WO1995033854A1 - Use of a specific marker for detection of salmonella with pcr - Google Patents

Abstract

A method is provided for the selection of diagnostic genetic markers fragments and useful in the identification of bacteria at the genus, species or serotype level. The method first involves the identification of a RAPD polymorphic DNA fragment common to a particular microbial group, the identification of the most conserved regions of that fragment, and the preparation of specific primers useful for detecting the presence of a marker within the fragment whereby that set of primers is then useful in the identification of all members of the chosen microbial group. Also provided is a specific diagnostic marker for Salmonella and primers directed thereto.

Description

Use of a specific marker for detection of Salmonella with PCR.

FIELD OF INVENTION

The invention relates to the field of molecular biology and the use of randomly amplified nucleic acid fragments for the selection of genetic markers useful in the identification of bacteria at the genus, species or serotype level. This invention further relates to a specific DNA marker sequence useful_ for the detection of Salmonella, and use of that diagnostic marker to determine if an unknown bacterium is a member of the genus Salmonella . BACKGROUND

An integral aspect of the field of microbiology is the ability to positively identify microorganisms at the level of genus, species or serotype. Correct identification is not only an essential tool in the laboratory but plays a significant role in the control of microbial contamination in the processing of food stuffs, production of agricultural products and monitoring of environmental media such as ground water. Increasing stringency in regulations which apply to microbial contamination have resulted in a corresponding increase in industry resources which must be dedicated to contamination monitoring.

Of greatest concern is the detection and control of pathogenic microorganisms . Although a broad range of microorganisms have been classified as pathogenic, attention has primarily focused on a few bacterial groupings such as Escherichia, Salmonella, Listeria and Clostridia . Typically, pathogen identification has relied on methods for distinguishing phenotypic aspects such as growth or motility characteristics, and immunological and serological characteristics. Selective growth procedures and immunological methods are the traditional methods of choice for bacterial identification, and can be effective for the presumptive detection of a large number of species within a particular genus . However, these methods are time consuming, and are subject to error. Selective growth methods require culturing and subculturing in selective media, followed by subjective analysis by an experienced investigator. Immunological detection (e.g., ELISA) is more rapid and specific, however it still requires growth of a significant population of organisms and isolation of the relevant antigens . For these reasons interest has turned to detection of bacterial pathogens on the basis of nucleic acid sequence.

It is well known, for example, that nucleic acid sequences associated with the ribosomes of bacteria are often highly conserved across genera and are therefore useful for identification (Webster, U.S. 4,717,653 and U.S. 5,087,558; Enns, Russel K. Lab . Med. , 19, 295,

(1998); Mordarski, M. Soc . Appl . Bacteriol . Tech . Ser. , 20 (Chem. Methods Bact. Syst. ) , 41, (1985)) . Weisburg et al., (EP 51736) disclose a method for the detection and identification of pathogenic microorganisms involving the PCR amplification and labeling of a target nucleotide for hybridization to 16S rDNA of E. coli . and Lane et al. , (WO 9015157) teach universal nucleic acid probes that hybridize to conserved regions of 23S or 16S rRNA of eubacteria. Although bacterial ribosomal nucleic acids contain highly conserved sequences, they are not the only sources of base sequence conservation that is useful for microorganism identification. Wheatcroft et al., (CA 2055302) describe the selection of transposable elements, flanked by unique DNA sequences for the detection of various Rhizobium strains. Similarly Tommassen et al., (WO 9011370) disclose polynucleotide probes and methods for the identification and detection of gram-positive bacteria. The method of Tommassen et al., relies on probes corresponding to relatively short fragments of the outer membrane protein OmpA, known to be highly conserved throughout gram-positive genera. Atlas et al., (EP 517154) teach a nucleic acid hybridization method for the detection of Giardia sp . based on designing probes with sequences complementary to regions of the gene encoding the giardin protein. Webster, J. A., (U.S. 4717653) has expanded upon the use of rRNA in disclosing a method for the characterization of bacteria based on the comparison of the chromatographic pattern of restriction endonuclease- digested DNA from the unknown organism with equivalent chromatographic patterns of at least 2 known different organism species. The digested DNA has been hybridized or reassociated with ribosomal RNA information- containing nucleic acid from, or derived from a known probe organism. The method of Webster et al., effectively establishes a unique bacterial nucleic acid "fingerprint" corresponding to a particular bacterial genus against which unknown "fingerprints" are compared. The methods described above are useful for the detection of bacteria but each relies upon knowledge of a gene, protein, or other specific sequence known a priori to be highly conserved throughout a specific bacterial group. An alternative method would involve a nontargeted analysis of bacterial genomic DNA for specific non-phenotypic genetic markers common to all species of that bacteria. For example, genetic markers based on single point mutations may be detected by differentiating DNA banding patterns from restriction enzyme analysis. As restriction enzymes cut DNA at specific sequences, a point mutation within this site results in the loss or gain of a recognition site, giving rise in that region to restriction fragments of different length. Mutations caused by the insertion, deletion or inversion of DNA stretches will also lead to a length variation of DNA restriction fragments. Genomic restriction fragments of different lengths between genotypes can be detected on Southern blots (Southern, E. M., J. Mol . Biol . 98, 503, (1975) . The genomic DNA is typically digested with any restriction enzyme of choice, the fragments are electrophoretically separated, and then hybridized against a suitably labelled probe for detection. The sequence variation detected by this method is known as restriction length polymorphism or RFLP (Botstein et al. Am. J. Hum. Genet . 342, 314, (1980)) . RFLP genetic markers are particularly useful in detecting genetic variation in phenotypically silent mutations and serve as highly accurate diagnostic tools. Another method of identifying genetic polymorphic markers employs DNA amplification using short primers of arbitrary sequence. These primers have been termed 'random amplified polymorphic DNA', or "RAPD" primers, Williams et al., Nucl . Acids . Res . , 18, 6531 (1990) and U.S. 5,126,239; (also EP 0 543 484 A2, WO 92/07095,

WO 92/07948, WO 92/14844, and WO 92/03567) . The RAPD method amplifies either double or single stranded nontargeted, arbitrary DNA sequences using standard amplification buffers, dATP, dCTP, dGTP and TTP and a thermostable DNA polymerase such as Tag. The nucleotide sequence of the primers is typically about 9 to 13 bases in length, between 50 and 80% G+C in composition and contains no palindromic sequences. RAPD detection of genetic polymorphisms represents an advance over RFLP in that it is less time consuming, more informative, and readily susceptible to automation. Because of its sensitivity for the detection of polymorphisms RAPD analysis and variations based on RAPD/PCR methods have become the methods of choice for analyzing genetic variation within species or closely related genera, both in the animal and plant kingdoms. For example, Landry et al., (Genome, 36, 580, (1993)) discuss the use of RAPD analysis to distinguish various species of minute parasitic wasps which are not morphologically distinct. Van Belkum et al. , (Mol . Biochem Parasitol 61, 69,

(1993) ) teach the use of PCR-RAPD for the distinction of various species of Giardi.

In commonly assigned application USSN 07/990,297, Applicants disclose a method of double-nested PCR which is used to detect the presence of a specific microbe. This disclosure first describes identifying a random unique segment of DNA for each individual microorganism which will be diagnostic for that microorganism. To identify and obtain this diagnostic nucleic acid segment a series of polymorphic markers is generated from each organism of interest using single primer RAPD analysis. The RAPD series from each organism is compared to similarly generated RAPD series for other organisms, and a RAPD marker unique to all members of the group is then selected. The unique marker is then isolated, amplified and sequenced. Outer primers and inner primers suitable for double-nested PCR of each marker may then be developed. These primers comprise sequence segments within the RAPD markers, wherein the inner set of primers will be complementary to the 3' ends of the target piece of nucleic acid. These nested primers may then be used for nested PCR amplification to definitely detect the presence of a specific microorganism. In the present method Applicants have more particularly adapted and more fully described this RAPD methodology to identify a sequence, or marker; the presence of which will be diagnostic for all individuals of a genetically related population. The present method first involves a RAPD amplification of genomic DNA of a representative number of individuals within a specific genus, species or subspecies to produce a RAPD amplification product, termed the diagnostic fragment. This diagnostic fragment must be present in the RAPD profiles in over 90% of the individuals tested. Sequence information from the diagnostic fragment will then enable identification of the most suitable PCR primer binding sites within the diagnostic fragment to define a unique diagnostic marker. Primers flanking this marker will be useful to produce an amplification product in the genetically selected group, but will not produce any amplification product in individuals outside of that group.

An important aspect of the present invention is the identification of the most conserved primer binding sites within this diagnostic sequence, which is accomplished by first determining which individuals, in the genus or grouping to be detected, exhibit the most genetic variation within the diagnostic sequence. Screening this subpopulation of "most polymorphic" individuals using various primers generated from the diagnostic sequence will define the most highly conserved primer bindings sites within the diagnostic fragment. Primers directed toward these highly conserved primer binding sites are then useful for the detection of all members of the genus, based upon the ability of the selected primers to amplify the diagnostic marker present in that particular population. A "yes" or "no" answer can then be readily provided to the question of whether a microorganism is a member of the genetically related population. If DNA amplification occurs using these primers, the target is present and the identity is confirmed as "yes". If amplification does not occur, the answer is no; the microorganism is not a member of that genetically related population. The necessity of electrophoresis to determine the presence of a marker of any particular size is eliminated.

Applicants ' method is distinctive in that to accomplish detection of a member of a group of organisms, the method first relies on determining the most conserved regions of a diagnostic fragment from a phenotypically uncharacterized segment of DNA common to all members of that group. One of skill in the art will recognize that conservation of sequence may represent both an ally and an enemy in the process of identification of the members of a particular genus. For example, many bacterial sequences are conserved across genera and hence would not be useful in the determination of species within a particular genus. It is precisely for that reason that methods heretofore elucidated in that art rely primarily on the analysis of sequences derived from proteins or genes known to be specific to a particular genus, i.e., ribosomal RNA or outer membrane proteins. Applicants' method departs from the art in that the conserved sequences of the instant method are not derived from a known gene, nor is the sequence associated with any known phenotypic characteristic. Further, Applicants' method is refined by the selection of the most conserved region of the diagnostic fragment by comparison with the genomic DNA of a subpopulation of individuals exhibiting the most genetic variation within the diagnostic fragment. Applicants ' method presupposes that the regions of the diagnostic fragment most conserved within the polymorphic subpopulation will also be conserved within the larger population comprising all members of the genus. Applicants are unaware of any art teaching this supposition.

The process of the present invention has been enabled in the present disclosure by the elucidation of a diagnostic marker sequence which is useful in rapidly and definitively identifying bacteria from the genus Salmonella.

SUMMARY OF THE INVENTION The present invention provides a method for the determination of diagnostic genetic markers for the identification of individuals of a genetically related population of microorganisms . The method comprises the following steps: (i) The first step entails performing a RAPD amplification on the genomic DNA of a representative number of individuals from a genetically related population, wherein said number of individuals will comprise the positive test panel, and whereby the RAPD amplification performed on individuals of the positive test panel will generate a RAPD marker profile from each individual of the positive test panel. Similarly the same RAPD amplification is performed on the genomic DNA of a significant number of individuals genetically unrelated to the positive test panel, wherein said number of genetically unrelated individuals will comprise the negative test panel, and whereby the RAPD amplification on individuals of the negative test panel will generate a RAPD marker profile from each individual of the negative test panel.

(ii) The second step comprises comparing the RAPD marker profiles from individuals of the positive test panel with the RAPD marker profiles from individuals of the negative test panel and thereby selecting a diagnostic nucleic acid fragment wherein said fragment is present in over 90% of the RAPD marker profiles from the positive test panel and absent in the RAPD marker profiles from the negative test panel, (iii) The nucleotide sequence of said diagnostic fragment is determined to identify available primer binding sites.

(iv) One or more pairs of primers corresponding to the available primer binding sites of step (iii) are prepared. (v) Primer-directed amplification is performed on the genomic DNA of a significant number of individuals from the positive test panel using the primer pairs of step (iv) , whereby a subpopulation of individuals which are the most polymorphic with respect to said diagnostic fragment is identified.

(vi) Primer-directed amplification is next performed on the genomic DNA of said polymorphic subpopulation of (v) using several candidate primer pairs derived from the sequence of said diagnostic fragment, whereby a particular candidate primer pair which produces primer amplification product for the highest percentage of individuals within the polymorphic subpopulation is thereby empirically selected. This primer pair now defines the diagnostic marker for that genetically related population of step (i) .

(vii) The method further comprises the step of confirming that the particular primer pair identified in (vi) is useful for amplifying a diagnostic genetic marker which is present in all of the genetically related individuals while absent in all of the genetically unrelated individuals, wherein said confirmation is accomplished by amplifying the genomic DNA of all individuals of the positive and negative test panels with said particular primer pair to determine that said primer pair is effective in amplifying a diagnostic genetic marker in all individuals of the positive test panel and is ineffective in amplifying said diagnostic marker in all individuals of the negative test panel. This invention further provides a method of determining whether an unknown bacterium is a member of the genus Salmonella, comprising analyzing the genomic DNA of said unknown bacterium to detect the presence of nucleic acid Sequence ID No. 1 or its complement, No. 20. In a preferred embodiment, said analysis can be accomplished by amplification using the primer pairs of Sequence ID Nos. 15 and 19.

This invention further provides isolated nucleic acid fragments having Sequence ID Nos. 1, 4, 14, 15, 16, 17, 18, 19, 10, 21 and 22.

BRIEF DESCRIPTION OF THE FIGURES

Figure 1A is a composite photograph showing electrophoretic marker profiles of amplification products for the positive test panel of Salmonella strains amplified with a single RAPD primer, 12CN03 (Sequence ID No. 4) .

Figure IB is a composite photograph showing electrophoretic marker profiles of amplification products for DNA from the negative test panel comprising a variety of non-Salmonella bacterial strains amplified with a single RAPD primer, 12CN03 (Sequence ID No. 4) . Figure 2 is the sequence of an 811 bp Salmonella diagnostic nucleic acid fragment, Sequence ID No. 1, which was generated by amplification of genomic DNA isolated from Salmonella typhlmurium (ATCC 29057) with the single 12-base primer 12CN03. The complementary strand to Sequence ID No. 1 is Sequence ID No. 20. Within this 811 bp nucleic acid of Figure 2, at position No. 35 to 786, is Sequence ID No. 21 and its complement, Sequence ID No. 22, which comprise the diagnostic marker of the invention for Salmonella .

Figure 3 is a composite photograph showing normal (N) and polymorphic (P) electrophoretic PCR amplification products generated from the primers 54-23/665rc-23 (Sequence ID Nos. 10/13) and primers 126-23/648rc-23 (Sequence ID Nos. 11/12) from a variety of Salmonella strains.

Figure 4 is a composite photograph showing PCR amplification of a variety of non-Salmonella strains using primer #60-26 (Sequence ID No. 15) and primer #761rc-26 (Sequence ID No. 19).

Figure 5 is a composite photograph showing PCR amplification of a variety of Salmonella strains using primer #60-26 (Sequence ID No. 15) and primer #761rc-26 (Sequence ID No. 19) .

DETAILED DESCRIPTION OF THE INVENTION As used herein the following terms may be used for interpretation of the claims and specification. "Nucleic acid" refers to a molecule which can be single stranded or double stranded, comprising monomers (nucleotides) containing a sugar, phosphate and either a purine or pyrimidine. In bacteria, lower eukaryotes, and in higher animals and plants, "deoxyribonucleic acid" (DNA) refers to the genetic material while

"ribonucleic acid" (RNA) is involved in the translation of the information from DNA into proteins.

The term "primer-directed amplification" refers to any of a number of methods known in the art that result in logarithmic amplification of nucleic acid molecules using the recognition of a specific nucleic acid sequence or sequences to initiate an amplification process. Applicants contemplate that amplification may be accomplished by any of several schemes known in this art, including but not limited to the polymerase chain reaction (PCR) or ligase chain reaction (LCR) . If PCR methodology is selected, the amplification method would include a replication composition consisting of for example, nucleotide triphosphates, two primers with appropriate sequences, DNA or RNA polymerase and proteins. These reagents and details describing procedures for their use in amplifying nucleic acids are provided in U.S. Patent 4,683,202 (1987, Mullis, et al.) and U.S. Patent 4,683,195 (1986, Mullis, et al.) . A "diagnostic fragment" refers to a particular DNA sequence which is highly conserved amongst the individuals of a particular genetically related population, for example, a genus, species, or subspecies of bacteria. In the instant invention, the term "diagnostic fragment" is used to refer to that fragment generated during RAPD amplification which is present in the RAPD profiles from a particular related group but absent in profiles from individuals outside of that group. The term "diagnostic marker" is used herein to refer to that portion of the diagnostic fragment which can be targeted to produce an amplification product in only members of the related group. The diagnostic marker is not present outside the related group, and attempts to amplify the diagnostic markers in individuals outside of the related group will result in no nucleic acid being amplified.

The term "primer" refers to a nucleic acid fragment or sequence that is complementary to at least one section along a strand of the sample nucleic acid, wherein the purpose of the primer is to sponsor and direct nucleic acid replication of a portion of the sample nucleic acid along that string. Primers can be designed to be complementary to specific segments of a targeted sequence. In PCR, for example, each primer is used in combination with another primer forming a "primer set" or "primer pair", this pair flanks the targeted sequence to be amplified. In RAPD amplification, single arbitrary primers are used to amplify nontargeted segments of nucleic acid which are located between the primer sequence sites in opposing DNA strands. The term "primer", as such, is used generally herein by Applicants to encompass any sequence-binding oligonucleotide which functions to initiate the nucleic acid replication process. "Diagnostic primers" will refer to primers designed with sequences complementary to primer binding sites on diagnostic marker. Diagnostic primers are useful in the convenient detection and identification of individuals of a genetically related population. A genetically related population refers to any grouping of microorganisms possessing multiple or single phenotypic characteristics of sufficient similarity to allow said organisms to be classified as a single genus, species, or subspecies of bacteria. For purposes of the present disclosure, examples of genetically related populations include, for example, the genus Salmonella or the species Listeria monocytogenus .

A "test panel" refers to a particular group of organisms or individuals selected on the basis of their genetic similarity to each other, or their genetic dissimilarity to another group (i.e., another genus, species, subspecies) . A "positive test panel" will refer to a number of individuals selected for the desired genetic similarity between those individuals, and in the instant case will be comprised of individuals included within the desired genetically related population. Examples of a positive test panel would be, for example, representative members of all the species of a particular genus (assuming that genus is the desired 'genetically related population') . Similarly, a "negative test panel" will refer to a test panel selected on the basis of genetic diversity between its members and the members of the positive test panel. An example of a negative test panel when the positive test panel is bacteria of the genus Salmonella, would be bacteria and other organisms outside of the Salmonella genus .

The term "representative number of individuals" refers to individuals within a genetically related population which are selected such that they represent the widest possible range of biochemical, morphological and immunological attributes known to exist within the targeted genetically related population. The term "representative number of individuals", when referring to individuals genetically unrelated to the genetically related population (the negative test panel) , means those microorganisms which are not included within the genetically related group but are genetically similar to that group. The term "unknown bacterium" refers to a bacterium whose identity is unknown.

The term "derived from", with reference to an amplification primer, refers to the fact that the sequence of the primer is a fragment of the sequence from which it has been "derived". The fragment is always denoted in a 5' to 3' orientation. The useful primer sequence size range for PCR amplification is about 15 base pairs to about 30 base pairs in length. The term "RAPD" refers to 'random amplified polymorphic DNA' . "RAPD amplification" refers to a method of single primer directed amplification of nucleic acids using short primers of arbitrary sequence to amplify nontargeted, random segments of nucleic acid. U.S. 5,126,239. "RAPD method" or "RAPD analysis" refers to a method for the detection of genetic polymorphisms involving the nontargeted amplification of nucleic acids using short primers of arbitrary sequence, whereby the profile or pattern of 'RAPD' amplification products is compared between samples to detect polymorphisms. "RAPD primers" refers to primers of about 8 to 13 bp, of arbitrary sequence, useful in the RAPD amplification or RAPD analysis according to the instant method. The "RAPD marker profile" refers to the pattern, or fingerprint, of amplified DNA fragments which are amplified during the RAPD method and separated and visualized by gel electrophoresis.

The diagnostic marker of the invention, once identified, can be used to identify an unknown microorganism by any of several analysis methods. In the present invention, primers flanking the marker are useful to amplify the marker using PCR. Alternatively, nucleic acid probes could be developed based upon some or all of the diagnostic marker sequences and thus used to detect the presence of the marker sequence using standard hybridization and reporter methods. It is contemplated that regions of about 30 base pairs or more of the diagnostic marker, especially encompassing the primer regions could be used as sites for hybridization of diagnostic probes. The present invention provides a method for the determination of genetic markers useful in the detection and identification of all members of a genetically related population. Examples of genetically related populations include following: 1) microorganisms belonging to the genus Salmonella

2) microorganisms belonging to the species Listeria monocytogenes

3) microorganisms belonging to the serotype of Escherichia coli designated 0157:H7. The instant method is particularly useful for the detection of specific genera, species or subspecies of bacteria which may be present either in food, human or animal body fluids or tissues, environmental media or medical products and apparatti.

To practice the instant method, a RAPD amplification, using a short arbitrary primer, is performed on the genomic DNA of at least 30 individuals from a genetically related population. These individuals are selected such that they represent the widest possible range of biochemical, morphological and immunological attributes known to exist within the targeted genetically related population. The electro- phoretically resolved patterns of amplification products produced by the RAPD amplifications are then compared, in hopes of indentifying a distinctive RAPD amplification product which is present in over 90% of the individuals tested. If this product is not found when the same RAPD amplification is then performed on the genomic DNA of at least 30 strains of microorganisms which fall outside of the targeted population, then this fragment is deemed to be suitable diagnostic fragment and it is then sequenced to determine suitable primer binding sites for further analysis and primer generation. It is imperative that the most conserved regions of the diagnostic fragment be determined for the generation of useful diagnostic primers, i.e., primers which will be capable of producing an amplification product in all members of the genetically related group. Determination of the most conserved region is accomplished by first determining which individuals, in the population group to be detected, exhibit the most genetic variation within the diagnostic fragment sequence. The genomic DNA of this polymorphic subpopulation is then analyzed with several sets of PCR primers generated from the diagnostic fragment to define the most highly conserved PCR primer bindings sites within the diagnostic fragment. Primers generated from these highly conserved primer binding sites are then used in assay methods for the detection of all members of the genus. The method is more particularly described below with reference to the specific method steps as provided in the Summary of the Invention. Selection of RAPD primers and detection of diagnostic fragment in members of the positive and negative control panels, steps (i) and (ii) :

Genomic DNA isolated from positive and negative test panels of microorganisms was subjected to RAPD amplification using eight 12-base primers of arbitrary sequence. The positive test panel comprised 62

Salmonella serotypes and is described in detail in the GENERAL METHODS section below. The negative test panel consisted of a variety of 11 non-Salmonella species and is also described in the GENERAL METHODS section below. Techniques for the isolation of genomic DNA are common and well known in the art and examples may be found in Sambrook et al., Molecular Cloning: A Laboratory Manual - volumes 1,2,3 (Cold Spring Harbor Laboratory: Cold Spring Harbor, New York. RAPD primers of 12 bases in length were used because at this primer length the RAPD patterns generally contained one to five amplified DNA fragments. Use of shorter primers frequently resulted in a large number of amplification products, which made the extraction of a single homogeneous fragment for sequencing much more difficult. When primers of greater than 12 bases were used a significant fraction of the bacterial strains produced no RAPD products which would have necessitated the screening of a much larger number of arbitrary primers. One of the primers, designated 12CN03, was found to produce both an 800 bp and 2000 bp amplification product in over 90% of the positive test panel. 12CN03 had the sequence of TTA GTC ACG GCA (Sequence ID No. 4) . Neither the 800 bp nor 2000 bp fragment was seen in the amplification products of the negative test panel with primer 12CN03. Because of its shorter length it was decided to focus attention on the 800 bp fragment for further analysis and this became the Salmonella diagnostic fragment. Figure 2 shows this fragment, wherein the top strand is shown as Sequence ID No. 1, and its complementary strand is shown as Sequence ID No. 20.

The 800 bp fragment did not appear with equal intensity in all of the Salmonella strains in the positive test panel. Considering the extreme sensitivity of RAPD patterns to sequence polymorphisms, it is assumed that the variations in the intensity of the RAPD marker in some Salmonella strains was the result of a minor sequence variation in the vicinity of the primer site. Considering the frequency at which the Salmonella fragment appeared, it could still be possible for highly conserved sequences, which are common to all members of the genus Salmonella, to be found between the 12CN03 priming sites flanking the 800 bp fragment. Sequencing of diagnostic fragmen , step (iii) :

The 800 bp product for Salmonella typhimurium 587 (ATCC #29057) was selected for extraction and sequencing. This strain was selected because it is a well-characterized type strain and because this serotype of Salmonella is a frequently encountered pathogenic microorganism. The amplification product was isolated by gel electrophoresis and the fragment was cut from the gel, eluted and reamplified with the 12CN03 primer to provide quantities of DNA suitable for sequencing. Sequencing was accomplished using the chain-termination method of Sanger et al . (Proc. Natl . Acad. Scl . USA 74, 5463, (1977)) using fluorescence-labeled dideoxynucleotides and the Genesis 2000™ DNA Analysis

System (E. I. du Pont de Nemours and Company, Wilmington, DE) . The complete sequence of the 800 bp Salmonella diagnostic fragment is shown in Figure 2. Identification of the most highly conserved regions of the diagnostic fragment, steps (iv) and (v) :

In order for the Salmonella diagnostic fragment to be useful for the detection of all members of the

Salmonella genus, it is necessary to identify the most conserved regions (i.e., primer sites) of the diagnostic fragment. In theory, identification of the conserved regions could be accomplished by generating primers to the fragment based on the known sequence and isolating and sequencing the same fragment from all members of the Salmonella genus. Sequencing, alignment and comparison of all the sequences would allow for the determination of the most conserved portion of the sequence. Although, this approach is theoretically possible, in reality it is prohibitively time consuming and expensive. The development of a general method requires an alternate approach.

The instant method provides a more direct and rapid method of identifying the most conserved regions of the diagnostic fragment, wherein the first step is the identification of a subpopulation of Salmonella sp. which show the greatest overall variation within the 800 bp diagnostic fragment. The strains which constitute this subpopulation are referred to as

"polymorphic" Salmonella . It must be understood that this subpopulation is defined as polymorphic only in the context of the diagnostic nucleic acid fragment shown in Figure 2 and not with respect to the classical biochemical and morphological attributes, which are commonly used to classif species . Once the members of the positive test panel that are polymorphic have been identified, these polymorphic Salmonella are used to screen for the most highly conserved regions of the diagnostic fragment. This approach presumed that the priming sites that are conserved among the most polymorphic Salmonella are also conserved in the general population of Salmonella .

In order to determine which Salmonella were "polymorphic" two sets of amplification primer pairs were arbitrarily selected from the diagnostic fragment and amplifications were carried out on DNA isolated from 740 strains of Salmonella representing all six subgenus groups for each of the primer sets. The initial primer sets were selected to achieve a GC content of 55 ± 3% for two pairs of primers all of which are located within 200 bases of the CN03 priming sites. Any strain of Salmonella which showed an amplification polymorphism was classified as a "polymorphic" Salmonella . The following amplification events were regarded as polymorphic when they occurred with either primer set: i) weak, inconsistent, or total lack of production of an amplification product ii) amplification products which are larger or smaller than the generally observed amplification product iii) the presence of more than one amplification product.

The largest single polymorphic group among the 740 strains of Salmonella were those which produced no amplification product with at least one of the primer pairs. However, a number of strains produced either multiple amplification products or products of a different size. Some examples of these types of polymorphic amplification events are shown in Figure 3. From the original group of 740 Salmonella strains a group of 43 polymorphic Salmonella were selected. Selection of a diagnostic primer pair to amplify the diagnostic genetic marker, step (vi) : Once the subpopulation of "polymorphic" Salmonella was identified primers were prepared for a large number sites at both ends of the Salmonella fragment sequence. The initial criteria for primer selection was that the GC content of the two primers should match and that the overall GC content fell in the range of 55 ± 3% . The second criteria was that the pairs of primers were all located within 200 bases of the CN03 priming sites. Using these primers amplifications were carried out on genomic DNA from the polymorphic Salmonella . Primer combinations which produced an amplification product in over 90% of the polymorphic Salmonella were selected for further evaluation. In such combinations, one of the primer sites was "locked" while the second priming site was moved upstream or downstream one base at a time. In this way the priming site that found the highest portion of polymorphic Salmonella was identified and fixed. The second priming site was then "locked" and additional primers were prepared, which moved the first priming site at the other end of the Salmonella target sequence upstream or downstream one base at a time. When the priming sites which produced an amplification product for the highest percentage of polymorphic Salmonella were identified, these primers were then evaluated for the entire test panel of Salmonella strains. Based on this analysis four regions were identified as being most conserved. Within these conserved regions five primer- pair combinations were capable of producing an amplification product in > 95% of the polymorphic Salmonella . These primer combinations were selected for further testing. Confirmation of selected primer pair as a diagnostic genetic marker, step (viii) :

The selected priming sites were understood to be highly conserved among the "polymorphic" Salmonella . The initial step in the final screening procedure was the determination of which, if any, priming sequences were conserved outside the genus Salmonella . The selectivity of the Salmonella primer sets was evaluated using a negative test panel consisting of over 100 strains representing 28 species which were either similar phenotypically to Salmonella or likely to be found in similar environments. The primer combination which showed the lowest rate of false positive responses in the negative test panel was then evaluated to determine its inclusivity for a positive test panel consisting of over 1480 Salmonella strains.

EXAMPLES GENERAL METHODS Suitable methods of genetic engineering employed herein are described in Sambrook et al., Molecular Cloning: A Laboratory Manual - volumes 1,2,3 (Cold Spring Harbor Laboratory: Cold Spring Harbor, New York, 1989), and in the instructions accompanying commercially available kits for genetic engineering. GeneClean (BiolOl LaJolla, CA) was used to isolate nucleic acid fragments from agarose gels and to remove enzymes from restriction digests and was performed as specified by the manufacturer. Unless otherwise specified all other standard reagents and solutions used in the following examples were supplied by J. T. Baker Co. (Phillipsburg, NJ) . Construction of Positive and Negative Test Panels

For the identification of a genus level Salmonella RAPD marker a positive test panel consisting of a variety of Salmonella subgenera was constructed to insure that the marker would include a broad range of Salmonella strains. The positive test panel contained of the following Salmonella serotypes: Subgenus I; S. typhimurium, S. typhi, S. enteritidis, S. saintpaul, S. binza, S. napoli, S. clerkwell, S. infantis, S. newport, S. heidelberg, S. virchow, S. Stanley, S. senftenberg, S. gallinarium, S. cholerasuis, S. paratyphi, S. bredeney, S. kedougou, S. montevideo, S. hadar, S. panama, S. braenderup, S. blockley, S. agona, S. brandenberg, S. anatum, S. thompson, S. berta, S. manchester, S. ealing, S. eastbourne, S. indiana, S. weltevreden, S. bracknell, S. bovismorbif ^'icans, S. bareilly, S. bristol, S. bergen, S. berkeley, S. birkinhead, S. austin, S. amager, S. blukwa, S. bonn, S. brazil, S. butantan, S. bodjonegro, S. adelaide, S. allandale, S. albuquerque, S. aequatoria, abaetetube, S. alabama, S. alachua, and S. Chicago; Subgenus II; S. artis, S. bloemfontein, S. bulawayo, S. bleadon, S. betioky, S. basel; Subgenus Ilia; S. arizonae; Subgenus V; S. brook field.

The negative test panel in the screening for a RAPD marker specific to Salmonella consisted of the following species; Escherichia coli, Escherichia blattae, Escherichia fregusonii , Escherichia hermani, Escherichia vulneris, Shigella sonnei, Shigella flexneri, Shigella dysenteria, Shigella boydii, Citrobacter diver sus, and Citrobacter freundii . These species represent a sampling of strains which are not included within the genus Salmonella but are genetically similar to

Salmonella . If strains representing these species show a substantially different RAPD pattern when amplified with the arbitrary primer used to generate the Salmonella marker, and if the selected Salmonella marker is absent from the pattern, it is expected that the marker sequence will be selective for Salmonella .

EXAMPLE 1 ISOLATION OF DIAGNOSTIC FRAGMENT FROM SALMONELLA SP . RAPD Screen Test Results:

Genomic DNA was isolated from members of both the positive and negative test panel members (above) and used to screen eight, 12-base primers of arbitrary sequence. These primers were used to generate RAPD patterns for strains representing the positive and negative test panels. The primers used in the initial RAPD screening are listed in Table I .

IAβ E_I

Twelve-Base Arbitrary Primers Used in the

Generation of RAPD Patterns for the Purpose of

Identifying a Specific Genus Level Salmonella Marker

12CN01 - AGC TGA TGC TAC (Sequence ID No. 2)

12CN02 - AGT CGA ACT GTC (Sequence ID No. 3)

12CN03 - TTA GTC ACG GCA (Sequence ID No. 4)

12CN04 - TGC GAT ACC GTA (Sequence ID No. 5)

12CN05 - CTA CAG CTG ATG (Sequence ID No. 6)

12CN06 - GTC AGT CGA ACT (Sequence ID No. 7)

12CN07 - GGC ATT AGT CAC (Sequence ID No. 8)

12CN08 - CGT ATG CGA TAC (Sequence ID No. 9)

The primers were used individually and as mixed pairs in the following amplification protocol; For each 50 μl reaction, 2 μl - dNTP mix (5 mM dNTP each) , 35 μl deionized water, 5 μl - 10X reaction buffer (500 mM KCl, 100 mM tris @ pH 8.3, 15 mM MgCl₂, 0.003% gelatin), 2.5 μl - each primer (10 mM) (5 μl if only one primer is used), 0.4 μl Taq polymerase (5 U/μl) , and 1.2 μl Taq dilution buffer (10 mM tris θ pH 8.0 and 1.0% Tween 20) were combined. 1.0 μl - genomic bacterial DNA @ 50 ng/μl was added. The reaction was heated to 94°C for 5 minutes. 32 cycles of the following temperature cycle were run; 1' @ 94°, 5' @ 46°, 2' ramp to 72°C, and 2' @ 72°C. A 5 μl aliquot of the reaction was combined with 2 μl of Ficol-loading buffer and run on a 4% acrylamide gel (29:1) /I .Ox TBE.

Figure 1A shows the RAPD patterns as separated by gel electrophoresis for samples of 16 different species of Salmonella from the positive test panel which was amplified with a single primer, 12CN03. The lanes are correlated with the Salmonella species as follows:

Lane Species and T.D. No. Lane Species and I.P. No.

1 S. typhimuriu 587 9 S. infantis 728 (ATCC 29057)

2 S. typhlmurium 588 10 S. heidelberg 577 (ATCC 29631)

3 S. binza 1085 11 S. virchow 738

4 S. napoli 966 12 S. Stanley 739

5 S. enteritidis 1109 13 S. senftenberg 740

6 S. enteritidis 737 14 S. gallinarium 741

7 S. newport 707 15 S. cholerasuis 917 (ATCC 6962) (ATCC 13312)

8 S. arizonae 725 16 S. paratyphi A 918 (ATCC 13314) (ATCC 9150)

Standard amplification conditions for amplification of DNA from the positive test panel consisted of 0.2 mM dNTPs, 1 μM 12CN03 primer and a reaction buffer of 50 mM KCl, 10 mM tris @ pH 8.3, 1.5 mM MgCl₂, and 0.0003% gelatin. A total of 32 cycles were run under the following conditions: 1' at 94°C; 5' at 46°C; 2' ramp to 72°C and 2' at 72°C. The final cycle was followed by an additional 9' at 72°C. Unlabeled lanes contain molecular weight markers of the following sizes; 228, 412, 693, 1331, and 2306 base pairs (bp) . RAPD amplification products were electrophoresed in 4% acrylamide/bisacrylamide (29/1) using a 1.0 X tris- borate-EDTA running buffer for 55 minutes at a field strength of 14V/cm. Following electrophoresis the gels were stained for 15 minutes in a solution of ethidium bromide at 0.25 μg/ml. As is evident by Figure 1A the positive test panel produced two characteristic amplification products of 800 and 2000 bp, which appeared in over 90% of the 91 Salmonella strains tested.

Figure IB shows the RAPD patterns as separated by gel electrophoresis for samples of 13 different species of a variety of Salmonella bacteria from the negative test panel which were amplified with a single primer, 12CN03. The lanes are correlated with the bacterial species as follows:

lane, speci s and i.^p. o. Lane Species and I.P. No.

1 Shigella sonnei 702 9 Escherichia coli 90

2 Shigella flexneri 1083 10 Escherichia blattae 846 (ATCC 29903) (ATCC 29907)

3 Shigella dysenteria 1082 11 Escherichia fregusonii 847 (ATCC 13313) (ATCC 35469)

4 Shigella boydii 1081 12 Escherichia hermani 848 (ATCC 8700) (ATCC 33650)

5 Citrobacter diver&us 97 13 Escherichia vulneris 850

(ATCC 33821)

6 Citrobacter freundii 383 (ATCC 8700)

Standard amplification conditions for the amplification of the negative test panel consisted of 0.2 mM dNTPs, 1 μM 12CN03 primer and a reaction buffer of 50 mM KCl, 10 mM tris @ pH 8.3, 1.5 mM MgCl₂, and 0.0003% gelatin. A total of 32 cycles were run under the following conditions: 1' at 94°C; 5' at 46°C; 2' ramp to 72°C and 2' at 72°C. The final cycle was followed by an additional 9' at 72°C. Molecular weight markers, gel composition, electrophoresis and staining conditions were as described above for the positive test panel.

As is evident by the data in figure IB, none of the negative test panel group showed the 800 bp or 2000 bp amplification products seen in the positive test panel. Extraction and Sequencing of the Sa lmonella diagnostic Fragmen :

The 800 bp product for Salmonella typhlmurium 587 (ATCC #29057) was selected for extraction and sequencing. The amplification product was isolated by electrophoresis in a low melting point agarose. The fragment was cut from the gel and extracted onto GlassMilk™ using a customized procedure from the

Geneclean kit sold by Bio 101 Inc. The fragment was then eluted and reamplified with the 12CN03 primer to provide quantities of DNA suitable for sequencing.

Since both ends of the fragment contain the same 12 base sequence, priming the parent diagnostic fragment with the 12CN03 primer would result in the production of two simultaneous sequences superimposed upon each other, which could not be resolved into the individual single- stranded sequences. Hence, it was necessary to carry out a restriction endonuclease digestion of the amplified 12CN03 product prior to running the sequencing reaction. Digest products were separated electrophoretically in low melting agarose and the appropriate restriction product was reisolated using the Geneclean procedure. The individual purified restriction digest products were then sequenced using 12CN03 as a sequencing primer. The restriction fragments were sequenced by the Sanger chain-termination method using fluorescence-labeled dideoxynucleotides and the Genesis 2000™ DNA Analysis System.

An example of the sequencing protocol used is as follows: Combine 1.5 μl - purified digest product (est. 100 ng) , 3.5 μl - 12CN03 @ 10.0 ng/μl and 28.5 μl - H₂0 and heat to 95°C for 2 minutes. Immediately place the mixture on wet ice. Add the following mixture 10 μl - 5X reverse transcriptase reaction buffer (300 mM tris @ pH 8.3, 375 mM NaCl, 37.5 mM MgCl2) , 6.5 μl - dNTP stock (180 uM ea.), 0.65 μl - ddNTP stock (250 μM 505nm-ddGTP, 800 μM 512nm-ddATP, 210 μM 519nm-ddCTP and 700 μM 526nm-ddTTP) and 1 μl - reverse transcriptase. Vortex, centrifuge and then incubate at 46°C for 15 minutes. Separate the sequencing products on a spin column and vacuum dry. Wash with 150 μl of cold 70% ethanol and centrifuge 5 min. Vacuum dry and reconstitute in 3 μl formamide. The labeled sequencing products were then analyzed by the Genesis 2000™ DNA Analysis System. Once differential sequence had been determined at both ends of the Salmonella target fragment the remaining sequence information was obtained through the use of either asymmetric PCR to generate single-stranded DNA or a modified double-stranded DNA sequencing protocol using double-stranded PCR product. The modification in the double-stranded protocol consisted of using a 46°C annealing temperature and a primer:template ratio of 25:1. This ratio is significantly higher than is generally practiced in sequencing reactions. At such a large primer:template ratio, priming at multiple sites is generally observed with single-stranded templates. However, when the template consists of short linear double-stranded DNA, successful priming can only occur at 5 ' blunt ends of the template and only with a primer whose sequence matches that end. The net result is that only a single discrete sequencing product is observed under these conditions . The sequence of the complete Salmonella fragment is shown in Figure 2. 29

EXAMPLE 2

DETERMINATION OF POLYMORPHIC POSITIVE TEST PANEL STRAINS The following procedure was used to determine which strains of Salmonella were most "polymorphic" with respect to the sequence of the diagnostic fragment shown in Figure 2. Two sets of amplification primer pairs were arbitrarily selected from the marker sequence. The sequence of these primers is shown in Table II.

TABLE II Primers used in the determination of polymorphic Salmonella #54-23 GAC GCT TAA TGC GGT TAA CGC CA (Sequence ID No. 10) #126-23 AAC CAT GCA TCA TCG GCA GAA CG (Sequence ID No. 11) #648rc-23 AGT AGC CTG CCG CTT ACG CTG AA (Sequence ID No. 12) #665rc-23 TCA GGA TGC AGG CGA TAG TAG CC (Sequence ID No. 13)

Primer nomenclature:

The first number indicates the 3' position of the primer on the Salmonella target sequence in Figure 2. The re indicates that the primer sequence is derived from the reverse complementary strand. The 23 indicates the length of the primer.

Amplifications were carried out on DNA isolated from 740 strains of Salmonella representing all six subgenus groups for each of the primer sets, 54-23/665rc-23 and 126-23/648rc/23. Standard amplification conditions consisted of 0.2 mM dNTPs,

0.5 μM each primer and a reaction buffer of 50 mM KCl, 10 mM tris 8 pH 8.3, 1.5 mM gCl2, and 0.0003% gelatin. A total of 35 cycles were run under the following conditions: 15 seconds at 94°C; 2 minutes at 69°C and 1 minute at 72°C. The final cycle was followed by an additional 7 minutes at 72°C. Gel composition, electrophoresis and staining conditions were as described above for the positive test panel in Example 1.

Strains of Salmonella were classified as a "polymorphic" if they produced amplification products that fell into the following categories : i) weak, inconsistent, or total lack of production of an amplification product; ii) amplification products which are larger or smaller than the generally observed amplification product; iii) the presence of more than one amplification product. Examples of these types of polymorphic amplification events are shown in Figure 3. Figure 3 shows the amplification product patterns as separated by gel electrophoresis for samples of 6 polymorphic and 6 normal Salmonella amplified with the primers of Table II. The lanes are correlated with the Salmonella strains as follows: ine Species and I.D. NO. Lane Species and I.P. No.

1 S. arizonae 1573 7 S. Subgenus Group II 1514

2 S. arizonae 1572 8 S. Subgenus Group V 1535

3 S. typhlmurium 708 9 S. Subgenus Group IV 1714 (ATCC 13311)

4 S. arizonae 726 10 5. Subgenus Group V 1773 (ATCC 12324)

5 S. oranienburg 2212 11 S. Subgenus Group I 1513

6 S. Subgenus Group I 2213 12 S. Subgenus Group I 1517

From the original group of 740 Salmonella strains a group of 43 polymorphic Salmonella were selected. EXAMPLE 3 EVALUATION OF PRIMING SITES WITHIN THE

DIAGNOSTIC FRAGMENT FOR THE BEST GENUS LEVEL TNCLϋSIVTTY OF SALMONELLA Example 3 illustrates the method used to identify which priming sites within the diagnostic Salmonella fragment showed the best inclusivity for Salmonella at the genus level.

Primers were prepared for a large number sites at both ends of the Salmonella target sequence.

Amplifications were carried out on genomic DNA from the 43 polymorphic Salmonella for a variety of these primer combinations according to the protocol listed below. In cases where a given primer combination produced an amplification product in over 90% of the polymorphic

Salmonella, additional primers were then prepared which moved one of the priming sites upstream or downstream one base at a time. Once the priming site that found the highest portion of polymorphic Salmonella was identified, that site was fixed and then additional' primers were prepared which moved the priming site at the other end of the Salmonella target sequence upstream or downstream one base at a time. The combination of priming sites which produced an amplification product for the highest percentage of polymorphic Salmonella would then be evaluated at the next stage of the screening procedure.

Primer-screening amplification reactions were conducted using the following procedure: Combine 1.5 μl - dNTP mix (5 mM each dNTP), 40 μl - deionized water, 5 μl - 10X reaction buffer (500 mM KCl, 100 mM tris @ pH 8.3, 15 mM MgCl₂, 0.003% gelatin) 0.4 μl - Taq polymerase (5U/μL) , 1.2 μl - Taq dilution buffer (10 mM tris @ pH 8.0 and 1.0% Tween 20), 0.66 μl - each primer (26-mer @ 10 μM) , and 1.0 μl - genomic DNA @ 50 ng/μl. Heat to 94°C for 2 minutes. Run 35 cycles of 15"(_ 94°C; 3' β 72°C. Combine a 5 μl aliquot of the reaction with 2 μl of Ficol-loading buffer and run on a 4% acrylamide gel (29:1) /l.OX TBE. Sample responses were graded as follows :

If a PCR product was visible at < 5 x 10⁴ DNA copies per reaction the result was scored as +1.

If a PCR product was only visible when the DNA copy number was > 5 x 10⁴ copies per reaction the test was scored as +0.5.

The scores for the 43 strains were summed and divided by 43. The results of the evaluation were assembled in Table III.

TABLE III

3'/3' 534 536 648 649 663 664 665 666 667 755 757 759 760 761 762 763 766 770 774

38 0.72 58 0.9 59 0.975 0.99 0.94 0.9 60 0.965 0.94 0.73 0.82 0.7 0.950.85 0.9 0.9 0.9 0.83 0.910.965 0.9 0.92 0.9 0.8 0.76 61 0.71 62 0.65 64 0.91 65 0.82 72 0.78 125 0.82 126 0.71 127 0.61 0.68 135 0.5

The numbers on the rows and columns represent the 3' positions relative to Sequence ID No. 1 of the two . primers used in the amplification reaction. Based on the results of the primer site evaluation, four 5 locations on the target sequence were sufficiently well conserved to yield priming sites capable of capturing over 95% of the polymorphic Salmonella . These sites were found in the following locations on the target sequence as displayed in Figure 2; 59-60, 534-536, 665 0 and 761. The 761 and 534 sites were selected over the 665 site because priming sites surrounding the 761 and 534 base positions detected a higher portion of the polymorphic Salmonella . Both the 59 and 60 sites were evaluated as possible priming sites for the 5 complementary strand of the target. The sequences for these primers are shown in Table IV.

TABLE TV Primer Sequences Found in at Least 95% of the Polymorphic Salmonella

#59-26 TTA GCC GGG ACG CTT AAT GCG GTT AA Sequence ID No. 14

#60-26 TAG CCG GGA CGC TTA ATG CGG TTA AC Sequence ID No. 15

#534rc-26 CTA TTT TCT GGC CTG ACG CTA TGA CC Sequence ID No. 16

#536rc-26 TTC TAT TTT CTG GCC TGA CGC TAT GA Sequence ID No. 17

#665rc-26 CAT TCA GGA TGC AGG CGA TAG TAG CC Sequence ID No. 18

#761rc-26 CTT TAC CGC TTC CAG TGT GGC CTG AA Sequence ID No. 19

Primer nomenclature:

The first number indicates the 3' position of the primer on the Salmonella target sequence in Figure 2. 0 The re indicates that the primer sequence is derived from the reverse complementary strand. The 26 indicates the length of the primer. EXAMPLE 4

EVALUATION OF LARGER POPULATIONS OF NEGATIVE AND POSITIVE TEST PANELS

Since the presence of bacteria in the genus Salmonella will be determined based on the production of an amplification product generated from the primers now being screened, it is necessary to conduct a broader sampling of strains representing the negative and positive test panels. The selectivity of the Salmonella primer sets was evaluated by testing representatives of the following species representing the negative test panel to determine whether they contained DNA sequences which were amplifiable with either the 60-26/761rc-26 primer set or any combination of primers 59-26 or 60-26 with

534rc-26 or 536rc-26; Escherichia coli, Shigella sonnei, Shigella dysenteria, Shigella flexneri, Shigella boydii, Enterobacter cloacae, Enterobacter agglomeran, Enterobacter aerogenes, Citrobacter freundii, Citrobacter diversus, Hafnia alvei, Proteus mirabilis, Proteus morganii, Proteus vulgaris, Klebsiella pneumoniae, Serratia marcescens, Yersinia enterocolitica, Listeria onocytogenes, Listeria innocua, Listeria ivanovii, Staphylococcus aureus, Staphylococcus warneri, Staphylococcus saprophyticus, Staphylococcus epidermidus, Enterococcus faecalis, Bacillus cereus, Bacillus thuringiensis, Bacillus subtilis.

A representative composite showing PCR amplification products for the non-Salmonella strains listed below is shown in Figure 4. Figure 4 shows the amplification products formed using the 60-26/761rc-26 primer set as separated by gel electrophoresis for samples of 44 non-Salmonella. Four strains of Salmonella were also included in the reaction set as a 36

positive control to indicate that conditions were sufficient for amplification of the Salmonella target sequence to take place. The lanes are correlated with the non-Salmonella and Salmonella strains as follows :

A.

Lane Species and T.D. No. Lane Species and I.P. No.

1 Escherichia coli 25 7 Enterobacter cloacae 123

2 Escherichia coli 33 8 Enterobacter cloacae 221

3 Escherichia coli 57 9 Enterobacter cloacae 313

4 Escherichia coli 84 10 Enterobacter cloacae 375 (ATCC 13047)

5 Escherichia coli 139 11 Proteus mirabilis 360

6 Salmonella typhimurium 897 12 Proteus mirabilis 364

Lane Species and T.P. No Lane Species and I.P. No.

1 Proteus morganii 99 7 Proteus vulgaris 959

2 Proteus morganii 363 8 Eπterojacter agglomerans 905

3 Salmonella enteritidis 1109 9 ■Enterobacter aerogenes 62

4 Proteus vulgaris 273 10 Enterobacter aerogenes 376 (ATCC 13048)

5 Proteus vulgaris 275 11 Klebsiella pneumoniae 373 (ATCC 13883)

6 Proteus vulgaris 385 12 Klebsiella pneumoniae 749 (ATCC 13315)

£

Lane Species and I. . No Lane Species and I.P. No.

1 Listeria monocytogenes 938 7 Citrobacter freundii 896

2 Listeria monocytogenes 941 8 Citrobacter diversus 217

3 Listeria innocua 1157 9 Hafnia alvei 934

4 Listeria ivanovii 1167 10 Serratia marcesens 372

5 Salmonella infantis 908 11 Eιterococcus faecalis 283 (ATCC 19433)

Citrobacter freundii 361 12 Yersinia enterocolitica 750 Q.

Lane species and i.p. No. Lane Species and I.P. No.

1 Staphylococcus aureus 118 7 Staphylococcus saprophyticus 78£

2 Staphylococcus aureus 207 8 Salmonella saintpaul 1086

3 Staphylococcus aureus 610 9 Shigella sonnei 701

4 Staphylococcus aureus 812 10 Shigella boydii 1081

(ATCC 8700)

5 Staphylococcus warneri 793 11 Shigella dysenteria 1082

(ATCC 13313)

6 Staphylococcus saprophyticus 762 12 Shigella flexneri 1083

(ATCC 29903)

Of the 100 strains which were evaluated only one strain which was tentatively identified as Hafnia alvei, gave a false positive result with the 60-26 and 761rc-26 primer set. The identity of this false positive is 5 considered ambiguous because although its ribotyping pattern appears to be closer to Hafnia alvei than to the genus Salmonella, the strain appears to be biochemically closer to Salmonella . The remaining 35 strains of Hafnia alvei, which were screened all tested negative

10 for the presence of the Salmonella test sequence.

Primer combinations using 3' sites at base positions 59 or 60 along with complementary strand priming sites'at 534 or 536 all generated amplification products with at least 20% of the negative test panel. Since this rate

15 of false positives was unacceptable for use in the preferred embodiments only the 60-26 and 761rc-26 primer set was selected for the further evaluation. The fragment of Figure 2 flanked and included by these primers included nucleic acid bases starting at position

20 35 and ending at position 786; this is the diagnostic target of the invention for Salmonella . Position 35 to 786 of Sequence ID No. 1 is designated Sequence ID No. 21. Position 35 to 786 of Sequence ID No. 20 is designated as Sequence ID No. 22. The detection efficiency of the diagnostic marker primers 60-26 and 761rc-26 primers was then evaluated on a test group of over 1480 Salmonella strains. A breakdown of the test group by subgenus group and serotype is shown in Table V.

T ELE-V. List of Salmonella Serotyoes Comprising the Test Group for the 60-26 and 761rc-26 Primers

Serotype/Subσenus No. Serotype/Subgenus No.

Salmonella abaetetuba F 3 Salmonella london El 2

Salmonella adabraka El 1 Salmonella madelia H 2

Salmonella adelaide 0 11 Salmonella manchester C2 3

Salmonella agama B 2 Salmonella manhatten C2 5

Salmonella agona 0 25 Salmonella manila E2 2

Salmonella ajiobo G2 2 Salmonella mbandaka Cl 14

Salmonella alabama Dl 2 Salmonella meleagridis El 3

Salmonella albany C3 5 Salmonella rαinnesota L 5

Salmonella altendorf B 2 Salmonella mis3issippi G2 4

Salmonella amsterdam El 7 Salmonella montevideo Cl 9

Salmonella anatum El 42 Salmonella morehead N 2

Salmonella arechavaleta B 2 Salmonella muenchen C2 11

Salmonella arkansas E3 11 Salmonella muenster El 10

Salmonella austin Cl 2 Salmonella napoli Dl 7

Salmonella bareilly Cl 8 Salmonella newbrunswick E2 5

Salmonella berta Dl 13 Salmonella newington E2 1

Salmonella binza E2 19 Salmonella newport C2 26

Salmonella blockley C2 4 Salmonella nyborg El 2

Salmonella bodjonegoro N 2 Salmonella ohio Cl 53

Salmonella braenderup Cl 30 Salmonella oranienburg Cl 8

Salmonella brandenburg B 9 Salmonella othmarschen Cl 5

Salmonella bredeney B 14 Salmonella panama Dl 8

Salmonella California B 7 Salmonella paratyphi A 1

Salmonella cerro K 13 Salmonella poona Gl 2

Salmonella champaign Q 2 Salmonella pullorum Dl 21

Salmonella chandans F 5 Salmonella reading B 8 Salmonella choleraesuis Cl 13 Salmonella redlands I 2

Salmonella corvallia C3 6 Salmonella rostock Dl 2

Salmonella cubana G2 21 Salmonella rubislaw F 5

Salmonella daressalaam B 1 Salmonella saintpaul B 10

Salmonella derby B 8 Salmonella sandiego B 7

Salmonella drypool E2 11 Salmonella Santiago C3 48

Salmonella dublin Dl 14 Salmonella sch arzengr. B 10

Salmonella durham G2 5 Salmonella sculcoates 2

Salmonella ealing 0 3 Salmonella senftenberg E4 56

Salmonella enteritidis Dl 124 Salmonella sladun B 2

Salmonella esch eiler Cl 2 Salmonella Stanley B 7

Salmonella ferlac H 2 Salmonella Stanleyville B 3

Salmonella gallinarum 0 3 Salmonella sya X 4

Salmonella give El 4 Salmonella tennessee Cl 19

Salmonella haardt 0 12 Salmonella thomasville E3 11

Salmonella hadar C2 17 Salmonella thompson Cl 16

Salmonella havana G2 15 Salmonella typhi Dl 2

Salmonella heidelberg B 20 Salmonella typhimurium B 97

Salmonella indiana B 13 Salmonella urbana N 2

Salmonella infantis Cl 31 Salmonella virchow Cl 14

Salmonella Johannesburg R 5 Salmonella waycross S 2

Salmonella kedougou G2 7 Salmonella worthington G2 11

Salmonella kentucky C3 11 Salmonella Group I species 211

Salmonella kiambu B 2 Salmonella Group II species 23

Salmonella krefeld E4 2 Salmonella Group Ilia species 39

Salmonella kubacha B 4 Salmonella Group Illb species 19

Salmonella lexington El 7 Salmonella Group IV species 16

Salmonella lille Cl 8 Salmonella Group V species 2

Salmonella livingston Cl 9

This pair of priming sites proved to be extremely accurate in detecting Salmonella strains from all six subgenus groups in the genus Salmonella . The 1390 strains of Group I Salmonella were detected at an efficiency of 99.75%. Although the remaining five subgenus groups contained considerably fewer strains, the strains comprising all these groups were detected at 100% efficiency. The detection efficiency of the 60 and 761 priming sites for the individual subgenus groups and the entire Salmonella test group are shown in Table VI.

TABLE VI

Summary of Salmonella Detecting Efficiency for the 60-26 and 761rc-26 Primer Set

Total Subgenus Group I Tested 1390

Total Positive 1386.5

% Positive 99.75

Total Subgenus Group II Tested 23

Total Positive 23

% Positive 100

Total Subgenus Group Ilia Tested 39

Total Positive 39

% Positive 100

Total Subgenus Group Illb Tested 19

Total Positive 19

% Positive 100

Total Subgenus Group IV Tested 16

Total Positive 16

% Positive 100

Total Subgenus Group V Tested 2

Total Positive 2

% Positive 100

Total Salmonella Tested 1489

Total Salmonella Positive 1485.5

% Positive 99.76 If a PCR product was visible at < 5 x 10⁴ DNA copies per reaction the result was scored as +1 .

If a PCR product was only visible when the DNA copy number was > 5 x 10⁴ copies per reaction the test was scored as +0.5.

A representative composite showing PCR amplification products for the Salmonella strains listed below is shown in Figure 5.

Figure 5 shows the amplification products formed using the 60-26/761rc-26 primer set as separated by gel electrophoresis for samples of 44 Salmonella . The lanes are correlated with Salmonella strains as follows :

Lane Species and I.D. No. Lane Species and I .D . No .

1 Salmonella abaetetuba 1550 7 Salmonella anatum 1501

2 Salmonella adabraka 2340 8 Salmonella anatum 2744

3 Salmonella agona 1353 9 Blank

4 Salmonella agona 1446 10 Salmonella binza 1432

5 Salmonella agona 2339 11 Salmonella binza 2682

6 Salmonella altendorf 1654 12 Salmonella brandenburg 1355 fi.

Lane Species and I.D. No. T.ane Species and T .D . No .

1 Salmonella enteritidis 706 7 Salmonella hadar 1231 (ATCC 6962)

2 Salmonella enteritidis 890 8 Salmonella havana 2245

3 Salmonella eschweiler 1647 9 Salmonella havana 2271

4 Salmonella gallinarum 1635 10 Blank

5 Salmonella gallinarum 2350 11 Salmonella heidelberg 1238

6 Salmonella haardt 1344 12 Salmonella heidelberg 1239

£

Lane Species and I.P. No. Lane Species and I.P. No.

1 Salmonella indiana 1480 7 Salmonella kentucky 2195

2 Salmonella infantis 727 8 Salmonella kentucky 2756

3 Blank 9 Salmonella kentucky 2759 4 Salmonella infantis 1437 10 Salmonella kentucky 2769

5 Salmonella kedougou 1251 11 Salmonella kiambu 919

6 Salmonella kedougou 1254 12 Salmonella lexington 1649

Lane, species and i.^p. No. Lane Species and I.P. No.

1 Salmonella typhimurium 1253 7 Salmonella virchow 1256

2 Salmonella typhimurium 1499 8 Salmonella virchow 1370

3 Salmonella typhimurium 1509 9 Salmonella virchow 1431

4 Salmonella urbana 1663 10 Blank

5 Salmonella virchow 738 11 Salmonella worthington 2638

6 Salmonella virchow 1241 12 Salmonella vrindaban 2314

SEQUENCE LISTING

(1) GENERAL INFORMATION:

(i) APPLICANT:

(A) NAME: E. I. DU PONT DE NEMOURS AND

COMPANY

(B) STREET: 1007 MARKET STREET

(C) CITY: WILMINGTON

(D) STATE: DELAWARE

(E) COUNTRY: UNITED STATES OF AMERICA

(F) POSTAL CODE (ZIP) : 19898

(G) TELEPHONE: 302-892-8112 (H) TELEFAX: 302-773-0164 (I) TELEX: 6717325

(ϋ) TITLE OF INVENTION: SELECTION OF DIAGNOSTIC GENETIC MARKERS IN MICROORGANISMS AND USE OF A SPECIFIC MARKER FOR DETECTION OF SALMONELLA

(iii) NUMBER OF SEQUENCES: 22

(iv) COMPUTER READABLE FORM:

(A) MEDIUM TYPE: DISKETTE, 3.50 INCH

(B) COMPUTER: MACINTOSH

(C) OPERATING SYSTEM: MACINTOSH, 6.0

(D) SOFTWARE: MICROSOFT WORD, 4.0

(v) CURRENT APPLICATION DATA:

(A) APPLICATION NUMBER:

(B) FILING DATE:

(C) CLASSIFICATION:

(vii) ATTORNEY/AGENT INFORMATION:

(A) NAME: GEIGER, KATHLEEN W.

(B) REGISTRATION NUMBER: 35,880

(C) REFERENCE/DOCKET NUMBER: MD-1068

(2) INFORMATION FOR SEQ ID NO:l:

(i) SEQUENCE CHARACTERISTICS:

(A) LENGTH: 811 base pairs

(B) TYPE: nucleic acid

(C) STRANDEDNESS: double

(D) TOPOLOGY: linear

(ii) MOLECULE TYPE: DNA (genomic) (iii) HYPOTHETICAL: NO

(xi) SEQUENCE DESCRIPTION: SEQ ID NO:l:

TTAGTCACGG CAGCCGCGAG GATGATATGG ATGTTAGCCG GGACGCTTAA TGCGGTTAAC 60

GCCATGCCGA CACCAGCGCC CGCCAGCGTG CCGAAACTGT AGAAACCATG CATCATCGGC 120

AGAACGGTTT TATTCAGCTC GCGTTCGACC GCCGCGCCTT CGACATTAAT CGCCACTTCG 180

GCGGCGCCAA AACTGGCGCC GAAAACGGCT AATCCAAGGG CAAAAATCAG CGGCGAGGCG 240

CACCACAGCG CGACGCTAAG AATAACCATC CCGGTTACTG CACAGGTCAT CGTCGTGCGA 300

ATAACCTTCC GGGTGCCAAA TCGTTTCACC AGCCAGGCGG AACAAAGAAT ACCGCTCATT 360

GAACCGATAG AAAGCCCGAA TAAGACCGCC CCCATTTCCG CGGTAGAGAC GGAAAGAATA 420

TCCCGAATAG CAGGCGTTCG GGTTGCCCAG GAGGCCATCA GCAGTCCGGG TAAAAAGAAG 480

AACATAAACA GCGCCCAGGT ACGGCGTTTT AAGGCGTTAC GTGAGGAGAG GACGGTCATA 540

GCGTCAGGCC AGAAAATAGA AGCGAGAGGT AAACATTAGC AAGCTTGTGT ACATTTGTAC 600

ATATCATCGT CATACTTCAT TGTGCAGACA GTTTTTACTG TCTGTTTTTT CAGCGTAAGC 660

GGCAGGCTAC TATCGCCTGC ATCCTGAATG AGATGTGGAA CTCATCATGA AAGAAAATGC 720

CGTAAGCGCG CCAATGATCC TAAGCGACGG GAAAAAATAA TTCAGGCCAC ACTGGAAGCG 780

GTAAAGACCT ATGGCACTCT GCCGTGACTA A 811 (2) INFORMATION FOR SEQ ID NO:2:

(i) SEQUENCE CHARACTERISTICS:

(A) LENGTH: 12 base pairs

(B) TYPE: nucleic acid

(C) STRANDEDNESS: single

(D) TOPOLOGY: linear

(ii) MOLECULE TYPE: DNA (genomic) (xi) SEQUENCE DESCRIPTION: SEQ ID NO:2: AGCTGATGCT AC 12 (2) INFORMATION FOR SEQ ID NO:3:

(i) SEQUENCE CHARACTERISTICS:

(A) LENGTH: 12 base pairs

(B) TYPE: nucleic acid

(C) STRANDEDNESS: single

(D) TOPOLOGY: linear

(ii) MOLECULE TYPE: DNA (genomic) (xi) SEQUENCE DESCRIPTION: SEQ ID NO:3: AGTCGAACTG TC 12

(2) INFORMATION FOR SEQ ID NO:4:

(i) SEQUENCE CHARACTERISTICS:

(A) LENGTH: 12 base pairs

(B) TYPE: nucleic acid

(C) STRANDEDNESS: single

(D) TOPOLOGY: linear

(ii) MOLECULE TYPE: DNA (genomic)

(xi) SEQUENCE DESCRIPTION: SEQ ID NO:4:

TTAGTCACGG CA 12

(2) INFORMATION FOR SEQ ID NO:5:

(i) SEQUENCE CHARACTERISTICS:

(A) LENGTH: 12 base pairs

(B) TYPE: nucleic acid

(C) STRANDEDNESS: single

(D) TOPOLOGY: linear

(ii) MOLECULE TYPE: DNA (genomic)

(xi) SEQUENCE DESCRIPTION: SEQ ID NO:5:

TGCGATACCG TA 12

(2) INFORMATION FOR SEQ ID NO: 6:

(i) SEQUENCE CHARACTERISTICS:

(A) LENGTH: 12 base pairs

(B) TYPE: nucleic acid

(C) STRANDEDNESS: single

(D) TOPOLOGY: linear

(ii) MOLECULE TYPE: DNA (genomic) (xi) SEQUENCE DESCRIPTION: SEQ ID NO: 6: CTACAGCTGA TG 12

(2) INFORMATION FOR SEQ ID NO:7:

(i) SEQUENCE CHARACTERISTICS:

(A) LENGTH: 12 base pairs

(B) TYPE: nucleic acid

(C) STRANDEDNESS: single

(D) TOPOLOGY: linear

(ii) MOLECULE TYPE: DNA (genomic)

(xi) SEQUENCE DESCRIPTION: SEQ ID NO:7:

GTCAGTCGAA CT • 12

(2) INFORMATION FOR SEQ ID NO:8:

(i) SEQUENCE CHARACTERISTICS:

(A) LENGTH: 12 base pairs

(B) TYPE: nucleic acid

(C) STRANDEDNESS: single

(D) TOPOLOGY: linear

(ii) MOLECULE TYPE: DNA (genomic)

(xi) SEQUENCE DESCRIPTION: SEQ ID NO:8:

GGCATTAGTC AC 12

(2) INFORMATION FOR SEQ ID NO: 9:

(i) SEQUENCE CHARACTERISTICS:

(A) LENGTH: 12 base pairs

(B) TYPE: nucleic acid

(C) STRANDEDNESS: single

(D) TOPOLOGY: linear

(ii) MOLECULE TYPE: DNA (genomic)

(xi) SEQUENCE DESCRIPTION: SEQ ID NO: 9:

CGTATGCGAT AC 12

(2) INFORMATION FOR SEQ ID NO:10:

(i) SEQUENCE CHARACTERISTICS:

(A) LENGTH: 23 base pairs

(B) TYPE: nucleic acid

(C) STRANDEDNESS: single

(D) TOPOLOGY: linear (ii) MOLECULE TYPE: DNA (genomic)

(xi) SEQUENCE DESCRIPTION: SEQ ID NO:10:

GACGCTTAAT GCGGTTAACG CCA 23

(2) INFORMATION FOR SEQ ID NO: 11:

(i) SEQUENCE CHARACTERISTICS:

(A) LENGTH: 23 base pairs

(B) TYPE: nucleic acid

(C) STRANDEDNESS: single

(D) TOPOLOGY: linear

(ii) MOLECULE TYPE: DNA (genomic)

(xi) SEQUENCE DESCRIPTION: SEQ ID NO:11:

AACCATGCAT CATCGGCAGA ACG 23

(2) INFORMATION FOR SEQ ID NO:12:

(i) SEQUENCE CHARACTERISTICS:

(A) LENGTH: 23 base pairs

(B) TYPE: nucleic acid

(C) STRANDEDNESS: single

(D) TOPOLOGY: linear

(ii) MOLECULE TYPE: DNA (genomic)

(xi) SEQUENCE DESCRIPTION: SEQ ID NO: 12:

AGTAGCCTGC CGCTTACGCT GAA 23

(2) INFORMATION FOR SEQ ID NO:13:

(i) SEQUENCE CHARACTERISTICS:

(A) LENGTH: 23 base pairs

(B) TYPE: nucleic acid

(C) STRANDEDNESS: single

(D) TOPOLOGY: linear

(ii) MOLECULE TYPE: DNA (genomic)

(xi) SEQUENCE DESCRIPTION: SEQ ID NO:13:

TCAGGATGCA GGCGATAGTA GCC 23

(2) INFORMATION FOR SEQ ID NO:14:

(i) SEQUENCE CHARACTERISTICS:

(A) LENGTH: 26 base pairs (B) TYPE: nucleic acid

(C) STRANDEDNESS: single

(D) TOPOLOGY: linear

(ii) MOLECULE TYPE: DNA (genomic) (xi) SEQUENCE DESCRIPTION: SEQ ID NO:14: TTAGCCGGGA CGCTTAATGC GGTTAA 26

(2) INFORMATION FOR SEQ ID NO:15:

(i) SEQUENCE CHARACTERISTICS:

(A) LENGTH: 26 base pairs

(B) TYPE: nucleic acid

(C) STRANDEDNESS: single

(D) TOPOLOGY: linear

(ii) MOLECULE TYPE: DNA (genomic)

(xi) SEQUENCE DESCRIPTION: SEQ ID NO:15:

TAGCCGGGAC GCTTAATGCG GTTAAC 26

(2) INFORMATION FOR SEQ ID NO:16:

(i) SEQUENCE CHARACTERISTICS:

(A) LENGTH: 26 base pairs

(B) TYPE: nucleic acid

(C) STRANDEDNESS: single

(D) TOPOLOGY: linear

(ii) MOLECULE TYPE: DNA (genomic)

(xi) SEQUENCE DESCRIPTION: SEQ ID NO: 16:

CTATTTTCTG GCCTGACGCT ATGACC 26

(2) INFORMATION FOR SEQ ID NO:17:

(i) SEQUENCE CHARACTERISTICS:

(A) LENGTH: 26 base pairs

(B) TYPE: nucleic acid

(C) STRANDEDNESS: single

(D) TOPOLOGY: linear

(ii) MOLECULE TYPE: DNA (genomic) (xi) SEQUENCE DESCRIPTION: SEQ ID NO:17: TTCTATTTTC TGGCCTGACG CTATGA 26 (2) INFORMATION FOR SEQ ID NO:18:

(i) SEQUENCE CHARACTERISTICS:

(A) LENGTH: 26 base pairs

(B) TYPE: nucleic acid

(C) STRANDEDNESS: single

(D) TOPOLOGY: linear

(ii) MOLECULE TYPE: DNA (genomic)

(xi) SEQUENCE DESCRIPTION: SEQ ID NO:18:

CATTCAGGAT GCAGGCGATA GTAGCC 26

(2) INFORMATION FOR SEQ ID NO:19:

(i) SEQUENCE CHARACTERISTICS:

(A) LENGTH: 26 base pairs

(B) TYPE: nucleic acid

(C) STRANDEDNESS: single

(D) TOPOLOGY: linear

(ii) MOLECULE TYPE: DNA (genomic) (xi) SEQUENCE DESCRIPTION: SEQ ID NO:19: CTTTACCGCT TCCAGTGTGG CCTGAA 26

(2) INFORMATION FOR SEQ ID NO:20:

(i) SEQUENCE CHARACTERISTICS:

(A) LENGTH: 811 base pairs

(B) TYPE: nucleic acid

(C) STRANDEDNESS: single

(D) TOPOLOGY: linear

(ii) MOLECULE TYPE: DNA (genomic) (xi) SEQUENCE DESCRIPTION: SEQ ID NO:20:

TTAGTCACGG CAGAGTGCCA TAGGTCTTTA CCGCTTCCAG TGTGGCCTGA ATTATTTTTT 60

CCCGTCGCTT AGGATCATTG GCGCGCTTAC GGCATTTTCT TTCATGATGA GTTCCACATC 120

TCATTCAGGA TGCAGGCGAT AGTAGCCTGC CGCTTACGCT GAAAAAACAG ACAGTAAAAA 180

CTGTCTGCAC AATGAAGTAT GACGATGATA TGTACAAATG TACACAAGCT TGCTAATGTT 240

TACCTCTCGC TTCTATTTTC TGGCCTGACG CTATGACCGT CCTCTCCTCA CGTAACGCCT 300

TAAAACGCCG TACCTGGGCG CTGTTTATGT TCTTCTTTTT ACCCGGACTG CTGATGGCCT 360

CCTGGGCAAC CCGAACGCCT GCTATTCGGG ATATTCTTTC CGTCTCTACC GCGGAAATGG 420 GGGCGGTCTT ATTCGGGCTT TCTATCGGTT CAATGAGCGG TATTCTTTGT TCCGCCTGGC 480

TGGTGAAACG ATTTGGCACC CGGAAGGTTA TTCGCACGAC GATGACCTGT GCAGTAACCG 540

GGATGGTTAT TCTTAGCGTC GCGCTGTGGT GCGCCTCGCC GCTGATTTTT GCCCTTGGAT 600

TAGCCGTTTT CGGCGCCAGT TTTGGCGCCG CCGAAGTGGC GATTAATGTC GAAGGCGCGG 660

CGGTCGAACG CGAGCTGAAT AAAACCGTTC TGCCGATGAT GCATGGTTTC TACAGTTTCG 720

GCACGCTGGC GGGCGCTGGT GTCGGCATGG CGTTAACCGC ATTAAGCGTC CCGGCTAACA 780

TCCATATCAT CCTCGCGGCT GCCGTGACTA A 811 (2) INFORMATION FOR SEQ ID NO:21:

(i) SEQUENCE CHARACTERISTICS:

(A) LENGTH: 752 base pairs

(B) TYPE: nucleic acid

(C) STRANDEDNESS: single

(D) TOPOLOGY: linear

(ii) MOLECULE TYPE: DNA (genomic) (xi) SEQUENCE DESCRIPTION: SEQ ID NO:21:

TAGCCGGGAC GCTTAATGCG GTTAACGCCA TGCCGACACC AGCGCCCGCC AGCGTGCCGA 60

AACTGTAGAA ACCATGCATC ATCGGCAGAA CGGTTTTATT CAGCTCGCGT TCGACCGCCG 120

CGCCTTCGAC ATTAATCGCC ACTTCGGCGG CGCCAAAACT GGCGCCGAAA ACGGCTAATC 180

CAAGGGCAAA AATCAGCGGC GAGGCGCACC ACAGCGCGAC GCTAAGAATA ACCATCCCGG 240

TTACTGCACA GGTCATCGTC GTGCGAATAA CCTTCCGGGT GCCAAATCGT TTCACCAGCC 300

AGGCGGAACA AAGAATACCG CTCATTGAAC CGATAGAAAG CCCGAATAAG ACCGCCCCCA 360

TTTCCGCGGT AGAGACGGAA AGAATATCCC GAATAGCAGG CGTTCGGGTT GCCCAGGAGG 420

CCATCAGCAG TCCGGGTAAA AAGAAGAACA TAAACAGCGC CCAGGTACGG CGTTTTAAGG 480

CGTTACGTGA GGAGAGGACG GTCATAGCGT CAGGCCAGAA AATAGAAGCG AGAGGTAAAC 540

^' ATTAGCAAGC TTGTGTACAT TTGTACATAT CATCGTCATA CTTCATTGTG CAGACAGTTT 600

TTACTGTCTG TTTTTTCAGC GTAAGCGGCA GGCTACTATC GCCTGCATCC TGAATGAGAT 660

GTGGAACTCA TCATGAAAGA AAATGCCGTA AGCGCGCCAA TGATCCTAAG CGACGGGAAA 720

AAATAATTCA GGCCACACTG GAAGCGGTAA AG 752 (2) INFORMATION FOR SEQ ID NO:22:

(i) SEQUENCE CHARACTERISTICS:

(A) LENGTH: 752 base pairs (B) TYPE: nucleic acid

(C) STRANDEDNESS: single

(D) TOPOLOGY: linear

(ii) MOLECULE TYPE: DNA (genomic) (xi) SEQUENCE DESCRIPTION: SEQ ID NO:22:

CTTTACCGCT TCCAGTGTGG CCTGAATTAT TTTTTCCCGT CGCTTAGGAT CATTGGCGCG 60

CTTACGGCAT TTTCTTTCAT GATGAGTTCC ACATCTCATT CAGGATGCAG GCGATAGTAG 120

CCTGCCGCTT ACGCTGAAAA AACAGACAGT AAAAACTGTC TGCACAATGA AGTATGACGA 180

TGATATGTAC AAATGTACAC AAGCTTGCTA ATGTTTACCT CTCGCTTCTA TTTTCTGGCC 240

TGACGCTATG ACCGTCCTCT CCTCACGTAA CGCCTTAAAA CGCCGTACCT GGGCGCTGTT 300

TATGTTCTTC TTTTTACCCG GACTGCTGAT GGCCTCCTGG GCAACCCGAA CGCCTGCTAT 360

TCGGGATATT CTTTCCGTCT CTACCGCGGA AATGGGGGCG GTCTTATTCG GGCTTTCTAT 420

CGGTTCAATG AGCGGTATTC TTTGTTCCGC CTGGCTGGTG AAACGATTTG GCACCCGGAA 480

GGTTATTCGC ACGACGATGA CCTGTGCAGT AACCGGGATG GTTATTCTTA GCGTCGCGCT 540

GTGGTGCGCC TCGCCGCTGA TTTTTGCCCT TGGATTAGCC GTTTTCGGCG CCAGTTTTGG 600

CGCCGCCGAA GTGGCGATTA ATGTCGAAGG CGCGGCGGTC GAACGCGAGC TGAATAAAAC 660

CGTTCTGCCG ATGATGCATG GTTTCTACAG TTTCGGCACG CTGGCGGGCG CTGGTGTCGG 720

CATGGCGTTA ACCGCATTAA GCGTCCCGGC TA 752

Claims

WHAT IS CLAIMED IS:

1. A method of determining whether an unknown bacterium is a member of the genus Salmonella, comprising analyzing the genomic DNA of said unknown bacterium to detect the presence of nucleic acid Sequence ID No. 1 or Sequence ID No. 20.

2. The method of Claim 1 wherein said analysis comprises the steps of:

(i) performing a PCR amplification reaction on the genomic DNA of said unknown bacterium using a pair of primers comprising a first primer and a second primer wherein said first primer has a nucleic acid sequence derived from Sequence ID No. 1 and said second primer has a nucleic acid sequence derived from Sequence ID No. 20; and (ii) detecting the presence of DNA which has been amplified by said primer pair of step (i); whereby the presence of amplified DNA at step (ii) indicates that said unknown bacterium is a member of the genus Salmonella .

3. The method of Claim 2 wherein at step (i) said first primer is selected from the group consisting of

Sequence ID Nos. 14 and 15, and said second primer is selected from the group consisitng of Sequence ID Nos. 16, 17, 18, and 19.

4. The method of Claim 2 wherein at step (i) said first primer is Sequence ID No. 15 and said second primer is Sequence ID No. 19.

5. The method of Claim 1 wherein said analysis comprises contacting the genomic DNA of said unknown organism with a nucleic acid probe wherein said probe consists essentially of a nucleic acid sequence which is complimentary to Sequence ID Nos. 1 or 20, or a fragment thereof, and further, detecting the presence of said hybridized probe.

6. An isolated nucleic acid fragment having Sequence ID No. 1 or a fragment thereof.

7. An isolated nucleic acid fragment having Sequence ID No. 20 or a fragment thereof.

8. An isolated nucleic acid fragment having Sequence ID No. 14. 9. An isolated nucleic acid fragment having

Sequence ID No. 15.

10. An isolated nucleic acid fragment having Sequence ID No. 16.

11. An isolated nucleic acid fragment having Sequence ID No. 17.

12. An isolated nucleic acid fragment having Sequence ID No. 18.

13. An isolated nucleic acid fragment having Sequence ID No. 19. 1 . An isolated nucleic acid fragment having Sequence ID No. 21.

15. An isolated nucleic acid fragment having Sequence ID No. 22.

16. An isolated nucleic acid fragment having Sequence ID No. 4.