGGGAGCCAACACCATTCAGCACTGTCACTGCTTTGGT |
| TTCAGTCTTCGTTAGAGCAGGTGTGACGGAT |
| SEQ ID NO. 261 (L4R) - ATACGGGAGCCAACACCATCTGACGACTTTGGGCTGATCGA |
| GCTATTGTCACCGAGAGCAGGTGTGACGGAT |
| SEQ ID NO. 262 (L6R) - ATACGGGAGCCAACACCAATAACATAAAGTATCGATTTGTG |
| GTCTATTTCGTTAGAGCAGGTGTGACGGAT |
| SEQ ID NO. 263 (L7R) - ATACGGGAGCCAACACCATCCCTGCTAACAACTCTTCCAGG |
| CAGAGCATTCGACAGAGCAGGTGTGACGGAT |
| SEQ ID NO. 264 (L8R) - ATACGGGAGCCAACACCATCATGGACCCCTGTCCTAGATTT |
| ACCCCTCGGCTTAAGAGCAGGTGTGACGGAT |
| SEQ ID NO. 265 (L9R) - ATACGGGAGCCAACACCACATAACTTCCTTCTTAGTCATGC |
| TGAGCCGGCCAGTAGAGCAGGTGTGACGGAT |
| SEQ ID NO. 266 (L10R) - ATACGGGAGCCAACACCAAGAGCCAAGCTTCCAGCATCCC |
| CTGTGATTCGTACCAGAGCAGGTGTGACGGAT |
| SEQ ID NO. 267 (Rough (Ra or R) Core LPS Antigens R1F) - ATCCGTC |
| ACACCTGCTCTCCGCACGTAGGACCACTTTGGTACACGCTCCCGTAGTGGTGTTGGCTCCCGTAT |
| SEQ ID NO. 268 (R5F) - ATCCGTCACACCTGCTCTACGGATGAACGAAGATTTTAAAG |
| TCAAGCTAATGCATGGTGTTGGCTCCCGTAT |
| SEQ ID NO. 269 (R6F) - ATCCGTCACACCTGCTCTGTAGTGAAGAGTCCGCAGTCCAC |
| GCTGTTCAACTCATGGTGTTGGCTCCCGTAT |
| SEQ ID NO. 270 (R7F) - ATCCGTCACACCTGCTCTACCGGCTGGCACGGTTATGTGTGA |
| CGGGCGAAGATATGGTGTTGGCTCCCGTAT |
| SEQ ID NO. 271 (R9F) - ATCCGTCACACCTGCTCTGCGTGTGGAGCGCCTAGGTGAGT |
| GGTGTTGGCTCCCGTAT |
| SEQ ID NO. 272 (R10F) - ATCCGTCACACCTGCTCTGATGTCCCTTTGAAGAGTTCCAT |
| GACGCTGGCTCCTTGGTGTTGGCTCCCGTAT |
| SEQ ID NO. 273 (R1R) - ATACGGGAGCCAACACCACTACGGGAGCGTGTACCAAAGT |
| GGTCCTACGTGCGGAGAGCAGGTGTGACGGAT |
| SEQ ID NO. 274 (R5R) - ATACGGGAGCCAACACCATGCATTAGCTTGACTTTAAAATC |
| TTCGTTCATCCGTAGAGCAGGTGTGACGGAT |
| SEQ ID NO. 275 (R6R) - ATACGGGAGCCAACACCATGAGTTGAACAGCGTGGACTGC |
| GGACTCTTCACTACAGAGCAGGTGTGACGGAT |
| SEQ ID NO. 276 (R7R) - ATACGGGAGCCAACACCATATCTTCGCCCGTCACACATAAC |
| CGTGCCAGCCGGTAGAGCAGGTGTGACGGAT |
| SEQ ID NO. 277 (R9R) - ATACGGGAGCCAACACCACTCACCTAGGCGCTCCACACGC |
| AGAGCAGGTGTGACGGAT |
| SEQ ID NO. 278 (R10R) - ATACGGGAGCCAACACCAAGGAGCCAGCGTCATGGAACTC |
| TTCAAAGGGACATCAGAGCAGGTGTGACGGAT |
| Listeriolysin (A surface protein on Listeria monocytogenes) DNA |
| ligands |
| SEQ ID NO. 279 (LO-10F) - ATCCGTCACACCTGCTCTGCCGGACCATCCAATATCAGC |
| TGTGGTGTTGGCTCCCGTAT |
| SEQ ID NO. 280 (LO-11F) - ATCCGTCACACCTGCTCTGGTGGAATGGACTAAGCTAGC |
| TAGCGTTTTAAAAGGTGGTGTTGGCTCCCGTAT |
| SEQ ID NO. 281 (LO-13F) - ATCCGTCACACCTGCTCTTAAAGTAGAGGCTGTTCTCCA |
| GACGTCGCAGGAGGATGGTGTTGGCTCCCGTAT |
| SEQ ID NO. 282 (LO-15F) - ATCCGTCACACCTGCTCTGTAGATGGCAAGGCATAAGCG |
| TCCGGAACGATAGAATGGTGTTGGCTCCCGTAT |
| SEQ ID NO. 283 (LO-16F) - ATCCGTCACACCTGCTCTGTAGATGGCAAGGCATAAGCG |
| TCCGGAACGATAGAATGGTGTTGGCTCCCGTAT |
| SEQ ID NO. 284 (LO-17F) - ATACGGGAGCCAACACCACAGCTGATATTGGATGGTCC |
| GGCAGAGCAGGTGTGACGGAT |
| SEQ ID NO. 285 (LO-19F) - ATCCGTCACACCTGCTCTTGGGCAGGAGCGAGAGACTCT |
| AATGGTAAGCAAGAATGGTGTTGGCTCCCGTAT |
| SEQ ID NO. 286 (LO-20F) - ATCCGTCACACCTGCTCTCCAACAAGGCGACCGACCGCA |
| TGCAGATAGCCAGGTTGGTGTTGGCTCCCGTAT |
| SEQ ID NO. 287 (LO-10R) - ATACGGGAGCCAACACCACAGCTGATATTGGATGGTCC |
| GGCAGAGCAGGTGTGACGGAT |
| SEQ ID NO. 288 (LO-11R) - ATACGGGAGCCAACACCACCTTTTAAAACGCTAGCTAG |
| CTTAGTCCATTCCACCAGAGCAGGTGTGACGGAT |
| SEQ ID NO. 289 (LO-13R) - ATACGGGAGCCAACACCATCCTCCTGCGACGTCTGGAGA |
| ACAGCCTCTACTTTAAGAGCAGGTGTGACGGAT |
| SEQ ID NO. 290 (LO-15R) - ATACGGGAGCCAACACCATTCTATCGTTCCGGACGCTTA |
| TGCCTTGCCATCTACAGAGCAGGTGTGACGGAT |
| SEQ ID NO. 291 (LO-16R) - ATACGGGAGCCAACACCATTCTATCGTTCCGGACGCTTA |
| TGCCTTGCCATCTACAGAGCAGGTGTGACGGAT |
| SEQ ID NO. 292 (LO-17R) - ATCCGTCACACCTGCTCTGCCGGACCATCCAATATCAGC |
| TGTGGTGTTGGCTCCCGTAT |
| SEQ ID NO. 293 (LO-19R) - ATACGGGAGCCAACACCATTCTTGCTTACCATTAGAGTC |
| TCTCGCTCCTGCCCAAGAGCAGGTGTGACGGAT |
| SEQ ID NO. 294 (LO-20R) - ATACGGGAGCCAACACCAACCTGGCTATCTGCATGCGGT |
| CGGTCGCCTTGTTGGAGAGCAGGTGTGACGGAT |
| Listeriolysin (Alternate form of Listeria surface protein |
| designated “Pest-Free”) DNA ligands |
| SEQ ID NO. 295 (LP-3F) - ATCCGTCACACCTGCTCTGTAGATGGCAAGGCATAAGCGT |
| CCGGAACGATAGAATGGTGTTGGCTCCCGTAT |
| SEQ ID NO. 296 (LP-11F) - ATCCGTCACACCTGCTCTAACCAAAAGGGTAGGAGACCA |
| AGCTAGCGATTTGGATGGTGTTGGCTCCCGTAT |
| SEQ ID NO. 297 (LP-13F) - ATCCGTCACACCTGCTCTGCCGGACCATCCAATATCAGCT |
| GTGGTGTTGGCTCCCGTAT |
| SEQ ID NO. 298 (LP-14F) - ATCCGTCACACCTGCTCTGAAGCCTAACGGAGAAGATGG |
| CCCTACTGCCGTAGGTGGTGTTGGCTCCCGTAT |
| SEQ ID NO. 299 (LP-15F) - ATCCGTCACACCTGCTCTACTAAACAAGGGCAAACTGTA |
| AACACAGTAGGGGCGTGGTGTTGGCTCCCGTAT |
| SEQ ID NO. 300 (LP-17F) - ATCCGTCACACCTGCTCTGGTGTTGGCTCCCGTATAGCTT |
| GGCTCCCGTATGGTGTTGGCTCCCGTAT |
| SEQ ID NO. 301 (LP-18F) - TCCGTCACACCTGCTCTGTCGCGATGATGAGCAGCAGCG |
| CAGGAGGGAGGGGGTGGTGTTGGCTCCCGTAT |
| SEQ ID NO. 302 (LP-20F) - ATCCGTCACACCTGCTCTGATCAGGGAAGACGCCAACAC |
| TGGTGTTGGCTCCCGTAT |
| SEQ ID NO. 303 (LP-3R) - ATACGGGAGCCAACACCATTCTATCGTTCCGGACGCTTA |
| TGCCTTGCCATCTACAGAGCAGGTGTGACGGAT |
| SEQ ID NO. 304 (LP-11R) - ATACGGGAGCCAACACCATCCAAATCGCTAGCTTGGTC |
| TCCTACCCTTTTGGTTAGAGCAGGTGTGACGGAT |
| SEQ ID NO. 305 (LP-13R) - ATACGGGAGCCAACACCACAGCTGATATTGGATGGTCCG |
| GCAGAGCAGGTGTGACGGAT |
| SEQ ID NO. 306 (LP-14R) - ATACGGGAGCCAACACCACCTACGGCAGTAGGGCCATC |
| TTCTCCGTTAGGCTTCAGAGCAGGTGTGACGGAT |
| SEQ ID NO. 307 (LP-15R) - ATACGGGAGCCAACACCACGCCCCTACTGTGTTTACAG |
| TTTGCCCTTGTTTAGTAGAGCAGGTGTGACGGAT |
| SEQ ID NO. 308 (LP-17R) - ATACGGGAGCCAACACCATACGGGAGCCAAGCTATACG |
| GGAGCCAACACCAGAGCAGGTGTGACGGAT |
| SEQ ID NO. 309 (LP-18R) - ATACGGGAGCCAACACCACCCCCTCCCTCCTGCGCTGCT |
| GCTCATCATCGCGACAGAGCAGGTGTGACGGAT |
| SEQ ID NO. 310 (LP-20R) - ATACGGGAGCCAACACCAGTGTTGGCGTCTTCCCTGATC |
| AGAGCAGGTGTGACGGAT |
| Listeria monocytogenes Whole Cell (LmW) |
| SEQ ID NO. 311 LmW-2 F - ATACGGGAGCCAACACCAATACCTGTAAAAGTCTGAG |
| AAGTGGAGTAACCTAGAGAGCAGGTGTGACGGAT (71) |
| SEQ ID NO. 312 LmW-2 R - ATCCGTCACACCTGCTCTCTAGGTTACTCCACTTCTCA |
| GACTTTTACAGGTATTGGTGTTGGCTCCCGTAT (71) |
| SEQ ID NO. 313 LmW-3 F - ATACGGGAGCCAACACCACCGACCAACAGTAATAGCC |
| TAAAAGAGTTATGCGCTAGAGCAGGTGTGACGGAT |
| SEQ ID NO. 314 LmW-3 R - ATCCGTCACACCTGCTCTAGCGCATAACTCTTTTAGGCT |
| ATTACTGTTGGTCGGTGGTGTTGGCTCCCGTAT |
| SEQ ID NO. 315 LmW-5 F - ATACGGGAGCCAACACCAGGTGGACTATATATGAAGTT |
| AGTGAGCTTTAACAGGAGAGCAGGTGTGACGGAT |
| SEQ ID NO. 316 LmW-5 R - ATCCGTCACACCTGCTCTCCTGTTAAAGCTCACTAACT |
| TCATATATAGTCCACCTGGTGTTGGCTCCCGTAT |
| SEQ ID NO. 317 LmW-8 F - ATACGGGAGCCAACACCACAGGAGAGGCAGTAAAAG |
| GGTTGGCTGCCTGGGTAGAGAGCAGGTGTGACGGAT |
| SEQ ID NO. 318 LmW-8 R - ATCCGTCACACCTGCTCTCTACCCAGGCAGCCAACCCT |
| TTTACTGCCTCTCCTGTGGTGTTGGCTCCCGTAT |
| SEQ ID NO. 319 LmW-9 F - ATACGGGAGCCAACACCATTAGCAAGGTAAGAACAGT |
| TTTAATACATGCCTTCCAGAGCAGGTGTGACGGAT |
| SEQ ID NO. 320 LmW-9 R - ATCCGTCACACCTGCTCTGGAAGGCATGTATTAAAACT |
| GTTCTTACCTTGCTAATGGTGTTGGCTCCCGTAT |
| SEQ ID NO. 321 LmW-10 F - ATACGGGAGCCAACACCATAACAAATAACCACCCTC |
| AATGCTAGATAGTGGCTTAGAGCAGGTGTGACGGAT |
| SEQ ID NO. 322 LmW-10 R - ATCCGTCACACCTGCTCTAAGCCACTATCTAGCATTGA |
| GGGTGGTTATTTGTTATGGTGTTGGCTCCCGTAT |
| SEQ ID NO. 323 LmW-11 F - ATACGGGAGCCAACACCAGGAACATGATAAGTGAGA |
| AGTGCGACGTTAGCTTATAGAGCAGGTGTGACGGAT |
| SEQ ID NO. 324 LmW-11 R - ATCCGTCACACCTGCTCTATAAGCTAACGTCGCACTTC |
| TCACTTATCATGTTCCTGGTGTTGGCTCCCGTAT |
| SEQ ID NO. 325 LmW-12 F - ATACGGGAGCCAACACCAAAAGGGTGTTCATACGGA |
| ATGTAGATCGCCTAAGTGAGAGCAGGTGTGACGGAT |
| SEQ ID NO. 326 LmW-12 R - ATCCGTCACACCTGCTCTCACTTAGGCGATCTACATTC |
| CGTATGAACACCCTTTTGGTGTTGGCTCCCGTAT |
| SEQ ID NO. 327 LmW-13 F - ATACGGGAGCCAACACCATGAGCACCGGCAAACGCG |
| TAGGTTAAGCTACATGACAGAGCAGGTGTGACGGAT |
| SEQ ID NO. 328 LmW-13 R - ATCCGTCACACCTGCTCTGTCATGTAGCTTAACCTACG |
| CGTTTGCCGGTGCTCATGGTGTTGGCTCCCGTAT |
| SEQ ID NO. 329 LmW-14 F - ATACGGGAGCCAACACCATGATTAGATACTGCCTAGC |
| TGTGTGCTCGTTGGGGGAGAGCAGGTGTGACGGAT |
| SEQ ID NO. 330 LmW-14 R - ATCCGTCACACCTGCTCTCCCCCAACGAGCACACAGC |
| TAGGCAGTATCTAATCATGGTGTTGGCTCCCGTAT |
| SEQ ID NO. 331 LmW-19 F - ATACGGGAGCCAACACCAGGAGGAAGGTCAGCGTTC |
| TTCACGTGGCTAGGGGGCAGAGCAGGTGTGACGGAT |
| SEQ ID NO. 332 LmW-19 R - ATCCGTCACACCTGCTCTGCCCCCTAGCCACGTGAAG |
| AACGCTGACCTTCCTCCTGGTGTTGGCTCCCGTAT |
| SEQ ID NO. 333 LmW-22 F - ATACGGGAGCCAACACCAACTGAGCTATATCTAGATC |
| GACTTACACATACACGTAGAGCAGGTGTGACGGAT |
| SEQ ID NO. 334 LmW-22 R - ATCCGTCACACCTGCTCTACGTGTATGTGTAAGTCGAT |
| CTAGATATAGCTCAGTTGGTGTTGGCTCCCGTAT |
| SEQ ID NO. 335 LmW-23 F - ATACGGGAGCCAACACCAGAGACGTGTGAAGTCCAG |
| G CAGGGTGCCTTCTGTCGAGAGCAGGTGTGACGGAT |
| SEQ ID NO. 336 LmW-23 R - ATCCGTCACACCTGCTCTCGACAGAAGGCACCCTGCC |
| TGGACTTCACACGTCTCTGGTGTTGGCTCCCGTAT |
| SEQ ID NO. 337 LmW-24 F - ATACGGGAGCCAACACCATCAAGTGGTGAGCGCCTCG |
| TCGGGAACTGCCGTGCGAGAGCAGGTGTGACGGAT |
| SEQ ID NO. 338 LmW-24 R - ATCCGTCACACCTGCTCTCGCACGGCAGTTCCCGACG |
| AGGCGCTCACCACTTGATGGTGTTGGCTCCCGTAT |
| SEQ ID NO. 339 LmW-25 F - ATACGGGAGCCAACACCACCGCTGAAACCTCTCCGCC |
| GTCCCGCCCTCCTCCCCAGAGCAGGTGTGACGGAT |
| SEQ ID NO. 340 LmW-25 R - ATCCGTCACACCTGCTCTGGGGAGGAGGGCGGGACGG |
| CGGAGAGGTTTCAGCGGTGGTGTTGGCTCCCGTAT |
| SEQ ID NO. 341 LmW-27 F - ATACGGGAGCCAACACCAGGAGATGGTAGCACTAAA |
| ATACGACGTATGCTGTGTAGAGCAGGTGTGACGGAT |
| SEQ ID NO. 342 LmW-27 R - ATCCGTCACACCTGCTCTACACAGCATACGTCGTATTT |
| TAGTGCTACCATCTCCTGGTGTTGGCTCCCGTAT |
| SEQ ID NO. 343 LmW-28 F - ATACGGGAGCCAACACCAAATCGACCGGACTAATCCT |
| GTGACTCCCCTATGTCTAGAGCAGGTGTGACGGAT |
| SEQ ID NO. 344 LmW-28 R - ATCCGTCACACCTGCTCTAGACATAGGGGAGTCACAG |
| G ATTAGTCCGGTCGATTTGGTGTTGGCTCCCGTAT |
| SEQ ID NO. 345 LmW-30 F - ATACGGGAGCCAACACCAAATTCAATTGCGCACGTAA |
| GAATAGATAGGCTGACCAGAGCAGGTGTGACGGAT |
| SEQ ID NO. 346 LmW-30 R - ATCCGTCACACCTGCTCTGGTCAGCCTATCTATTCTTA |
| CGTGCGCAATTGAATTTGGTGTTGGCTCCCGTAT |
| SEQ ID NO. 347 LmW-31 F - ATACGGGAGCCAACACCACACACAGAGCGCCATGGA |
| CTCAGTCAGATGTGATGTAGAGCAGGTGTGACGGAT |
| SEQ ID NO. 348 LmW-31 R - ATCCGTCACACCTGCTCTACATCACATCTGACTGAGT |
| CCATGGCGCTCTGTGTGTGGTGTTGGCTCCCGTAT |
| SEQ ID NO. 349 LmW-32 F - ATACGGGAGCCAACACCATCCAATGAGGCCATGGACC |
| GGTAAACTCGGACGCGCAGAGCAGGTGTGACGGAT |
| SEQ ID NO. 350 LmW-32 R - ATCCGTCACACCTGCTCTGCGCGTCCGAGTTTACCGGT |
| CCATGGCCTCATTGGATGGTGTTGGCTCCCGTAT |
| SEQ ID NO. 351 LmW-33 F - ATACGGGAGCCAACACCAACCCCGGTACCATCCGAC |
| ACCACGAGCACCCGGACGAGAGCAGGTGTGACGGAT |
| SEQ ID NO. 352 LmW-33 R - ATCCGTCACACCTGCTCTCGTCCGGGTGCTCGTGGTGT |
| CGGATGGTACCGGGGTTGGTGTTGGCTCCCGTAT |
| SEQ ID NO. 353 LmW-34 F - ATACGGGAGCCAACACCAAGGCGAAACTATTCACAG |
| AGACTGATCCAGCAAGGTAGAGCAGGTGTGACGGAT |
| SEQ ID NO. 354 LmW-34 R - ATCCGTCACACCTGCTCTACCTTGCTGGATCAGTCTCT |
| GTGAATAGTTTCGCCTTGGTGTTGGCTCCCGTAT |
| SEQ ID NO. 355 LmW-35 F - ATACGGGAGCCAACACCAAACACATAGTCGTGGCAG |
| AACGAATACTTAGCGCGGAGAGCAGGTGTGACGGAT |
| SEQ ID NO. 356 LmW-35 R - ATCCGTCACACCTGCTCTCCGCGCTAAGTATTCGTTCT |
| GCCACGACTATGTGTTTGGTGTTGGCTCCCGTAT |
| SEQ ID NO. 357 LmW-36 F - ATACGGGAGCCAACACCAACACGATCGACGGCGCTT |
| GGTCCCTTACAACCCTGCAGAGCAGGTGTGACGGAT |
| SEQ ID NO. 358 LmW-36 R - ATCCGTCACACCTGCTCTGCAGGGTTGTAAGGGACCA |
| AGCGCCGTCGATCGTGTTGGTGTTGGCTCCCGTAT |
| SEQ ID NO. 359 LmW-37 F - ATACGGGAGCCAACACCAAACCAGGACTCTGTCGCTC |
| TAAACATGACCATCGATAGAGCAGGTGTGACGGAT |
| SEQ ID NO. 360 LmW-37 R - ATCCGTCACACCTGCTCTATCGATGGTCATGTTTAGA |
| GCGACAGAGTCCTGGTTTGGTGTTGGCTCCCGTAT |
| SEQ ID NO. 361 LmW-39 F - ATACGGGAGCCAACACCACAACCACTGTAGGCTCAT |
| GTAACTACCCGTTGTTGAGAGCAGGTGTGACGGAT (71) |
| SEQ ID NO. 362 LmW-39 R - ATCCGTCACACCTGCTCTCAACAACGGGTAGTTACAT |
| GAGCCTACAGTGGTTGTGGTGTTGGCTCCCGTAT (71) |
| SEQ ID NO. 363 LmW-40 F - ATACGGGAGCCAACACCAGGGGACAAGCAGAACCGA |
| ACAGATTGCAACGTATCCAGAGCAGGTGTGACGGAT |
| SEQ ID NO. 364 LmW-40 R - ATCCGTCACACCTGCTCTGGATACGTTGCAATCTGTTC |
| GGTTCTGCTTGTCCCCTGGTGTTGGCTCCCGTAT |
| SEQ ID NO. 365 LmW-41 F - ATACGGGAGCCAACACCAGCGCTTGAACAACATAAT |
| GCCGCCCAAGACCTTGACAGAGCAGGTGTGACGGAT |
| SEQ ID NO. 366 LmW-41 R - ATCCGTCACACCTGCTCTGTCAAGGTCTTGGGCGGCA |
| TTATGTTGTTCAAGCGCTGGTGTTGGCTCCCGTAT |
| SEQ ID NO. 367 LmW-42 F - ATACGGGAGCCAACACCACAGTGCCTAGACTTTTACA |
| ATGAACCAATTGCTGGAAGAGCAGGTGTGACGGAT |
| SEQ ID NO. 368 LmW-42 R - ATCCGTCACACCTGCTCTTCCAGCAATTGGTTCATTGT |
| AAAAGTCTAGGCACTGTGGTGTTGGCTCCCGTAT |
| SEQ ID NO. 369 LmW-43 F - ATACGGGAGCCAACACCACCCACTCTCCCCCCGCTCC |
| CGCTCCCCCGCTCCGCGAGAGCAGGTGTGACGGAT |
| SEQ ID NO. 370 LmW-43 R - ATCCGTCACACCTGCTCTCGCGGAGCGGGGGAGCGGG |
| AGCGGGGGGAGAGTGGGTGGTGTTGGCTCCCGTAT |
| SEQ ID NO. 371 LmW-44 F - ATACGGGAGCCAACACCATCTAACAATCATACACTTG |
| GAAGGTGACTGTCCTGGAGAGCAGGTGTGACGGAT |
| SEQ ID NO. 372 LmW-44 R - ATCCGTCACACCTGCTCTCCAGGACAGTCACCTTCCA |
| AGTGTATGATTGTTAGATGGTGTTGGCTCCCGTAT |
| SEQ ID NO. 373 LmW-46 F - ATACGGGAGCCAACACCATGTCAGGACCTCCATCGCC |
| CGGGCCCGCCGCCGCTGAGAGCAGGTGTGACGGAT |
| SEQ ID NO. 374 LmW-46 R - ATCCGTCACACCTGCTCTCAGCGGCGGCGGGCCCGGG |
| CGATGGAGGTCCTGACATGGTGTTGGCTCCCGTAT |
| SEQ ID NO. 375 LmW-47 F - ATACGGGAGCCAACACCAGGCGACAGCCTGTGCGAGT |
| AAGATTGAATGGTAGGTAGAGCAGGTGTGACGGAT |
| SEQ ID NO. 376 LmW-47 R - ATCCGTCACACCTGCTCTACCTACCATTCAATCTTACT |
| CGCACAGGCTGTCGCCTGGTGTTGGCTCCCGTAT |
| SEQ ID NO. 377 LmW-49 F - ATACGGGAGCCAACACCATCTGTGTCAGTCTGGCCTG |
| TTTTTTATTCTCCGCGGAGAGCAGGTGTGACGGAT |
| SEQ ID NO. 378 LmW-49 R - ATCCGTCACACCTGCTCTCCGCGGAGAATAAAAAACA |
| GGCCAGACTGACACAGATGGTGTTGGCTCCCGTAT |
| SEQ ID NO. 379 LmW-50 F - ATACGGGAGCCAACACCAGCCAGGAAAACTATGAGG |
| CAAAAACACGATCCGGGTAGAGCAGGTGTGACGGAT |
| SEQ ID NO. 380 LmW-50 R - ATCCGTCACACCTGCTCTACCCGGATCGTGTTTTTGCC |
| TCATAGTTTTCCTGGCTGGTGTTGGCTCCCGTAT |
| N-acetyl-glucosamine (NAG) Component of Bacterial Peptidoglycan |
| and Fungal Chitin |
| SEQ ID NO. 381 NAG 13F - ATACGGGAGCCAACACCATAGAAGTATGTTGTTATTCTA |
| TGGAAATAAAACGACAGAGCAGGTGTGACGGAT |
| SEQ ID NO. 382 NAG 13R - ATCCGTCACACCTGCTCTGTCGTTTTATTTCCATAGAATA |
| ACAACATACTTCTATGGTGTTGGCTCCCGTAT |
| SEQ ID NO. 383 NAG 14F - ATACGGGAGCCAACACCATCCCGTTGTGATCAGAGAGC |
| ATGAAATGATGTTTTGAGAGCAGGTGTGACGGAT |
| SEQ ID NO. 384 NAG 14R - ATCCGTCACACCTGCTCTCAAAACATCATTTCATGCTCT |
| CTGATCACAACGGGATGGTGTTGGCTCCCGTAT |
| SEQ ID NO. 385 NAG 18F - ATACGGGAGCCAACACCATGCATGGGACCTGTTATCCTA |
| ACAAGCTGTCAAGGCAGAGCAGGTGTGACGGAT |
| SEQ ID NO. 386 NAG 18R - ATCCGTCACACCTGCTCTGCCTTGACAGCTTGTTAGGAT |
| AACAGGTCCCATGCATGGTGTTGGCTCCCGTAT |
| SEQ ID NO. 387 NAG 20F - ATACGGGAGCCAACACCACAAAACGTTCCGAGGGAGTA |
| AGCACTTAATAATGTAGAGCAGGTGTGACGGAT (71) |
| SEQ ID NO. 388 NAG 20R - ATCCGTCACACCTGCTCTACATTATTAAGTGCTTACTCCC |
| TCGGAACGTTTTGTGGTGTTGGCTCCCGTAT (71) |
| SEQ ID NO. 389 NAG 21F - ATACGGGAGCCAACACCACGTCTTATAGATGTCTGTATT |
| GTTTATCGCTCGCCCAGAGCAGGTGTGACGGAT |
| SEQ ID NO. 390 NAG 21R - ATCCGTCACACCTGCTCTGGGCGAGCGATAAACAATACA |
| GACATCTATAAGACGTGGTGTTGGCTCCCGTAT |
| SEQ ID NO. 391 NAG 22F - ATACGGGAGCCAACACCACCATCTCTGGTGATAACCAGT |
| GATCTTAACTATAGCAGAGCAGGTGTGACGGAT |
| SEQ ID NO. 392 NAG 22R - ATCCGTCACACCTGCTCTGCTATAGTTAAGATCACTGGT |
| TATCACCAGAGATGGTGGTGTTGGCTCCCGTAT |
| SEQ ID NO. 393 NAG 23F - ATACGGGAGCCAACACCACCACCTCACTACAGTGATCTT |
| TTGCTCTGAATAGCCAGAGCAGGTGTGACGGAT |
| SEQ ID NO. 394 NAG 23R - ATCCGTCACACCTGCTCTGGCTATTCAGAGCAAAAGATC |
| ACTGTAGTGAGGTGGTGGTGTTGGCTCCCGTAT |
| SEQ ID NO. 395 NAG 25F - ATACGGGAGCCAACACCATGTCTCTTAGGATACAAAGCC |
| AAACTGAGCCCGTGCAGAGCAGGTGTGACGGAT |
| SEQ ID NO. 396 NAG 25R - ATCCGTCACACCTGCTCTGCACGGGCTCAGTTTGGCTTT |
| GTATCCTAAGAGACATGGTGTTGGCTCCCGTAT |
| SEQ ID NO. 397 NAG 26F - ATACGGGAGCCAACACCACCTCCAATAGCCAAAAGAAA |
| TCGCCAACTAACGGCAAGAGCAGGTGTGACGGAT |
| SEQ ID NO. 398 NAG 26R - ATCCGTCACACCTGCTCTTGCCGTTAGTTGGCGATTTCTT |
| TTGGCTATTGGAGGTGGTGTTGGCTCCCGTAT |
| SEQ ID NO. 399 NAG 30F - ATACGGGAGCCAACACCATCACTACTTTTATAATTTCATT |
| CTTCTGGCGTCCCTAGAGCAGGTGTGACGGAT |
| SEQ ID NO. 400 NAG 30R - ATCCGTCACACCTGCTCTAGGGACGCCAGAAGAATGAA |
| ATTATAAAAGTAGTGATGGTGTTGGCTCCCGTAT |
| N-acetyl-muramic acid (NAM) Component of Bacterial Peptidoglycan |
| SEQ ID NO. 401 NAM 23F - ATACGGGAGCCAACACCAACTGCCCACGCCGCGACCCC |
| GCGGCGCACCCAACCAAGAGCAGGTGTGACGGAT |
| SEQ ID NO. 402 NAM 23R - ATCCGTCACACCTGCTCTTGGTTGGGTGCGCCGCGGGG |
| TCGCGGCGTGGGCAGTTGGTGTTGGCTCCCGTAT |
| SEQ ID NO. 403 NAM 31F - ATACGGGAGCCAACACCAACGGTTACCAGGCGTGTTAA |
| GGATATATGCTGAACCAGAGCAGGTGTGACGGAT |
| SEQ ID NO. 404 NAM 31R - ATCCGTCACACCTGCTCTGGTTCAGCATATATCCTTAAC |
| ACGCCTGGTAACCGTTGGTGTTGGCTCCCGTAT |
| Salmonella typhimurium lipopolysaccharide (LPS) DNA ligands |
| SEQ ID NO. 405 (St-7F) - ATCCGTCACACCTGCTCTGTCCAAAGGCTACGCGTTAACGT |
| GGTGTTGGCTCCCGTAT |
| SEQ ID NO. 406 (St-10F) - ATCCGTCACACCTGCTCTGGAGCAATATGGTGGAGAAACG |
| TGGTGTTGGCTCCCGTAT |
| SEQ ID NO. 407 (St-11F) - ATCCGTCACACCTGCTCTGCCGGACCATCCAATATCAGCT |
| GTGGTGTTGGCTCCCGTAT |
| SEQ ID NO. 408 (St-15F) - ATCCGTCACACCTGCTCTGAACAGGATAGGGATTAGCGAG |
| TCAACTAAGCAGCATGGTGTTGGCTCCCGTAT |
| SEQ ID NO. 409 (St-16F) - ATCCGTCACACCTGCTCTGGCGGACAGGAAATAAGAATG |
| AACGCAAAATTTATCTGGTGTTGGCTCCCGTAT |
| SEQ ID NO. 410 (St-18F) - ATCCGTCACACCTGCTCTACGCAACGCGACAGGAACATTC |
| ATTATAGAATGTGTTGGTGTTGGCTCCCGTAT |
| SEQ ID NO. 411 (St-19F) - ATCCGTCACACCTGCTCTCGGCTGCAATGCGGGAGAGTAG |
| GGGGGAACCAAACCTGGTGTTGGCTCCCGTAT |
| SEQ ID NO. 412 (St-20F) - ATCCGTCACACCTGCTCTATGACTGGAACACGGGTATCGA |
| TGATTAGATGTCCTTGGTGTTGGCTCCCGTAT |
| SEQ ID NO. 413 (St-7R) - ATACGGGAGCCAACACCACGTTAACGCGTAGCCTTTGGAC |
| AGAGCAGGTGTGACGGAT |
| SEQ ID NO. 414 (St-10R) - ATACGGGAGCCAACACCACGTTTCTCCACCATATTGCTCC |
| AGAGCAGGTGTGACGGAT |
| SEQ ID NO. 415 (St-11R) - ATACGGGAGCCAACACCACAGCTGATATTGGATGGTCCG |
| GCAGAGCAGGTGTGACGGAT |
| SEQ ID NO. 416 (St-15R) - ATACGGGAGCCAACACCATGCTGCTTAGTTGACTCGCTAA |
| TCCCTATCCTGTTCAGAGCAGGTGTGACGGAT |
| SEQ ID NO. 417 (St-16R) - ATACGGGAGCCAACACCAGATAAATTTTGCGTTCATTCTT |
| ATTTCCTGTCCGCCAGAGCAGGTGTGACGGAT |
| SEQ ID NO. 418 (St-18R) - ATACGGGAGCCAACACCAACACATTCTATAATGAATGTT |
| CCTGTCGCGTTGCGTAGAGCAGGTGTGACGGAT |
| SEQ ID NO. 419 (St-19R) - ATACGGGAGCCAACACCAGGTTTGGTTCCCCCCTACTCTC |
| CCGCATTGCAGCCGAGAGCAGGTGTGACGGAT |
| SEQ ID NO. 420 (St-20R) - ATACGGGAGCCAACACCAAGGACATCTAATCATCGATAC |
| CCGTGTTCCAGTCATAGAGCAGGTGTGACGGAT |
| S. typhimurium (S. enterica serovar Typhimurium type 13311) |
| OMPs - Fresh Bacteria |
| SEQ ID NO. 421 (StO-2F) - ATACGGGAGCCAACACCAGATAAATTTTGCGTTCATTCT |
| TATTTCCTGTCCGCCAGAGCAGGTGTGACGGAT |
| SEQ ID NO. 422 (StO-2R) - ATCCGTCACACCTGCTCTGGCGGACAGGAAATAAGAAT |
| GAACGCAAAATTTATCTGGTGTTGGCTCCCGTAT |
| SEQ ID NO. 423 (StO-4F) - ATACGGGAGCCAACACCAGATAAATTTTGGTTCATTCTT |
| ATTTCCTGTCCGCCAGAGCAGGTGTGACGGAT (71) |
| SEQ ID NO. 424 (StO-4R) - ATCCGTCACACCTGCTCTGGCGGACAGGAAATAAGAAT |
| GAACCAAAATTTATCTGGTGTTGGCTCCCGTAT (71) |
| SEQ ID NO. 425 (StO-5F) - ATACGGGAGCCAACACCACGGGGCTACCAGCACCGTCA |
| CCCCTCATTCTGCCACAGAGCAGGTGTGACGGAT |
| SEQ ID NO. 426 (StO-5R) - ATCCGTCACACCTGCTCTGTGGCAGAATGAGGGGTGAC |
| GGTGCTGGTAGCCCCGTGGTGTTGGCTCCCGTAT |
| SEQ ID NO. 427 (StO-6F) - ATACGGGAGCCAACACCAAAAGATGGAAAACACTGGAA |
| GGAAAATGCGGTCAGAGCAGGTGTGACGGAT (69) |
| SEQ ID NO. 429 (StO-6R) - ATCCGTCACACCTGCTCTGACCGCATTTTCCTTCCAGTGT |
| TTTCCATCTTTTGGTGTTGGCTCCCGTAT (69) |
| SEQ ID NO. 429 (StO-7F) - ATACGGGAGCCAACACCACCGGGCCGATGGGCACCAGG |
| AACTCTCGGACGAGTGAGAGCAGGTGTGACGGAT |
| SEQ ID NO. 430 (StO-7R) - ATCCGTCACACCTGCTCTCACTCGTCCGAGAGTTCCTGG |
| TGCCCATCGGCCCGGTGGTGTTGGCTCCCGTAT |
| SEQ ID NO. 431 (StO-8F) - ATACGGGAGCCAACACCACAGCTGATATTGGATGGTCC |
| GGCAGAGCAGGTGTGACGGAT (59) |
| SEQ ID NO. 432 (StO-8R) - ATCCGTCACACCTGCTCTGCCGGACCATCCAATATCAGC |
| TGTGGTGTTGGCTCCCGTAT (59) |
| SEQ ID NO. 433 (StO-9F) - ATACGGGAGCCAACACCAGTCGAAAGGCGGCCGTCCAG |
| TCGAGTGATTTGACCTAGAGCAGGTGTGACGGAT |
| SEQ ID NO. 434 (StO-9R) - ATCCGTCACACCTGCTCTAGGTCAAATCACTCGACTGGA |
| CGGCCGCCTTTCGACTGGTGTTGGCTCCCGTAT |
| SEQ ID NO. 435 (StO-10F) - ATACGGGAGCCAACACCACGGGGCGTGCCGTCAAAAG |
| ACCGAGATGTGGCTGCGAGAGCAGGTGTGACGGAT |
| SEQ ID NO. 436 (StO-10R) - ATCCGTCACACCTGCTCTCGCAGCCACATCTCGGTCTT |
| TTGACGGCACGCCCCGTGGTGTTGGCTCCCGTAT |
| SEQ ID NO. 437 (StO-11/13F) - ATACGGGAGCCAACACCACTAACTTGTTGCTGATCT |
| TATCCAGAGCAGGTGTGACGGAT (59) |
| SEQ ID NO. 438 (StO-11/13R) - ATCCGTCACACCTGCTCTGGATAAGATCAGCAACAA |
| GTTAGTGGTGTTGGCTCCCGTAT (59) |
| SEQ ID NO. 439 (StO-12F) - ATACGGGAGCCAACACCATTTAGCGTAGGGCTCGCTTA |
| T CATTTCTCATTCCCTAGAGCAGGTGTGACGGAT |
| SEQ ID NO. 440 (StO-12R) - ATCCGTCACACCTGCTCTAGGGAATGAGAAATGATAAG |
| CGAGCCCTACGCTAAATGGTGTTGGCTCCCGTAT |
| SEQ ID NO. 441 (StO-14F) - ATACGGGAGCCAACACCACCGCAACCCAAATCTCTACA |
| CGGATTATCGTCGAGCAGAGCAGGTGTGACGGAT |
| SEQ ID NO. 442 (StO-14R) - ATCCGTCACACCTGCTCTGCTCGACGATAATCCGTGTA |
| GAGATTTGGGTTGCGGTGGTGTTGGCTCCCGTAT |
| SEQ ID NO. 443 (StO-16F) - ATACGGGAGCCAACACCAACACATTCTATAATGAATGT |
| TCCTGTCGCGTTGCGTAGAGCAGGTGTGACGGAT |
| SEQ ID NO. 444 (StO-16R) - ATCCGTCACACCTGCTCTACGCAACGCGACAGGAACAT |
| TCATTATAGAATGTGTTGGTGTTGGCTCCCGTAT |
| SEQ ID NO. 445 (StO-17F) - ATACGGGAGCCAACACCAGCCTACCCCCCCTGTACGAG |
| GGCCGCAACCACGTAGAGAGCAGGTGTGACGGAT |
| SEQ ID NO. 446 (StO-17R) - ATCCGTCACACCTGCTCTCTACGTGGTTGCGGCCCTCGT |
| ACAGGGGGGGTAGGCTGGTGTTGGCTCCCGTAT |
| SEQ ID NO. 447 (StO-18F) - ATACGGGAGCCAACACCACATCTAGCACGAGACCCTAT |
| CCCAGAGCAGGTGTGACGGAT (59) |
| SEQ ID NO. 448 (StO-18R) - ATCCGTCACACCTGCTCTGGGATAGGGTCTCGTGCTAG |
| ATGTGGTGTTGGCTCCCGTAT (59) |
| SEQ ID NO. 449 (StO-19F) - ATACGGGAGCCAACACCAACAGCGACTCGAGTCTGAC |
| GACTCGCGGGGCAAATGAGAGCAGGTGTGACGGAT |
| SEQ ID NO. 450 (StO-19R) - ATCCGTCACACCTGCTCTCATTTGCCCCGCGAGTCGTC |
| AGACTCGAGTCGCTGTTGGTGTTGGCTCCCGTAT |
| SEQ ID NO. 451 (StO-20/24F) - ATACGGGAGCCAACACCATAGTGTTGGGCCAATACG |
| GTAACGTGTCCTTGGAGAGCAGGTGTGACGGAT (69) |
| SEQ ID NO. 452 (StO-20/24R) - ATCCGTCACACCTGCTCTCCAAGGACACGTTACCGT |
| ATTGGCCCAACACTATGGTGTTGGCTCCCGTAT (69) |
| SEQ ID NO. 453 (StO-21F) - ATACGGGAGCCAACACCACTAAGGAGAGGTCGCGACA |
| GACTCTTCTGGTCAAGGAGAGCAGGTGTGACGGAT |
| SEQ ID NO. 454 (StO-21R) - ATCCGTCACACCTGCTCTCCTTGACCAGAAGAGTCTGT |
| CGCGACCTCTCCTTAGTGGTGTTGGCTCCCGTATG |
| SEQ ID NO. 455 (StO-22F) - ATACGGGAGCCAACACCAACTTCGACTCAAAGAAGTCC |
| ACGTGAGACTGGTGGAAGAGCAGGTGTGACGGAT |
| SEQ ID NO. 456 (StO-22R) - ATCCGTCACACCTGCTCTTCCACCAGTCTCACGTGGAC |
| TTCTTTGAGTCGAAGTTGGTGTTGGCTCCCGTAT |
| SEQ ID NO. 457 (StO-23F) - ATACGGGAGCCAACACCACCCGGGGAGACCCGCACGG |
| GCGCACAATCCTTGTCGAGAGCAGGTGTGACGGAT |
| SEQ ID NO. 458 (StO-23R) - ATCCGTCACACCTGCTCTCGACAAGGATTGTGCGCCCG |
| TGCGGGTCTCCCCGGGTGGTGTTGGCTCCCGTAT |
| SEQ ID NO. 459 (StO-25F) - ATACGGGAGCCAACACCAGCTGGACCAAACTACGCCC |
| ATTGTGGGGGTCCCCGGAGAGCAGGTGTGACGGAT |
| SEQ ID NO. 460 (StO-25R) - ATCCGTCACACCTGCTCTCCGGGGACCCCCACAATGGG |
| CGTAGTTTGGTCCAGCTGGTGTTGGCTCCCGTAT |
| S. typhimurium (S. enterica serovar Typhimurium type 13311) |
| Whole Cell DNA Ligands |
| SEQ ID NO. 461 StW-4/14/24/26/39/72 F - ATACGGGAGCCAACACCATAGTGTT |
| GGGCCAATACGGTAACGTGTCCTTGGAGAGCAGGTGTGACGGAT (69) |
| SEQ ID NO. 462 StW-4/14/24/26/39/72 R - ATCCGTCACACCTGCTCTCCAAGGAC |
| ACGTTACCGTATTGGCCCAACACTATGGTGTTGGCTCCCGTAT (69) |
| SEQ ID NO. 463 StW-7 F - ATACGGGAGCCAACACCAGTGGGACCTACGGCCTTTGG |
| CCCGCTGTTACAACGTAGAGCAGGTGTGACGGAT |
| SEQ ID NO. 464 StW-7 R - ATCCGTCACACCTGCTCTACGTTGTAACAGCGGGCCAAA |
| GGCCGTAGGTCCCACTGGTGTTGGCTCCCGTAT |
| SEQ ID NO. 465 StW-9 F - ATACGGGAGCCAACACCACTTACGCATCAGCCACTCGA |
| GAGACGGCGTTATGGCAGAGCAGGTGTGACGGAT |
| SEQ ID NO. 466 StW-9 R - ATCCGTCACACCTGCTCTGCCATAACGCCGTCTCTCGAG |
| TGGCTGATGCGTAAGTGGTGTTGGCTCCCGTAT |
| SEQ ID NO. 467 StW-11 F - ATACGGGAGCCAACACCACTATAGGGTGTAGCTGATC |
| CGCTCCCTTCTCCCAGGAGAGCAGGTGTGACGGAT |
| SEQ ID NO. 468 StW-11 R - ATCCGTCACACCTGCTCTCCTGGGAGAAGGGAGCGGAT |
| CAGCTACACCCTATAGTGGTGTTGGCTCCCGTAT |
| SEQ ID NO. 469 StW-12 F - ATACGGGAGCCAACACCAGAACACCTAGAGACTAGTT |
| CGTGTCGGCCCAGCGTGAGAGCAGGTGTGACGGAT |
| SEQ ID NO. 470 StW-12 R - ATCCGTCACACCTGCTCTCACGCTGGGCCGACACGAAC |
| TAGTCTCTAGGTGTTCTGGTGTTGGCTCCCGTAT |
| SEQ ID NO. 471 StW-16 F - ATACGGGAGCCAACACCATAAGAACCACCATTCCGCGT |
| TCGCCTCCCGAGGTGTAGAGCAGGTGTGACGGAT |
| SEQ ID NO. 472 StW-16 R - ATCCGTCACACCTGCTCTACACCTCGGGAGGCGAACGC |
| GGAATGGTGGTTCTTATGGTGTTGGCTCCCGTAT |
| SEQ ID NO. 473 StW-19 F - ATACGGGAGCCAACACCAGGCCATAGGCAATTTCATAT |
| AGCAACTGGTGAGCGTAGAGCAGGTGTGACGGAT |
| SEQ ID NO. 474 StW-19 R - ATCCGTCACACCTGCTCTACGCTCACCAGTTGCTATAT |
| GAAATTGCCTATGGCCTGGTGTTGGCTCCCGTAT |
| SEQ ID NO. 475 StW-20 F - ATACGGGAGCCAACACCAACAGAAGTCGACCCTGGTA |
| ATCATGCTCTCTCACGGAGAGCAGGTGTGACGGAT |
| SEQ ID NO. 476 StW-20 R - ATCCGTCACACCTGCTCTCCGTGAGAGAGCATGATTAC |
| CAGGGTCGACTTCTGTTGGTGTTGGCTCCCGTAT |
| SEQ ID NO. 477 StW-22 F - ATACGGGAGCCAACACCACCAACACCTGGAGAACTTG |
| AAACGCAGATGGTCCCCAGAGCAGGTGTGACGGAT |
| SEQ ID NO. 478 StW-22 R - ATCCGTCACACCTGCTCTGGGGACCATCTGCGTTTCAA |
| GTTCTCCAGGTGTTGGTGGTGTTGGCTCCCGTAT |
| SEQ ID NO. 479 StW-23 F - ATACGGGAGCCAACACCAGGTAGCGACATGACAGTAC |
| CACTTACAGGACGTGCCAGAGCAGGTGTGACGGAT |
| SEQ ID NO. 480 StW-23 R - ATCCGTCACACCTGCTCTGGCACGTCCTGTAAGTGGTA |
| CTGTCATGTCGCTACCTGGTGTTGGCTCCCGTAT |
| SEQ ID NO. 481 StW-25 F - ATACGGGAGCCAACACCAATGACGTAAACACAAACGG |
| CGGACCCAATCGTGTTCAGAGCAGGTGTGACGGAT |
| SEQ ID NO. 482 StW-25 R - ATCCGTCACACCTGCTCTGAACACGATTGGGTCCGCCG |
| TTTGTGTTTACGTCATTGGTGTTGGCTCCCGTAT |
| SEQ ID NO. 483 StW-27 F - ATACGGGAGCCAACACCATGCTCCAGCATATTGATTAA |
| TGCCAAGAGTTGGAACAGAGCAGGTGTGACGGAT |
| SEQ ID NO. 484 StW-27 R - ATCCGTCACACCTGCTCTGTTCCAACTCTTGGCATTAAT |
| CAATATGCTGGAGCATGGTGTTGGCTCCCGTAT |
| SEQ ID NO. 485 StW-29 F - ATACGGGAGCCAACACCATGTGGTTCAGATGCGCCATA |
| TCTAGACGGTCTCTGTAGAGCAGGTGTGACGGAT |
| SEQ ID NO. 486 StW-29 R - ATCCGTCACACCTGCTCTACAGAGACCGTCTAGATATG |
| GCGCATCTGAACCACATGGTGTTGGCTCCCGTAT |
| SEQ ID NO. 487 StW-30 F - ATACGGGAGCCAACACCAAACCCCATTCTGTCACAGCG |
| CCACCCAACGAGTGTTAGAGCAGGTGTGACGGAT |
| SEQ ID NO. 488 StW-30 R - ATCCGTCACACCTGCTCTAACACTCGTTGGGTGGCGCT |
| GTGACAGAATGGGGTTTGGTGTTGGCTCCCGTAT |
| SEQ ID NO. 489 StW-34 F - ATACGGGAGCCAACACCAGCCGGTATCGGTGCTGAGGG |
| CCTTGGCTTGGCTCTGAGAGCAGGTGTGACGGAT |
| SEQ ID NO. 489 StW-34 R - ATCCGTCACACCTGCTCTCAGAGCCAAGCCAAGGCCCT |
| CAGCACCGATACCGGCTGGTGTTGGCTCCCGTAT |
| SEQ ID NO. 490 StW-36 F - ATACGGGAGCCAACACCATGGCGACCTAATCAGCCGGA |
| CAGTGCTCCTCAACGTAGAGCAGGTGTGACGGAT |
| SEQ ID NO. 491 StW-36 R - ATCCGTCACACCTGCTCTACGTTGAGGAGCACTGTCCG |
| GCTGATTAGGTCGCCATGGTGTTGGCTCCCGTAT |
| SEQ ID NO. 492 StW-38 F - ATACGGGAGCCAACACCATGGAGACAGGGGGAACGAC |
| AGCGGCGGTTGCGGGGCAGAGCAGGTGTGACGGA |
| SEQ ID NO. 493 StW-38 R - ATCCGTCACACCTGCTCTGCCCCGCAACCGCCGCTGTC |
| GTTCCCCCTGTCTCCATGGTGTTGGCTCCCGTAT |
| SEQ ID NO. 494 StW-40 F - ATACGGGAGCCAACACCAATAGCCGGCCGAAATCCCTT |
| TGGGATGGTCATACCGAGAGCAGGTGTGACGGAT |
| SEQ ID NO. 495 StW-40 R - ATCCGTCACACCTGCTCTCGGTATGACCATCCCAAAGG |
| GATTTCGGCCGGCTATTGGTGTTGGCTCCCGTAT |
| SEQ ID NO. 496 StW-42 F - ATACGGGAGCCAACACCACCGAATGTGCTGCAAGACT |
| AATCTGGATGGCCATGCAGAGCAGGTGTGACGGAT |
| SEQ ID NO. 497 StW-42 R - ATCCGTCACACCTGCTCTGCATGGCCATCCAGATTAGTC |
| TTGCAGCACATTCGGTGGTGTTGGCTCCCGTAT |
| SEQ ID NO. 498 StW-43 F - ATACGGGAGCCAACACCAAATCGAGTTCGTGACAGTTG |
| GGCAGATACCGAGTCCAGAGCAGGTGTGACGGAT |
| SEQ ID NO. 499 StW-43 R - ATCCGTCACACCTGCTCTGGACTCGGTATCTGCCCAAC |
| TGTCACGAACTCGATTTGGTGTTGGCTCCCGTAT |
| SEQ ID NO. 500 StW-45 F - ATACGGGAGCCAACACCAGGGTCCACGCTACACGGATC |
| AAGTCTAGCTGGTTGTAGAGCAGGTGTGACGGAT |
| SEQ ID NO. 501 StW-45 R - ATCCGTCACACCTGCTCTACAACCAGCTAGACTTGATC |
| CGTGTAGCGTGGACCCTGGTGTTGGCTCCCGTAT |
| SEQ ID NO. 502 StW-47 F - ATACGGGAGCCAACACCATCCCACAAGGCTCGTGTTAG |
| GCCTCCAATGCTCTCGAGAGCAGGTGTGACGGAT |
| SEQ ID NO. 503 StW-47 R - ATCCGTCACACCTGCTCTCGAGAGCATTGGAGGCCTAA |
| CACGAGCCTTGTGGGATGGTGTTGGCTCCCGTAT |
| SEQ ID NO. 504 StW-48 F - ATACGGGAGCCAACACCAGGCCCCGAGAAATTATCGAT |
| AGTGGTTTCTCGCCCTAGAGCAGGTGTGACGGAT |
| SEQ ID NO. 505 StW-48 R - ATCCGTCACACCTGCTCTAGGGCGAGAAACCACTATCG |
| ATAATTTCTCGGGGCCTGGTGTTGGCTCCCGTAT |
| SEQ ID NO. 506 StW-49 F - ATACGGGAGCCAACACCACACCCGGATGCGATTAAGAA |
| GTTACTGCCTTGCGGGAGAGCAGGTGTGACGGAT |
| SEQ ID NO. 507 StW-49 R - ATCCGTCACACCTGCTCTCCCGCAAGGCAGTAACTTCTT |
| AATCGCATCCGGGTGTGGTGTTGGCTCCCGTAT |
| SEQ ID NO. 508 StW-50 F - ATACGGGAGCCAACACCATGCCATGCACTTGGTTCCGA |
| ACGTTCGCGTCATTGCAGAGCAGGTGTGACGGAT |
| SEQ ID NO. 509 StW-50 R - ATCCGTCACACCTGCTCTGCAATGACGCGAACGTTCGG |
| AACCAAGTGCATGGCATGGTGTTGGCTCCCGTAT |
| SEQ ID NO. 510 StW-56 F - ATACGGGAGCCAACACCACCAAAAAAAGCTGTGACCG |
| GAAGGTGCTGCTGACGTAGAGCAGGTGTGACGGAT |
| SEQ ID NO. 511 StW-56 R - ATCCGTCACACCTGCTCTACGTCAGCAGCACCTTCCGGT |
| CACAGCTTTTTTTGGTGGTGTTGGCTCCCGTAT |
| SEQ ID NO. 512 StW-58 F - ATACGGGAGCCAACACCAAGCTACCATCCACCTAACAG |
| GACTACGCGAATTGCAAGAGCAGGTGTGACGGAT |
| SEQ ID NO. 513 StW-58 R - ATCCGTCACACCTGCTCTTGCAATTCGCGTAGTCCTGTT |
| AGGTGGATGGTAGCTTGGTGTTGGCTCCCGTAT |
| SEQ ID NO. 514 StW-61 F - ATACGGGAGCCAACACCACAAGCAGGAATAAGCGCCG |
| GTCCAGAGCAGGTGTGACGGAT (59) |
| SEQ ID NO. 515 StW-61 R - ATCCGTCACACCTGCTCTGGACCGGCGCTTATTCCTGCT |
| TGTGGTGTTGGCTCCCGTAT (59) |
| SEQ ID NO. 516 StW-62 F - ATACGGGAGCCAACACCACATGGACCGGCAACCTCAG |
| AAGTAGCAAACCACCATAGAGCAGGTGTGACGGAT |
| SEQ ID NO. 517 StW-62 R - ATCCGTCACACCTGCTCTATGGTGGTTTGCTACTTCTGA |
| GGTTGCCGGTCCATGTGGTGTTGGCTCCCGTAT |
| SEQ ID NO. 518 StW-65 F - ATACGGGAGCCAACACCATGTCCAAACCATTCTCGGAC |
| CTCCCTCAGTGGCGGCAGAGCAGGTGTGACGGAT |
| SEQ ID NO. 519 StW-65 R - ATCCGTCACACCTGCTCTGCCGCCACTGAGGGAGGTCC |
| GAGAATGGTTTGGACATGGTGTTGGCTCCCGTAT |
| SEQ ID NO. 520 StW-66 F - ATACGGGAGCCAACACCAGTCCGTTATGACATGTCCGG |
| ACCCGTACGCGTGTCAAGAGCAGGTGTGACGGAT |
| SEQ ID NO. 521 StW-66 R - ATCCGTCACACCTGCTCTTGACACGCGTACGGGTCCGG |
| ACATGTCATAACGGACTGGTGTTGGCTCCCGTAT |
| SEQ ID NO. 522 StW-67 F - ATACGGGAGCCAACACCATCCGCTCACATGATGCTGTA |
| CGATGGCCGCGTGCAAAGAGCAGGTGTGACGGAT |
| SEQ ID NO. 523 StW-67 R - ATCCGTCACACCTGCTCTTTGCACGCGGCCATCGTACA |
| GCATCATGTGAGCGGATGGTGTTGGCTCCCGTAT |
| SEQ ID NO. 524 StW-68 F - ATACGGGAGCCAACACCACGTCGCATATACCCCGAGAA |
| GGTAGATCGTGGACTAGAGCAGGTGTGACGGAT (71) |
| SEQ ID NO. 525 StW-68 R - ATCCGTCACACCTGCTCTAGTCCACGATCTACCTTCTCG |
| GGGTATATGCGACGTGGTGTTGGCTCCCGTAT (71) |
| SEQ ID NO. 526 StW-69 F - ATACGGGAGCCAACACCACGAGGACCTAGACTTGTCCG |
| ACATCACAGTGTGCGAGAGCAGGTGTGACGGAT (71) |
| SEQ ID NO. 527 StW-69 R - ATCCGTCACACCTGCTCTCGCACACTGTGATGTCGGAC |
| AAGTCTAGGTCCTCGTGGTGTTGGCTCCCGTAT (71) |
| SEQ ID NO. 528 StW-70 F - ATACGGGAGCCAACACCACAGCTGATATTGGATGGTCC |
| GGCAGAGCAGGTGTGACGGAT (59) |
| SEQ ID NO. 529 StW-70 R - ATCCGTCACACCTGCTCTGCCGGACCATCCAATATCAG |
| CTGTGGTGTTGGCTCCCGTAT (59) |
| SEQ ID NO. 530 StW-71 F - ATACGGGAGCCAACACCACGGGACCATCAGCCTCAACT |
| TCCTACAAGGCCTACTAGAGCAGGTGTGACGGAT |
| SEQ ID NO. 531 StW-71 R - ATCCGTCACACCTGCTCTAGTAGGCCTTGTAGGAAGTT |
| GAGGCTGATGGTCCCGTGGTGTTGGCTCCCGTAT |
| SEQ ID NO. 532 StW-73 F - ATACGGGAGCCAACACCAATGGACAAAGGCAATAGCG |
| TCAATTGAAGTCAGACCAGAGCAGGTGTGACGGAT |
| SEQ ID NO. 533 StW-73 R - ATCCGTCACACCTGCTCTGGTCTGACTTCAATTGACGCT |
| ATTGCCTTTGTCCATTGGTGTTGGCTCCCGTAT |
| SEQ ID NO. 534 StW-74 F - ATACGGGAGCCAACACCAACTGAACTCATGAAGCACG |
| ATTGTTGCCCCACGTGCAGAGCAGGTGTGACGGAT |
| SEQ ID NO. 535 StW-74 R - ATCCGTCACACCTGCTCTGCACGTGGGGCAACAATCGT |
| GCTTCATGAGTTCAGTTGGTGTTGGCTCCCGTAT |
| SEQ ID NO. 536 StW-76 F - ATACGGGAGCCAACACCAATCCCTAGCAAGTAAGCTGG |
| TGGAGCTAGTACACGTAGAGCAGGTGTGACGGAT |
| SEQ ID NO. 537 StW-76 R - ATCCGTCACACCTGCTCTACGTGTACTAGCTCCACCAGC |
| TTACTTGCTAGGGATTGGTGTTGGCTCCCGTAT |
| SEQ ID NO. 538 StW-78 F - ATACGGGAGCCAACACCACACCGAAAGCCGGAACGAT |
| AGGGTACAGCTGGGTGTAGAGCAGGTGTGACGGAT |
| SEQ ID NO. 539 StW-78 R - ATCCGTCACACCTGCTCTACACCCAGCTGTACCCTATC |
| GTTCCGGCTTTCGGTGTGGTGTTGGCTCCCGTAT |
| SEQ ID NO. 540 StW-79 F - ATACGGGAGCCAACACCAAGGGCGAACTAGCATCACC |
| TCGGTCGCTCATAGGCCAGAGCAGGTGTGACGGAT |
| SEQ ID NO. 541 StW-79 R - ATCCGTCACACCTGCTCTGGCCTATGAGCGACCGAGGT |
| GATGCTAGTTCGCCCTTGGTGTTGGCTCCCGTAT |
| SEQ ID NO. 542 StW-80 F - ATACGGGAGCCAACACCACAGGGCGACGTAAGCTCCG |
| TCCAGAGGATGTCAGTAGAGCAGGTGTGACGGAT (71) |
| SEQ ID NO. 543 StW-80 R - ATCCGTCACACCTGCTCTACTGACATCCTCTGGACGGA |
| GCTTACGTCGCCCTGTGGTGTTGGCTCCCGTAT (71) |
| Shiga-like Toxin type 1; Stx-1 |
| SEQ ID NO. 544 (SH-2F) - ATCCGTCACACCTGCTCTGGAGACATTAAAAACCGGAG |
| TTTATTTATACCTTTCTGGTGTTGGCTCCCGTAT |
| SEQ ID NO. 545 (SH-2R) - ATACGGGAGCCAACACCAGAAAGGTATAAATAAACTCC |
| GGTTTTTAATGTCTCCAGAGCAGGTGTGACGGAT |
| SEQ ID NO. 546 (SH-3F (59)) - ATACGGGAGCCAACACCACTAACTTGTTGCTGATCT |
| TATCCAGAGCAGGTGTGACGGAT |
| SEQ ID NO. 547 (SH-3R (59)) - ATCCGTCACACCTGCTCTGGATAAGATCAGCAACAA |
| GTTAGTGGTGTTGGCTCCCGTAT |
| SEQ ID NO. 548 (SH-4F (58)) - ATCCGTCACACCTGCTCTGCATGGAGAGTTTTTTGGT |
| CAGTGGTGTTGGCTCCCGTAT |
| SEQ ID NO. 549 (SH-4R (58)) - ATACGGGAGCCAACACCACTGACCAAAAAACTCTC |
| CATGCAGAGCAGGTGTGACGGAT |
| SEQ ID NO. 550 (SH-6F (58)) - ATACGGGAGCCAACACCACGTTAACGCGTAGCCTTT |
| GGACAGAGCAGGTGTGACGGAT |
| SEQ ID NO. 551 (SH-6R (58)) - ATCCGTCACACCTGCTCTGTCCAAAGGCTACGCGTT |
| AACGTGGTGTTGGCTCCCGTAT |
| SEQ ID NO. 552 (SH-8/21/23/24/25F (59)) - ATCCGTCACACCTGCTCTGCCGG |
| ACCATCCAATATCAGCTGTGGTGTTGGCTCCCGTAT |
| SEQ ID NO. 553 (SH-8/21/23/24/25 Rev (59)) - ATACGGGAGCCAACACCACA |
| GCTGATATTGGATGGTCCGGCAGAGCAGGTGTGACGGAT |
| SEQ ID NO. 554 (SH-9F) - ATCCGTCACACCTGCTCTCGTCCGTCATTAAGTTCGGAG |
| GCTGGCGGGTTGCGTTGGTGTTGGCTCCCGTAT |
| SEQ ID NO. 555 (SH-9R) - ATACGGGAGCCAACACCAACGCAACCCGCCAGCCTCCG |
| AACTTAATGACGGACGAGAGCAGGTGTGACGGAT |
| SEQ ID NO. 556 (SH-10F) - ATACGGGAGCCAACACCATTCTATCGTTCCGGACGCTT |
| ATGCCTTGCCATCTACAGAGCAGGTGTGACGGAT |
| SEQ ID NO. 557 (SH-10R) - ATCCGTCACACCTGCTCTGTAGATGGCAAGGCATAAGC |
| GTCCGGAACGATAGAATGGTGTTGGCTCCCGTAT |
| SEQ ID NO. 558 (SH-11F) - TCCGTCACACCTGCTCTAACTCTTACTACTTTGTTGCTA |
| TCACATTCAACTGTTGGTGTTGGCTCCCGTAT |
| SEQ ID NO. 559 (SH-11R) - ATACGGGAGCCAACACCAACAGTTGAATGTGATAGCA |
| ACAAAGTAGTAAGAGTTAGAGCAGGTGTGACGGAT |
| SEQ ID NO. 560 (SH-12 F(58)) - ATCCGTCACACCTGCTCTGGCCTTTCACCAAGCG |
| TCCTTGTGGTGTTGGCTCCCGTAT |
| SEQ ID NO. 561 (SH-12R (58)) - ATACGGGAGCCAACACCACAAGGACGCTTGGTGAA |
| AGGCCAGAGCAGGTGTGACGGAT |
| SEQ ID NO. 562 (SH-16F (58)) - ATCCGTCACACCTGCTCTGGCACCGAGCACGGGAA |
| CCCAGTGGTGTTGGCTCCCGTAT |
| SEQ ID NO. 563 (SH-16R (58)) - ATACGGGAGCCAACACCACTGGGTTCCCGTGCTCG |
| GTGCCAGAGCAGGTGTGACGGAT |
| SEQ ID NO. 564 (SH-17F (69)) - ATACGGGAGCCAACACCATAGTGTTGGGCCAATAC |
| GGTAACGTGTCCTTGGAGAGCAGGTGTGACGGAT |
| SEQ ID NO. 565 (SH-17R (69)) - ATCCGTCACACCTGCTCTCCAAGGACACGTTACCG |
| TATTGGCCCAACACTATGGTGTTGGCTCCCGTAT |
| SEQ ID NO. 567 (SH-18F) - ATCCGTCACACCTGCTCTACCCGATGCCGCCCCGGGATT |
| GTTGTATGACCATCTTGGTGTTGGCTCCCGTAT |
| SEQ ID NO. 568 (SH-18R) - ATACGGGAGCCAACACCAAGATGGTCATACAACAATC |
| CCGGGGCGGCATCGGGTAGAGCAGGTGTGACGGAT |
| SEQ ID NO. 569 (SH-19F) - ATACGGGAGCCAACACCACCCCATGAGTACACGTGAAC |
| GGACACAGCCTCCGGCAGAGCAGGTGTGACGGAT |
| SEQ ID NO. 570 (SH-19R) - ATCCGTCACACCTGCTCTGCCGGAGGCTGTGTCCGTTC |
| ACGTGTACTCATGGGGTGGTGTTGGCTCCCGTAT |
| SEQ ID NO. 571 (SH-20F) - ATCCGTCACACCTGCTCTTAACCATTCATTTCTTTTGTG |
| GTATGACCGTTCGCCTGGTGTTGGCTCCCGTAT |
| SEQ ID NO. 572 (SH-20R) - ATACGGGAGCCAACACCAGGCGAACGGTCATACCACA |
| AAAGAAATGAATGGTTAAGAGCAGGTGTGACGGAT |
| SEQ ID NO. 573 (SH-22F (58)) - ATCCGTCACACCTGCTCTGGGGCTCTTTTCGTTA |
| ACCAGGTGGTGTTGGCTCCCGTAT |
| SEQ ID NO. 574 (SH-22R (58)) - ATACGGGAGCCAACACCACCTGGTTAACGAAAAGA |
| GCCCCAGAGCAGGTGTGACGGAT |
| Shiga-like toxin 2; Stx-2 |
| SEQ ID NO. 575 S2-1 F - ATACGGGAGCCAACACCAGGCGACCAAGTTTGAATCACC |
| ACAATCGTGACGGTGAGAGCAGGTGTGACGGAT |
| SEQ ID NO. 576 S2-1 R - ATCCGTCACACCTGCTCTCACCGTCACGATTGTGGTGATTC |
| AAACTTGGTCGCCTGGTGTTGGCTCCCGTAT |
| SEQ ID NO. 577 S2-2 F - ATACGGGAGCCAACACCACCATCACATCTTGGCCCGGTAC |
| CCTGGATACTAGCCAGAGCAGGTGTGACGGAT |
| SEQ ID NO. 578 S2-2 R - ATCCGTCACACCTGCTCTGGCTAGTATCCAGGGTACCGGG |
| CCAAGATGTGATGGTGGTGTTGGCTCCCGTAT |
| SEQ ID NO. 579 S2-3 F - ATACGGGAGCCAACACCAGCACTAGCTCGGGTAACGGGG |
| ACATTAGAGTTTGCCAGAGCAGGTGTGACGGAT |
| SEQ ID NO. 580 S2-3 R - ATCCGTCACACCTGCTCTGGCAAACTCTAATGTCCCCGTT |
| ACCCGAGCTAGTGCTGGTGTTGGCTCCCGTAT |
| SEQ ID NO. 581 S2-4 F - ATACGGGAGCCAACACCAAAGCCCACCGCGCCCAGATCT |
| ACAAGACTTCCAACTAGAGCAGGTGTGACGGAT |
| SEQ ID NO. 582 S2-4 R - ATCCGTCACACCTGCTCTAGTTGGAAGTCTTGTAGATCTG |
| GGCGCGGTGGGCTTTGGTGTTGGCTCCCGTAT |
| SEQ ID NO. 583 S2-5 F - ATACGGGAGCCAACACCATCTTTGTCACTCTGGATTAGGT |
| TAATCCACTGAAACAGAGCAGGTGTGACGGAT |
| SEQ ID NO. 584 S2-5 R - ATCCGTCACACCTGCTCTGTTTCAGTGGATTAACCTAATC |
| CAGAGTGACAAAGATGGTGTTGGCTCCCGTAT |
| SEQ ID NO. 585 S2-7 F - ATACGGGAGCCAACACCACGAACCCGGGATTCTAGCAATT |
| GTCCCCCTCGAGCGAGAGCAGGTGTGACGGAT |
| SEQ ID NO. 586 S2-7 R - ATCCGTCACACCTGCTCTCGCTCGAGGGGGACAATTGCTA |
| GAATCCCGGGTTCGTGGTGTTGGCTCCCGTAT |
| SEQ ID NO. 587 S2-8 F - ATACGGGAGCCAACACCAATGATTAATAGAACCCCCTAT |
| GACCTGGCCGCTGGGAGAGCAGGTGTGACGGAT |
| SEQ ID NO. 588 S2-8 R - ATCCGTCACACCTGCTCTCCCAGCGGCCAGGTCATAGGGG |
| GTTCTATTAATCATTGGTGTTGGCTCCCGTAT |
| SEQ ID NO. 589 S2-9 F - ATACGGGAGCCAACACCATGGTCGGATAGCATGTCCATG |
| TTGTCGGGTTTAACAAGAGCAGGTGTGACGGAT |
| SEQ ID NO. 590 S2-9 R - ATCCGTCACACCTGCTCTTGTTAAACCCGACAACATGGAC |
| ATGCTATCCGACCATGGTGTTGGCTCCCGTAT |
| SEQ ID NO. 591 S2-10 F - ATACGGGAGCCAACACCAGGGGAATCTTGCTTGCGTAGC |
| GACGCATAATGACGTAGAGCAGGTGTGACGGAT |
| SEQ ID NO. 592 S2-10 R - ATCCGTCACACCTGCTCTACGTCATTATGCGTCGCTACG |
| CAAGCAAGATTCCCCTGGTGTTGGCTCCCGTAT |
| SEQ ID NO. 593 S2-12 F - ATACGGGAGCCAACACCATGAAGTGGACAAATGTGCGTT |
| CCCCTGACGTACCGGAGAGCAGGTGTGACGGAT |
| SEQ ID NO. 594 S2-12 R - ATCCGTCACACCTGCTCTCCGGTACGTCAGGGGAACGCA |
| CATTTGTCCACTTCATGGTGTTGGCTCCCGTA |
| SEQ ID NO. 595 S2-13 F - ATACGGGAGCCAACACCACCATTTAGTGTTAGACTAAGT |
| GATATCGAGTCGAGGAGAGCAGGTGTGACGGAT |
| SEQ ID NO. 596 S2-13 R - ATCCGTCACACCTGCTCTCCTCGACTCGATATCACTTAGT |
| CTAACACTAAATGGTGGTGTTGGCTCCCGTAT |
| SEQ ID NO. 597 S2-14 F - ATACGGGAGCCAACACCACTTCCACTTTTTCGCCTAATT |
| GCCTGTTGCATGGTAAGAGCAGGTGTGACGGAT |
| SEQ ID NO. 598 S2-14 R - ATCCGTCACACCTGCTCTTACCATGCAACAGGCAATTAG |
| GCGAAAAAGTGGAAGTGGTGTTGGCTCCCGTAT |
| SEQ ID NO. 599 S2-14.1 F - ATACGGGAGCCAACACCAGGCGATGTCCTAAAGTCTTT |
| AAGGCGAATATAGTTGAGAGCAGGTGTGACGGAT |
| SEQ ID NO. 600 S2-14.1 R - ATCCGTCACACCTGCTCTCAACTATATTCGCCTTAAAGA |
| CTTTAGGACATCGCCTGGTGTTGGCTCCCGTAT |
| SEQ ID NO. 601 S2-15 F - ATACGGGAGCCAACACCACCCCCCCCTCCGTGGGCCGCT |
| CCCCTCGGCCGGGCCAGAGCAGGTGTGACGGAT |
| SEQ ID NO. 602 S2-15 R - ATCCGTCACACCTGCTCTGGCCCGGCCGAGGGGAGCGGC |
| CCACGGAGGGGGGGGTGGTGTTGGCTCCCGTAT |
| SEQ ID NO. 603 S2-16 F - ATACGGGAGCCAACACCATCCCGTGAAGCAACGACAATA |
| CAAGACGAGCGAAGGAGAGCAGGTGTGACGGAT |
| SEQ ID NO. 604 S2-16 R - ATCCGTCACACCTGCTCTCCTTCGCTCGTCTTGTATTGTC |
| GTTGCTTCACGGGATGGTGTTGGCTCCCGTAT |
| SEQ ID NO. 605 S2-17 F - ATACGGGAGCCAACACCACGCGACTTCTTCAACAGATAC |
| AGAGCGCTTGGGGCCAGAGCAGGTGTGACGGAT |
| SEQ ID NO. 606 S2-17 R - ATCCGTCACACCTGCTCTGGCCCCAAGCGCTCTGTATCT |
| GTTGAAGAAGTCGCGTGGTGTTGGCTCCCGTAT |
| SEQ ID NO. 607 S2-18 F - ATACGGGAGCCAACACCAGGAAATGGTACCTAAGAAAT |
| GAGAACTTTGACGCACAGAGCAGGTGTGACGGAT |
| SEQ ID NO. 607 S2-18 R - ATCCGTCACACCTGCTCTGTGCGTCAAAGTTCTCATTTCT |
| TAGGTACCATTTCCTGGTGTTGGCTCCCGTAT |
| SEQ ID NO. 609 S2-19 F - ATACGGGAGCCAACACCATTAAAGTTAATCTTACACGTT |
| TCCGACTTCCATTTGAGAGCAGGTGTGACGGAT |
| SEQ ID NO. 610 S2-19 R - ATCCGTCACACCTGCTCTCAAATGGAAGTCGGAAACGTG |
| TAAGATTAACTTTAATGGTGTTGGCTCCCGTAT |
| SEQ ID NO. 611 S2-20 F - ATACGGGAGCCAACACCAAGGAGTCCGTCTACGTTTTAC |
| GAGCTAAGGCCTTTGAGAGCAGGTGTGACGGAT |
| SEQ ID NO. 612 S2-20 R - ATCCGTCACACCTGCTCTCAAAGGCCTTAGCTCGTAAAA |
| CGTAGACGGACTCCTTGGTGTTGGCTCCCGTAT |
| Cryptosporidium parvum oocysts (CP) |
| SEQ ID NO. 613 CP 12F - ATACGGGAGCCAACACCATAATGAAGCGATGTAGCGAGTT |
| TTTGAAAGGGACACAGAGCAGGTGTGACGGAT |
| SEQ ID NO. 614 CP12R - ATCCGTCACACCTGCTCTGTGTCCCTTTCAAAAACTCGCTA |
| CATCGCTTCATTATGGTGTTGGCTCCCGTAT |
| SEQ ID NO. 615 CP 13F - ATACGGGAGCCAACACCATTTAGTCCATAGCTTCAGCGCT |
| TCCACCTCCTTAACAGAGCAGGTGTGACGGAT |
| SEQ ID NO. 616 CP 13R - ATCCGTCACACCTGCTCTGTTAAGGAGGTGGAAGCGCTGA |
| AGCTATGGACTAAATGGTGTTGGCTCCCGTAT |
| SEQ ID NO. 617 CP 15F - ATACGGGAGCCAACACCACCCGTTTTTGATCTAATGAGGA |
| TACAATATTCGTCTAGAGCAGGTGTGACGGAT |
| SEQ ID NO. 618 CP 15R - ATCCGTCACACCTGCTCTAGACGAATATTGTATCCTCATTA |
| GATCAAAAACGGGTGGTGTTGGCTCCCGTAT |
| SEQ ID NO. 619 CP 16F - ATACGGGAGCCAACACCACCGGGTCCCCGTGATCTAGGAC |
| AACACGGCGGTTGGAGAGCAGGTGTGACGGAT |
| SEQ ID NO. 620 CP 16R - ATCCGTCACACCTGCTCTCCAACCGCCGTGTTGTCCTAGAT |
| CACGGGGACCCGGTGGTGTTGGCTCCCGTAT |
| SEQ ID NO. 621 CP 17F - ATACGGGAGCCAACACCAGTTCAGGCATACATGATGTGGG |
| TTCTTATTCCGTGCAGAGCAGGTGTGACGGAT |
| SEQ ID NO. 622 CP 17R - ATCCGTCACACCTGCTCTGCACGGAATAAGAACCCACATC |
| ATGTATGCCTGAACTGGTGTTGGCTCCCGTAT |
| SEQ ID NO. 623 CP18F - ATACGGGAGCCAACACCAGGCAGCCCGGTCCCGGACTAAC |
| AACCGCGGTACCCAAGAGCAGGTGTGACGGAT |
| SEQ ID NO. 624 CP18R - ATCCGTCACACCTGCTCTTGGGTACCGCGGTTGTTAGTCCG |
| GGACCGGGCTGCCTGGTGTTGGCTCCCGTAT |
| SEQ ID NO. 625 CP20F - ATACGGGAGCCAACACCATTCAGGGCTTTTGTGTATGCAC |
| TCCAGCTATCAGACAGAGCAGGTGTGACGGAT |
| SEQ ID NO. 626 CP20R - ATCCGTCACACCTGCTCTGTCTGATAGCTGGAGTGCATACA |
| CAAAAGCCCTGAATGGTGTTGGCTCCCGTAT |
| SEQ ID NO. 627 CP 21F - ATACGGGAGCCAACACCAAGGGACGGCAGGTTCGCAGCT |
| GCGTCATCTTTCTTCAGAGCAGGTGTGACGGAT |
| SEQ ID NO. 628 CP 21R - ATCCGTCACACCTGCTCTGAAGAAAGATGACGCAGCTGCG |
| AACCTGCCGTCCCTTGGTGTTGGCTCCCGTAT |
| SEQ ID NO. 629 CP 22F (71) - ATACGGGAGCCAACACCACGAGGACTTAGACTTGTCC |
| GACATCACAGTGTGCGAGAGCAGGTGTGACGGAT |
| SEQ ID NO. 630 CP 22R (71) - ATCCGTCACACCTGCTCTCGCACACTGTGATGTCGG |
| ACAAGTCTAAGTCCTCGTGGTGTTGGCTCCCGTAT |
| SEQ ID NO. 631 CP 23F - ATACGGGAGCCAACACCACTTCCCTGTCCTTCCCTCAGTG |
| AGGCCTGTCTCCTCAGAGCAGGTGTGACGGAT |
| SEQ ID NO. 632 CP 23R - ATCCGTCACACCTGCTCTGAGGAGACAGGCCTCACTGAGG |
| GAAGGACAGGGAAGTGGTGTTGGCTCCCGTAT |
| SEQ ID NO. 633 CP 24F - ATACGGGAGCCAACACCAGGAGATGTTCGTGTAATAGGGG |
| GTTACACCCGGTCGAGAGCAGGTGTGACGGAT |
| SEQ ID NO. 634 CP 24R - ATCCGTCACACCTGCTCTCGACCGGGTGTAACCCCCTATTA |
| CACGAACATCTCCTGGTGTTGGCTCCCGTAT |
| SEQ ID NO. 635 CP 25F - ATACGGGAGCCAACACCATCGCTCAAGTTCTTCATTACTCC |
| TATCGCTTCCGCTAGAGCAGGTGTGACGGAT |
| SEQ ID NO. 636 CP 25R - ATCCGTCACACCTGCTCTAGCGGAAGCGATAGGAGTAATG |
| AAGAACTTGAGCGATGGTGTTGGCTCCCGTAT |
| Giardia (UDP-N-acetylgalactosamine Surface Antigen; Gi) |
| SEQ ID NO. 637 Gi 22F - ATACGGGAGCCAACACCATTCTACTCCCAGGTATGTCTCTG |
| GGCCCCCCCGGCCAGAGCAGGTGTGACGGAT |
| SEQ ID NO. 638 Gi 22R - ATCCGTCACACCTGCTCTGGCCGGGGGGGCCCAGAGACAT |
| ACCTGGGAGTAGAATGGTGTTGGCTCCCGTAT |
| SEQ ID NO. 639 Gi 25F - ATACGGGAGCCAACACCAACAACATAGCCCTGGCACGAC |
| AGTGGCATACCAGGCAGAGCAGGTGTGACGGAT |
| SEQ ID NO. 640 Gi 25R - ATCCGTCACACCTGCTCTGCCTGGTATGCCACTGTCGTGCC |
| AGGGCTATGTTGTTGGTGTTGGCTCCCGTAT |
| SEQ ID NO. 641 Gi 30F - ATACGGGAGCCAACACCACGTAATGATGTGCACCTCTCTC |
| CGACTGTTTCTCGTAGAGCAGGTGTGACGGAT |
| SEQ ID NO. 642 Gi 30R - ATCCGTCACACCTGCTCTACGAGAAACAGTCGGAGAGAGG |
| TGCACATCATTACGTGGTGTTGGCTCCCGTAT |
| SEQ ID NO. 643 Gi-33F - ATACGGGAGCCAACACCACATCTTATTCGTCCCCAGTCCT |
| TTGGTCTCCTGCTCAGAGCAGGTGTGACGGAT |
| SEQ ID NO. 644 Gi-33R - TCCGTCACACCTGCTCTGAGCAGGAGACCAAAGGACTG |
| GGGACGAATAAGATGTGGTGTTGGCTCCCGTAT |
| SEQ ID NO. 645 Gi-37F - ATACGGGAGCCAACACCACCTGCTGATTTCCTATAATCC |
| GGCCCATACCTTAGGAGAGCAGGTGTGACGGAT |
| SEQ ID NO. 646 Gi-37R - ATCCGTCACACCTGCTCTCCTAAGGTATGGGCCGGATTA |
| TAGGAAATCAGCAGGTGGTGTTGGCTCCCGTAT |
| SEQ ID NO. 647 Gi-38F - ATACGGGAGCCAACACCATAAGAGTCCTCTAAGGTCGCT |
| TATTTTTAACCCCTAAGAGCAGGTGTGACGGAT |
| SEQ ID NO. 648 Gi-38R - ATCCGTCACACCTGCTCTTAGGGGTTAAAAATAAGCGAC |
| CTTAGAGGACTCTTATGGTGTTGGCTCCCGTAT |
| SEQ ID NO. 649 Gi-40F - ATACGGGAGCCAACACCATCCCCACACCCTCGTTCCGACC |
| GCTAGAATCCCCGAAGAGCAGGTGTGACGGAT |
| SEQ ID NO. 650 Gi-40R - ATCCGTCACACCTGCTCTTCGGGGATTCTAGCGGTCGGAA |
| CGAGGGTGTGGGGATGGTGTTGGCTCCCGTAT |
Claims
I claim:1. A DNA ligand sequence consisting of a nucleic acid sequence selected from SEQ ID NOS: 1-650.
2. A composition comprising the DNA ligand sequence of claim 1.
3. The composition of claim 2, wherein said aptamer is capable of binding to a targeted waterborne or foodborne pathogenic bacteria.
4. The composition of claim 2, wherein said aptamer is capable of binding to a targeted waterborne or foodborne pathogenic toxin.
5. The composition of claim 3, being capable of use for detecting said targeted bacteria, wherein said targeted bacteria is present in a sample with at least 10 bacteria per mL.
6. The composition of claim 3, being capable of use for quantifying the number of said targeted bacteria in a sample.
7. The DNA ligand sequence of claim 1, capable of being used for at least one of the assay types: ELISA-like, lateral flow test strip, chemiluminescence, electrochemiluminescence, fluorescence (intensity, lifetime, FP, FRET beacons or competitive FRET), magnetic bead capture, membrane blotting (including dot or slot blotting and the DNA ligand-based analog to “Western” blotting), surface plasmon resonance, plastic-adherent, or radioisotopic detection in food and water samples in tubes, cuvettes or on flat surfaces such as membranes or plastic or glass biochips.
8. The DNA ligand sequence of claim 9 wherein the target is Campylobacter jejuni or a closely related species such as C. coli or C. lari and the DNA ligand sequences are selected from SEQ ID NO's. 1-58.
9. The DNA ligand sequence of claim 9 wherein the target is a pathogenic strain of Escherichia coli and the DNA ligand sequences are selected from SEQ ID NO's. 67-224.
10. The DNA ligand sequence of claim 9 wherein the target is a strain of Listeria monocytogenes or a related species and the DNA ligand sequences are selected from SEQ ID NO's. 279-380.
11. The DNA ligand sequence of claim 9 wherein the target is a strain of Salmonella enterica serovar Typhimurium (formerly Salmonella typhimurium) or a related species and the DNA ligand sequences are selected from SEQ ID NO's. 405-543.
12. The DNA ligand sequence of claim 9 wherein the target is Shiga-like toxin 1 or 2 (or Vero toxins) and the DNA ligand sequences are selected from SEQ ID NO's. 544-612.
13. The DNA ligand sequence of claim 9 wherein the target is a strain of Enterococcus faecalis or a closely related Gram positive organism and the DNA ligand sequences are selected from SEQ ID NO's. 59-66.
14. The DNA ligand sequence of claim 9 wherein the target is Cryptosporidium parvum (or a closely related species) and the DNA ligand sequences are selected from SEQ ID NO's. 613-636.
15. The DNA ligand sequence of claim 9 wherein the target is a species of Giardia parasite and the DNA ligand sequences are selected from SEQ ID NO's. 637-650.
16. The DNA ligand sequence of claim 9 wherein the target is a general Gram negative bacterial pathogen as detected by its lipopolysaccharide (LPS endotoxin) or common core component of LPS and the DNA ligand sequences are selected from SEQ ID NO's. 225-278.
17. The DNA ligand sequence of claim 9 wherein the target is a general Gram positive bacterial pathogen or a pathogenic or nonpathogenic mold or fungus as detected by its peptidoglycan or chitin or common components such as N-acetyl-glucosamine (NAG) and N-acetylmuramic acid (NAM) and the DNA ligand sequences are selected from SEQ ID NO's. 381-404.
18. The DNA ligand sequence of claim 1, wherein said nucleic acid sequence is produced by chemical synthesis, wherein said nucleic acid sequence is linear, wherein said nucleic acid sequence has two- or three-dimensional linked multiple aptamers or aptamer binding sites in which said aptamer binding sites have two or more single-stranded segments of 5-10 bases, and wherein intervening nucleotide sequences between said aptamer binding sites do not bind the target.
19. The DNA ligand sequence of claim 1, wherein said nucleic acid sequence is produced biosynthetically (enzymatically) by polymerase chain reaction (“PCR”), asymmetric PCR, or other DNA polymerase-based reaction using a complementary template DNA into which aptamers or their binding sites are linked with intervening nucleotide sequences that do not bind the target.
Images & Drawings included:
Sources:
- United States Patent and Trademark Office - verify current appl. status at the USPTO↗
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