GENETIC MARKERS FOR DIAGNOSIS OF TUBERCULOSIS CAUSED BY MYCOBACTERIUM TUBERCULOSIS

Abstract

The application is related to novel signature sequences for diagnosis of Mycobacterium tuberculosis in clinical samples with 100% specificity and a very high degree of sensitivity.

Description

RELATED APPLICATION

This application is related to and takes priority from the Indian Provisional Application 5572/CHE/2013 filed on Dec. 3, 2013 and is incorporated herein in its entirety.

FIELD OF THE INVENTION

The application is related to novel signature sequences for diagnosis of Mycobacterium tuberculosis in clinical samples. These signature sequences have the ability to differentiate Mycobacterium tuberculosis DNA from other mycobacterial species by PCR with 100% specificity and very high sensitivity.

BACKGROUND OF THE INVENTION

Tuberculosis (TB) is a major global health problem with an alarming rate of mortality associated with it. It is one of the leading infectious diseases caused by bacteria taking one human life every 15-20 seconds globally. Estimates of 2011 reveal that there are almost 9 million new cases and 1.4 million TB deaths (Global Tuberculosis Report 2012, WHO 2013). The disease is caused by Mycobacterium tuberculosis, a member of the genus Mycobacterium, while in a few cases Mycobacterium bovis has been reported to be the causal organism. More than 100 mycobacterium species are known and among them only a few are pathogenic for humans.

Conventional diagnostic methods include examination of sputum smear under a microscope for acid-fast mycobacteria and radiological reading of lungs. However, in most cases the sputum smear examination turns out to be negative for the bacteria due to early stages of infection and lung changes are not readily visible on an x-rays until several months into the infection.

Diagnosis of mycobacteria-related disease poses difficulties for several reasons which have been recognized by researchers and clinicians over the years. Firstly, these bacteria are in small numbers and are already at a contagious stage when they become detectable by conventional methods. Pulmonary disease caused by different mycobacteria are not readily detectable clinically or radiologically. Detection of organism in culture achieves 100% specificity but the growth of mycobacteria in culture takes about 3-6 weeks (Bates et al, Am. Respir. 134, 415-417, 1986) thus making the process time-consuming. In addition, repeated cultures may be required to ensure success.

Several molecular tests for tuberculosis have been developed in the past. These include the Gen-probe ‘Amplified mycobacterium direct test’ by Abbe et al (J. Clin. Mincrobiol. 31, 3270, 1993), ligase chain reaction (LCR) (J. Clin. Microbiol. 35, 2424, 1997), PCR based Roche Amplicor TB test (J. Clin. Microbiol. 33, 1832, 1995) and IS6110 based detection (J. Clin. Microbiol. 28, 2668, 1990).

U.S. Pat. No. 5,168,039 discloses the IS6110 based detection of M. tuberculosis wherein a repetitive DNA segment specific for members of M. tuberculosis complex is used for the diagnosis. While IS6110 based detection system has been shown to have high level of specificity, there are also reports on false positive detections of 3 to 20% making it unreliable (J. Clin. Microbiol. 32, 277, 1994). In addition, lack of IS6110 sequence in some M. tuberculosis strains may also limit the use of the same for diagnostic tests routinely (Tuber. Lung Dis. 76, 550, 1995). U.S. Pat. No. 7,638,309 provides detection of mycobacteria in clinical specimens in the intergenic region between methyl mycotic acid synthase genes mmaA1 and mmaA2 and the flanking region in mmaA1 and mmaA2 genes.

Thus, it appears that there is a paucity of simple, rapid and reliable tests that can specifically detect M. tuberculosis during early stages of the disease. The present invention has identified ‘signature sequences’ that can differentiate M. tuberculosis from a large number of other mycobacterial DNA. These ‘signature sequences’ are used in detection of early disease in clinical samples of patients.

SUMMARY OF THE INVENTION

The invention provides novel signature sequences for diagnosis of Mycobacterium species (sps) in clinical samples with 100% specificity and a very high degree of sensitivity.

In one aspect, the invention provides a nucleotide sequence capable of selectively detecting pathogenic Mycobacterium sps using oligonucleotide primers corresponding to the signature sequence selected from SEQ ID NO: 1, 2, 3 or 4.

In another aspect the invention provides a method of detecting pathogenic mycobacterium sps in a clinical sample, said method comprising the steps of:

a. removal of contaminants from the clinical sample by conventional methods;

b. extraction of genomic DNA from the contaminant-free clinical sample;

c. designing a set of specific oligonucleotide primers capable of specifically detecting SEQ ID NO: 1, 2, 3 or 4 for use in RT-PCR;

d. analyzing PCR product by electrophoresis or specific probe nucleotide sequence complementary to SEQ ID NO: 1, 2, 3 or 4.

The set of oligonucleotide primers of the invention are selected from

(i)    5′ ATGCAGGTTGCGACTGTACACCCGG 3′
3′ GGCCGCTCTTGTTCTTCGTCGGAT 5′
(ii)   5′ GTGTTTGCGTTGAGTAATAATCTGAACCGTGT 3′
3′ AGCCAATTCCAGCACGATGTCGCC 5′
(iii)  5′ ATGCAGGTTGCGACTGTACACCCGG 3′
3′ GGCCGCTCTTGTTCTTCGTCGGAT 5′
(iv)   5′ TGTACCGCGTGCCCGACGATTTG 3′
3′ ACAGGCAGCTAACAGGGCGTCGG 5′

(v) a set of oligonucleotide primers complementary to (i), (ii), (iii) or (iv) or

(vi) a set of oligonucleotide primers comprising of sequence containing any 10 consecutive bases from one of the sequences selected from SEQ ID NO: 1, 2, 3 or 4.

In yet another aspect, the invention provides a kit for the detection of pathogenic mycobacterium sps in clinical samples, said kit comprising set of oligonucleotide primers selected from

(i)    5′ ATGCAGGTTGCGACTGTACACCCGG 3′
3′ GGCCGCTCTTGTTCTTCGTCGGAT 5′
(ii)   5′ GTGTTTGCGTTGAGTAATAATCTGAACCGTGT 3′
3′ AGCCAATTCCAGCACGATGTCGCC 5′
(iii)  5′ ATGCAGGTTGCGACTGTACACCCGG 3′
3′ GGCCGCTCTTGTTCTTCGTCGGAT 5′
(iv)   5′ TGTACCGCGTGCCCGACGATTTG 3′
3′ ACAGGCAGCTAACAGGGCGTCGG 5′

(v) a set of oligonucleotide primers complementary to (i), (ii), (iii) or (iv) or

(vi) a set of oligonucleotide primers comprising of sequence containing any 10 consecutive bases from one of the sequences selected from SEQ ID NO: 1, 2, 3 or 4.

Furthermore, the invention provides a method of detecting pathogenic mycobacterium sps in a clinical sample wherein the sample is isolated from individuals vaccinated against tuberculosis. It also provides a method of detecting pathogenic mycobacterium sps in a clinical sample wherein the sample is isolated from individuals treated against tuberculosis.

BRIEF DESCRIPTION OF FIGURES

FIG. 1A: Amplification of SS1 at low and varied DNA template concentrations.

FIG. 1B: Amplification of SS2 at low and varied DNA template concentrations.

FIG. 1C: Amplification of SS3 at low and varied DNA template concentrations.

FIG. 1D: Amplification of SS4 at low and varied DNA template concentrations.

FIG. 2: Amplification of signature sequences SS1, SS2, SS3 and SS4 from patient sputum samples.

FIG. 3: Amplification of signature sequences SS1 and SS3 from patient blood samples.

DETAILS OF THE INVENTION

The present invention relates to detection of pathogenic Mycobacterium species using signature sequences SEQ ID NO: 1, 2, 3 or 4 with a high degree of sensitivity and 100% specificity.

In one embodiment, the invention provides novel DNA diagnostic markers for specific detection of Mycobacterium tuberculosis which causes tuberculosis.

A three-pronged approach was carried out to identify novel DNA diagnostic marker for detection of pathogenic mycobacterium sps, especially, Mycobacterium tuberculosis. First step provides an in-silico approach to identify and shortlist potential sequences of Mycobacterium, unique and exclusive to pathogenic mycobacterium sps, especially Mycobacterium tuberculosis. The criteria used for selection of the potential sequences are presented below which involves comparative proteomic analysis of 13 mycobacterium species:

• • i. Strict pathogens (the most virulent pathogens) such as Mycobacterium tuberculosis, Mycobacterium laprae, Mycobacterium ulcerous and Mycobacterium bovis.
  • ii. Opportunistic pathogens, which belong to Non Tuberculous Mycobacteria (NTM) group, can cause pulmonary and other disseminated infections in immune compromised individuals (Infect. Genet. Evol. 12, 832, 2012; Appl. Environ. Microbiol. 79, 825, 2013). Mycobacterium marinum, Mycobacterium avium, Mycobacterium intracellulare, Mycobacterium aviumpara tuberculosis and Mycobacterium abscessus, cause opportunistic pulmonary infection in human whereas Mycobacterium avium subspecies paratuberculosis (MAP), the third member of MAC is the suspected causative agent of Crohn's disease in human (Appl. Environ. Microbiol. 79, 825, 2013; Crit. Rev. Microbiol. 38, 52, 2012).
  • iii. Non-pathogenic group includes Mycobacterium gilvum, Mycobacterium vanbaalenii, Mycobacterium smegmatis and Mycobacterium indicus pranii, which does not cause disseminated infections even in immune compromised individuals (BMC Microbiol. 10, 237, 2010; Infect. Genet. Evol., 12, 853, 2012; Br. J. Exp. Pathol. 52, 627, 1971).

The following bioinformatics process flow resulted in the identification of potential gene markers of the invention.

• • a) Perform all against all NCBI BLAST (J Mol Biol., 215, 403, 1990) on the protein sequences from the selected genomes.
  • b) Perform all against all NCBI BLAST ((J Mol Biol., 215, 403, 1990) on the nucleotide sequences from the selected genomes.
  • C) Identify Protein Domains from Pfam (Comp. Genomics, 396, 43, 2007) and GENE-3D/CATH (Nucleic Acids Research, 40, D465, 2012) using InterPro (Nucleic Acids Research, 40, D306, 2012).
  • d) Classify sequences into three categories namely i) CLASS 1 and ii) CLASS 2 as potential hits and iii) rest as non-hits.

The above process flow resulted in the classification of the potential hits into class 1 and class 2. As per the present invention, class 1 are genes unique to the organism of interest based on the fact that they do not share protein domain and protein sequence identity of more than 20% and nucleotide sequence identity of more than 35% with any other organism in the selected organism list. In another embodiment, class 2 genes are those that do not share protein domain and protein sequence identity of more than 20% and nucleotide sequence identity of more than 35% with any other organism in the selected organism list.

Table 1 provides potential candidate genes carrying ‘signature sequences’ based on the bioinformatics process flow.

TABLE 1
Potential “signature sequences” carrying candidate genes
H37Rv Gene
Identifiers	Class	H37Rv protein description
Rv1507A	1	Hypothetical protein
Rv1509	1	Hypothetical protein
Rv2645	1	Hypothetical protein
Rv2653c	1	Possible PhiRv2 prophage protein
Rv2654c	1	Possible PhiRv2 prophage protein
Rv2658c	1	Possible prophage protein
Rv0064A	2	Possible antitoxin VapB1
Rv0078B	2	Hypothetical protein
Rv0397A	2	Hypothetical protein
Rv0456B	2	Possible antitoxin MazE1
Rv0959A	2	Possible antitoxin VapB9
Rv1366A	2	Hypothetical protein
Rv1954A	2	Hypothetical protein
Rv1991A	2	Antitoxin MazE6
Rv2142A	2	Possible antitoxin ParD2
Rv2231A	2	Possible toxin VapC16
Rv2231B	2	Possible antitoxin VapB16
Rv2274A	2	Possible antitoxin MazE8
Rv2395A	2	Acid and phagosome regulated protein A AprA
Rv2395B	2	Acid and phagosome regulated protein B AprB
Rv2862A	2	Possible antitoxin VapB23
Rv3190A	2	Hypothetical protein
Rv3344c	2	PE-PGRS family protein PE_PGRS49]
		[partial = 5′]
Rv3512	2	PE-PGRS family protein PE_PGRS56]
		[partial = 5′]
Rv3599c	2	Hypothetical short protein

In one aspect, the invention functionally characterizes the potential ‘signature sequences (SS)’-carrying candidate genes based on functional information retrieved from Tuberculist (Tuberculosis (Edinb) 91, 7, 2011) and TB database (Nucleic Acids Research, 37, D499, 2009). Accordingly, the potential signature sequences can be functionally characterized into the following groups:

• • a. 9 (Rv0064A, Rv0456B, Rv0959A, Rv1991A, Rv2142A, Rv2231A, Rv2231B, Rv2274A and Rv2862A) fell into the toxin-antitoxin category.
  • b. 3 (Rv2653c, Rv2654c, Rv2658c) are possible prophages.
  • c. 2 (Rv3344c and Rv3512) belong to PE_PGRS family of proteins
  • d. 2 (Rv2645 and Rv2653c) are deleted (partially or completely) in one or more clinical isolates eliminating their use as diagnostic markers.
  • e. 9 (Rv1507A, Rv1509, Rv0078B, Rv2645, Rv0397A, Rv1366A, Rv1954A, Rv3599c, Rv3190A) are hypothetical proteins.
  • f. 2 (Rv2395A, Rv2395B) are acid and phagosome regulated proteins.

Based on the in-silico analysis, two Class 1 genes (Rv1507A and Rv1509) and two Class 2 genes (Rv1954A and Rv2231A) with homologs in Mycobacterium bovis BCG were selected as potential candidates (Table 2).

TABLE 2
Nucleotide Sequences of Potential “signature sequences” carrying genes
			Prediction
Gene Name	Sequence	Description	Class
Rv1507A	>Rv1507A	Gene length:	CLASS 1
hypothetical	ATGCAATCAGGTCAAAATATCCTCGCCAAGG	504 bp,
protein	TATGTAATTTGATTGAACAATCGCGACTTTC	Protein length:
	TTCAACGCGGTGTCTCCAATTTAGAATAACA	167 aa
	AATACGTCGCGCCCGCGACAGCTCCGCTGGA
	GCGAGTTCAAGCGATTCTGCGACATATTCAA
	TATGGTGCTCGGGAAGGCCAGGATGGGCCGC
	GACCCGGGGCGTCCGGTGCGCGATGAACGTC
	GCATCGTCTCCTGTGAGATAATTGCATCCGA
	TCATATAGGGCTGGCTGCGGCTAGGTTGCTG
	GCAAAAAGATATCGCGGCCGATCCGTTTCTG
	GTTTTGTCTTGATGATCAAATCCGCTTCCGT
	TCACGAGATCGATTCCTGGTCTTCCCCCAGC
	GTCGCGATGTCGATAGGTGTCGCGCTTTGTT
	CGTACCCGCACTACGCGGCGGCGAGAACCTC
	GCCACCGAATCGGGATTGGGGGGAGGATACC
	ACTCGGTCGAGGCCCGTCACCGGCCTTCTAG
	CGGGTTG
Rv1509	>Rv1509	Gene length:	CLASS 1
Essential	GTGTTTGCGTTGAGTAATAATCTGAACCGTG	882 bp,
hypothetical	TGAACGCATGCATGGATGGATTCCTTGCCCG	Protein length:
protein	TATCCGCTCACATGTTGATGCGCACGCGCCA	293 aa
	GAATTGCGTTCACTGTTCGATACGATGGCGG
	CCGAGGCCCGATTTGCACGCGACTGGCTGTC
	CGAGGACCTCGCGCGGTTGCCTGTCGGTGCA
	GCATTGCTGGAAGTGGGCGGGGGGGTACTTC
	TGCTCAGCTGTCAACTGGCGGCGGAGGGATT
	TGACATCACCGCCATCGAGCCGACGGGTGAA
	GGTTTTGGCAAGTTCAGACAGCTTGGCGACA
	TCGTGCTGGAATTGGCTGCAGCACGACCCAC
	CATCGCGCCATGCAAGGCGGAAGACTTTATT
	TCCGAGAAGCGGTTCGACTTCGCCTTCTCGC
	TGAATGTGATGGAGCACATCGACCTTCCGGA
	TGAGGCAGTCAGGCGGGTATCGGAAGTGCTG
	AAACCGGGGGCCAGTTACCACTTCCTGTGCC
	CGAATTACGTATTCCCGTACGAACCGCATTT
	CAATATCCCAACATTCTTCACCAAAGAGCTG
	ACATGCCGGGTGATGCGACATCGCATCGAGG
	GCAATACGGGCATGGATGACCCGAAGGGAGT
	CTGGCGTTCGCTCAACTGGATTACGGTTCCC
	AAGGTGAAACGCTTTGCGGCGAAGGATGCGA
	CGCTGACCTTGCGCTTCCACCGTGCAATGTT
	GGTATGGATGCTGGAACGCGCGCTGACGGAT
	AAGGAATTCGCTGGTCGCCGGGCACAATGGA
	TGGTCGCTGCTATTCGCTCGGCGGTGAAATT
	GCGTGTGCATCATCTGGCAGGCTATGTTCCC
	GCTACGCTGCAGCCCATCATGGATGTGCGGC
	TAACGAAGAGGTAA
Rv1954a	>gi|448814763:2201231-2201623	Gene length:	CLASS 2
Hypothetical	Mycobacterium tuberculosis H37Rv	303 bp,
protein	complete genome	Protein length:
	TGGTATAAGCTGGTTTTAGACGAAAAGGACC	100 bp
	CCACCTCGGGGTCTGATGGCCAGGGGCAGGG
	TCGTGTGCATTGGGGATGCAGGTTGCGACTG
	TACACCCGGCGTGTTCCGCGCGACAGCGGGT
	GGGATGCCGGTGCTGGTGGTCATCGAGTCTG
	GGACAGGAGGTGATCAGATGGCTCGTAAAGC
	TACGTCCCCGGGTAAGCCGGCTCCGACGTCG
	GGACAGTATCGCCCGGTTGGCGGTGGCAACG
	AGGTGACCGTTCCGAAGGGACACCGTCTGCC
	TCCCTCGCCCAAGCCCGGTCAGAAGTGGGTG
	AACGTCGATCCGACGAAGAACAAGAGCGGCC
	GCGGCTGAGCTTGTGCCGTCGGGATGGGTGT
	CGCACCGTCTCGGCGGGTCGC
Rv2231A	>gi|448814763:c2506224-2505671	Gene length:	CLASS 2
	Mycobacterium tuberculosis H37Rv	426 bp,
	complete genome	Protein length:
	GCCGCGGCGAGCCGGTAGCAAAGCTTGTGCC	141 aa
	GCTGCATCCTCATGAGACTCGGCGGTTAGGC
	ATTGACCATGGCGTGTACCGCGTGCCCGACG
	ATTTGGACGCTCCGTTGTCAGACGACGTGCT
	CGAACGCTTTCACCGGTGAAGCGCTACCTCA
	TCGACACCCACGTTTGGCTGCGGATGCCGTC
	AACGAAACACGGGCGATTGTTCAGGACGTCC
	GCAACAGCATTCTCTTGTCGGCCGCCAGTGC
	CTGGGAGATCGCGATCAACTACCGCCTCGGC
	AAGCTCCCGCCGCCCGAGCCATCGGCCTCTT
	ACGTGCCCGATCGAATGCGCCGCTGCGGCAC
	GTCGCCGCTGTCAGTTGACCACGCACACACT
	GCGCACCGCAGAGCTTCCGGATCACCATCGA
	CATCCATTCGACCGTGTGCTCATCGCCCAGG
	CACAGCTGCTTGGCCTGACGATCATCACCGC
	CGACGCCCTGTTAGCTGCCTGTGATGTCGCG
	GTTGTCGCCGCGTAGACAACGCGTCGGCGGT
	GCTCTGGATTCTTGGCCCGCACACCG

In a most preferred aspect, the signature sequences were designed keeping in view the diagnostic tool of RT PCR. These were short sequences amenable for PCR amplification from selected genes. The specific signature sequences, SS1 (Rv1507A), SS2 (Rv1509), SS3 (RV1954A) and SS4 (Rv2231A) of the invention are provided below. Homology search using NCBI nucleotide BLAST against the genus Mycobacterium was conducted on these signature sequences to confirm their uniqueness.

SS1 (Rv1507A):
>Rv1507A
SEQ ID NO: 1
ATGCAATCAGGTCAAAATATCCTCGCCAAGGTATGTAATTTGATTGAACA
ATCGCGACTTTCTTCAACGCGGTGTCTCCAATTTAGAATAACAAATACGT
CGCGCCCGCGACAGCTCCGCTGGAGCGAGTTCAAGCGATTCTGCGACATA
TTCAATATGGTGCTCGGGAAGGCCAGGATGGGCCGCGACCCGGGGCGTCC
GGTGCGCGATGAACGTCGCATCGTCTCCTG
SS2 (Rv1509):
>gi|448814763:1700212-1701093 Mycobacterium
tuberculosis H37Rv complete genome
SEQ ID NO: 2
GTGTTTGCGTTGAGTAATAATCTGAACCGTGTGAACGCATGCATGGATGG
ATTCCTTGCCCGTATCCGCTCACATGTTGATGCGCACGCGCCAGAATTGC
GTTCACTGTTCGATACGATGGCGGCCGAGGCCCGATTTGCACGCGACTGG
CTGTCCGAGGACCTCGCGCGGTTGCCTGTCGGTGCAGCATTGCTGGAAGT
GGGCGGGGGGGTACTTCTGCTCAGCTGTCAACTGGCGGCGGAGGGATTTG
ACATCACCGCCATCGAGCCGACGGGTGAAGGTTTTGGCAAGTTCAGACAG
CTTGGCGACATCGTGCTGGAATTGGCTGCA
SS3 (RV1954A):
>gi|448814763:2201277-2201579 Mycobacterium
tuberculosis H37Rv complete genome
SEQ ID NO: 3
ATGGCCAGGGGCAGGGTCGTGTGCATTGGGGATGCAGGTTGCGACTGTAC
ACCCGGCGTGTTCCGCGCGACAGCGGGTGGGATGCCGGTGCTGGTGGTCA
TCGAGTCTGGGACAGGAGGTGATCAGATGGCTCGTAAAGCTACGTCCCCG
GGTAAGCCGGCTCCGACGTCGGGACAGTATCGCCCGGTTGGCGGTGGCAA
CGAGGTGACCGTTCCGAAGGGACACCGTCTGCCTCCCTCGCCCAAGCCCG
GTCAGAAGTGGGTGAACGTCGATCCGACGA
SS4 (Rv2231A):
>gi|448814763:c2506161-2505736 Mycobacterium
tuberculosis H37Rv complete genome
SEQ ID NO: 4
TTGACCATGGCGTGTACCGCGTGCCCGACGATTTGGACGCTCCGTTGTCA
GACGACGTGCTCGAACGCTTTCACCGGTGAAGCGCTACCTCATCGACACC
CACGTTTGGCTGCGGATGCCGTCAACGAAACACGGGCGATTGTTCAGGAC
GTCCGCAACAGCATTCTCTTGTCGGCCGCCAGTGCCTGGGAGATCGCGAT
CAACTACCGCCTCGGCAAGCTCCCGCCGCCCGAGCCATCGGCCTCTTACG
TGCCCGATCGAATGCGCCGCTGCGGCACGTCGCCGCTGTCAGTTGACCAC
GCACACACTGCGCACCGCAGAGCTTCCGGATCACCATCGACATCCATTCG
ACCGTGTGCTCATCGCCCAGGCACAGCTGCTTGGCCTGA

For the purposes of PCR validation, the signature sequences SS1, SS2, SS3 and SS4 were selected and oligonucleotide primers were designed to generate corresponding specific PCR amplification products. Table 3 provides the set of designed oligonucleotide primers.

TABLE 3
Signature sequences SS1, SS2, SS3 and
SS4 and respective oligonucleotide primers
Signature
Sequences			Prediction
(SS)	Sequence	Description	Class
SS1 from	>Rv1507A	NZE_Rv1954A_F	CLASS 1
Rv1507A	ATGCAATCAGGTCAAAATATCCTCGCC	ATGCAGGTTGCGA
	AAGGTATGTAATTTGATTGAACAATCG	CTGTACACCCGG
	CGACTTTCTTCAACGCGGTGTCTCCAA	Length = 25,
	TTTAGAATAACAAATACGTCGCGCCCG	Tm = 58.6,
	CGACAGCTCCGCTGGAGCGAGTTCAAG	% G + C = 60
	CGATTCTGCGACATATTCAATATGGTG	NZE_Rv1954A_R
	CTCGGGAAGGCCAGGATGGGCCGCGAC	GGCCGCTCTTGTT
	CCGGGGCGTCCGGTGCGCGATGAACGT	CTTCGTCGGAT
	CGCATCGTCTCCTG	Length = 24,
		Tm = 57.4,
		% G + C = 58.3
		Amplicon
		Size = ~280 bp
SS2 from	>gi|448814763:1700212-1701093	NZE_Rv1509_F	CLASS 1
Rv1509	Mycobacterium tuberculosis H37Rv	GTGTTTGCGTTGA
	complete genome	GTAATAATCTGAA
	GTGTTTGCGTTGAGTAATAATCTGAAC	CCGTGT
	CGTGTGAACGCATGCATGGATGGATTC	Length = 32,
	CTTGCCCGTATCCGCTCACATGTTGAT	Tm = 57.5
	GCGCACGCGCCAGAATTGCGTTCACTG	% G + C = 41
	TTCGATACGATGGCGGCCGAGGCCCGA	NZE_Rv1509_R
	TTTGCACGCGACTGGCTGTCCGAGGAC	AGCCAATTCCAGC
	CTCGCGCGGTTGCCTGTCGGTGCAGCA	ACGATGTCGCC
	TTGCTGGAAGTGGGCGGGGGGGTACTT	Length = 24,
	CTGCTCAGCTGTCAACTGGCGGCGGAG	Tm = 58.8,
	GGATTTGACATCACCGCCATCGAGCCG	% G + C = 58.3
	ACGGGTGAAGGTTTTGGCAAGTTCAGA	Amplicon
	CAGCTTGGCGACATCGTGCTGGAATTG	Size = ~330 bp
	GCTGCA
SS3 from	>gi|448814763:2201277-2201579	NZE_Rv1954A_F	CLASS 2
Rv1954A	Mycobacterium tuberculosis H37Rv	ATGCAGGTTGCGA
	complete genome	CTGTACACCCGG
	ATGGCCAGGGGCAGGGTCGTGTGCATT	Length = 25,
	GGGGATGCAGGTTGCGACTGTACACCC	Tm = 58.6,
	GGCGTGTTCCGCGCGACAGCGGGTGGG	% G + C = 60
	ATGCCGGTGCTGGTGGTCATCGAGTCT	NZE_Rv1954A_R
	GGGACAGGAGGTGATCAGATGGCTCGT	GGCCGCTCTTGTT
	AAAGCTACGTCCCCGGGTAAGCCGGCT	CTTCGTCGGAT
	CCGACGTCGGGACAGTATCGCCCGGTT	Length = 24,
	GGCGGTGGCAACGAGGTGACCGTTCCG	Tm = 57.4,
	AAGGGACACCGTCTGCCTCCCTCGCCC	% G + C = 58.3
	AAGCCCGGTCAGAAGTGGGTGAACGTC	Amplicon
	GATCCGACGA	Size = ~280 bp
SS4 from	>gi|448814763:c2506161-2505736	NZE_Rv2231A_F	CLASS 2
Rv2231A	Mycobacterium tuberculosis H37Rv	TGTACCGCGTGCC
	complete genome	CGACGATTTG
	TTGACCATGGCGTGTACCGCGTGCCCG	Length = 23,
	ACGATTTGGACGCTCCGTTGTCAGACG	Tm = 59.1,
	ACGTGCTCGAACGCTTTCACCGGTGAA	% G + C = 61
	GCGCTACCTCATCGACACCCACGTTTG	NZE_Rv2231A_R
	GCTGCGGATGCCGTCAACGAAACACGG	ACAGGCAGCTAAC
	GCGATTGTTCAGGACGTCCGCAACAGC	AGGGCGTCGG
	ATTCTCTTGTCGGCCGCCAGTGCCTGG	Length = 23,
	GAGATCGCGATCAACTACCGCCTCGGC	Tm = 57.1,
	AAGCTCCCGCCGCCCGAGCCATCGGCC	% G + C = 65
	TCTTACGTGCCCGATCGAATGCGCCGC	Amplicon
	TGCGGCACGTCGCCGCTGTCAGTTGAC	Size = ~390 bp
	CACGCACACACTGCGCACCGCAGAGCT
	TCCGGATCACCATCGACATCCATTCGA
	CCGTGTGCTCATCGCCCAGGCACAGCT
	GCTTGGCCTGAC

In a preferred embodiment, pathogenic mycobacterium sps can be detected with 100% specificity following PCR using DNA isolated from clinical samples from patients who presented with clinical symptoms of the disease. In another embodiment, pathogenic mycobacterium sps is also detected using the above method in clinical samples isolated from individuals vaccinated against tuberculosis. In yet another embodiment, pathogenic mycobacterium sps is also detected using the above method in clinical samples isolated from individuals treated against tuberculosis.

Pathogenic mycobacterium sps, as provided in the invention, includes Mycobacterium tuberculosis and Mycobacterium bovis. More specifically, pathogenic mycobacterium sps represents Mycobacterium tuberculosis, the TB causing bacterium.

Clinical samples, as meant here, includes specimens such as blood, sputum, cerebrospinal fluid, gastric lavage, tissue biopsies and the likes thereof. PCR product can be easily visualized by any conventional method that can be readily recognized by a person skilled in the art such as electrophoresis.

Following Examples serve as a tool to illustrate the invention. However, it should in no way be considered to be limiting the invention.

Example 1

Determination of Specificity and Sensitivity of Signature Sequences

Genomic DNA for PCR Amplification

Genomic DNA of Mycobacterium tuberculosis and 13 other mycobacterial species were used for testing the specificity of signature sequences using PCR. These include, M. avium subspecies paratuberculosis, M. smegmatis (ATCC19420), M. vaccae, M. marinum (ATCC927), M. chelonae (ATCC14472), M. flavescens (ATCC14474), M. fortuitum (ATCC6481), M. kansasii (ATCC12478), M. bovis (ATCC27294), M. bovis (BCG), M. avium (ATCC25291), M. gastri, M. indicuspranii.

PCR Reaction

The PCR reaction mixture (50 μl) consisted of 10×taqPCR buffer, 0.5 mmolMgCl2, 0.4 mmol dNTP, 10 pmol forward and reverse primers respectively, 4% DMSO and 1Utaq DNA polymerase. The reaction conditions were the following: 95° C. for 5 minutes, followed by 35 cycles of 95° C. for 30 seconds, annealing temperature 50° C. for 30 seconds, 72° C. for 1 minute and finally 72° C. for 10 minutes. All PCR products were electrophoresed on 2% agarose gel with ethidium bromide staining.

The “signature sequences” were tested for their ability to differentiate Mycobacterium tuberculosis DNA from a large number of other mycobacterial DNA in PCR using primers complementary to these “signature sequences” as shown in Table 3. For this purpose, chromosomal DNA extracted from 13 mycobacterium species including human genomic DNA were tested by mycobacterium genus-specific primers of the ‘signature sequences’. SS1 and SS2 were negative for all 13 mycobacterium species tested whereas SS3 and SS4 show positive PCR results only when M. bovis BCG genomic DNA was used as template.

Table 4 summarizes the specificity data resulting from PCR using specific primers of signature sequences SS1, SS2, SS3 and SS4.

TABLE 4
Specific amplification of signature sequences from
Mycobacterium tuberculosis and M. bovis BCG
	Specimen	SS1	SS2	SS3	SS4
	M. tuberculosis	+	+	+	+
	M. bovis BCG	−	−	−	−
	M. avium	−	−	−	−
	M. smegmatis	−	−	−	−
	M. vaccae	−	−	−	−
	M. avium	−	−	−	−
	M. chelonae	−	−	−	−
	M. flori	−	−	−	−
	M. fortuitum	−	−	−	−
	M. kansasi	−	−	−	−
	M. bovis	−	−	−	−
	M. marinum	−	−	−	−
	M. gastri	−	−	−	−
	MIP	−	−	−	−
	MAP	−	−	−	−
	M. leprae
	Human Genome	−	−	−	−

Furthermore, sensitivity analysis revealed that the signature sequences were highly sensitive in being able to detect <1 ng (100pg) DNA as shown in FIGS. 1A, 1B, 1C and 1D for the four primers of the signature sequences SS1, SS2, SS3 and SS4 respectively.

Example 2

Evaluation of Mycobacterium tuberculosis-Specific Primer Pair Using Clinical Samples
A) Amplification of Signature Sequences from Patient Sputum Samples

Sputum samples were processed by the Universal Sample Processing (USP) method for DNA extraction as described by Chakravorty et al (J Clin Microbiol 43, 4357, 2005). DNA was isolated from the USP sediments by boiling in the presence of five volumes of solution containing 10% Chelex-100 resin, 0.03% triton X-100, and 0.3% Tween 20. The isolated DNA was stored at 20° C. and used for PCR assay.

PCR reaction was carried out using specific primers as given in Table 3.

The results show amplification of signature sequences in patient sputum sample (FIG. 2) demonstrating the diagnostic utility of the signature sequences for detecting pathogenic Mycobacterium tuberculosis.

B) Amplification of Signature Sequences from Patient Blood Samples

DNA from blood samples of tuberculosis patients were isolated as per the protocol described in van Heiden et al (isolation of DNA from Mycobacterium tuberculosis, Paul D. van Heiden, Thomas C. Victor, Robin M. Warren, and Eileen G. van Holden)

The results show amplification of SS1 and SS3 as seen in FIG. 3.

Claims

1: A method of detecting Mycobacterium tuberculosis in a clinical sample, said method comprising the steps of:

a) removal of contaminants from the clinical sample to generate a contaminant-free clinical sample;

b) extraction of genomic DNA from the contaminant-free clinical sample;

c) designing a set of specific oligonucleotide primers capable of specifically detecting SEQ ID NO: 2 for use in RT-PCR;

d) performing PCR with the oligonucleotide primers of step c) on the genomic DNA of step b) to produce a PCR product; and

e) analyzing the PCR product obtained in step d) by electrophoresis or a specific probe nucleotide sequence complementary to SEQ ID NO: 2.

2: The method of claim 1, wherein the set of oligonucleotide primers are selected from: (i)  (SEQ ID NO: 7) 5′ GTGTTTGCGTTGAGTAATAATCTGAACCGTGT 3′ and (SEQ ID NO: 8) 3′ AGCCAATTCCAGCACGATGTCGCC 5′;

(ii) a set of oligonucleotide primers complementary to (i);

or

(iii) a set of oligonucleotide primers comprising a sequence containing any 10 consecutive bases from the sequence of SEQ ID NO: 2.

3: The method of claim 1, wherein the clinical sample is isolated from individuals vaccinated against tuberculosis.

4: The method of claim 1, wherein the clinical sample is isolated from individuals treated against tuberculosis.