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International Journal of Evolutionary Biology logoLink to International Journal of Evolutionary Biology
. 2014 Feb 25;2014:284170. doi: 10.1155/2014/284170

Mycobacterium tuberculosis H37Rv: In Silico Drug Targets Identification by Metabolic Pathways Analysis

Asad Amir 1,*, Khyati Rana 1, Arvind Arya 1, Neelesh Kapoor 1, Hirdesh Kumar 1, Mohd Asif Siddiqui 1
PMCID: PMC3955624  PMID: 24719775

Abstract

Mycobacterium tuberculosis (Mtb) is a pathogenic bacteria species in the genus Mycobacterium and the causative agent of most cases of tuberculosis. Tuberculosis (TB) is the leading cause of death in the world from a bacterial infectious disease. This antibiotic resistance strain lead to development of the new antibiotics or drug molecules which can kill or suppress the growth of Mycobacterium tuberculosis. We have performed an in silico comparative analysis of metabolic pathways of the host Homo sapiens and the pathogen Mycobacterium tuberculosis (H37Rv). Novel efforts in developing drugs that target the intracellular metabolism of M. tuberculosis often focus on metabolic pathways that are specific to M. tuberculosis. We have identified five unique pathways for Mycobacterium tuberculosis having a number of 60 enzymes, which are nonhomologous to Homo sapiens protein sequences, and among them there were 55 enzymes, which are nonhomologous to Homo sapiens protein sequences. These enzymes were also found to be essential for survival of the Mycobacterium tuberculosis according to the DEG database. Further, the functional analysis using Uniprot showed involvement of all the unique enzymes in the different cellular components.

1. Introduction

Mycobacterium tuberculosis (Mtb), the causative agent of tuberculosis (TB), remains a major health threat. Each year, 8 million new TB cases appear and 2 million individuals die of TB [1]. Further, about half a million new multidrug resistant TB cases are estimated to occur every year [2]. The existing drugs, although of immense value in controlling the disease to the extent that is being done today, have several shortcomings, the most important of them being the emergence of drug resistance rendering even the front-line drugs inactive. In addition, drugs such as rifampicin have high levels of adverse effects making them prone to patient incompliance. Another important problem with most of the existing antimycobacterials is their inability to act upon latent forms of the bacillus. In addition to these problems, the vicious interactions between the HIV (human immunodeficiency virus) and TB have led to further challenges for antitubercular drug discovery [3].

Recently, genome-scale metabolic network reconstructions for different organisms have enabled systematic analyses of metabolic functions and predictions of metabolism-related phenotypes. By collecting all possible biochemical reactions for specific organisms, different groups have reconstructed metabolic networks for bacteria, for example, Escherichia coli, Helicobacter pylori, and Chromohalobacter salexigens, eukaryotic microorganisms, mice, and even humans [46]. The website of the Systems Biology Research Group at the University of California, San Diego (http://gcrg.ucsd.edu/), provides a continuously updated list of genome-scale metabolic network reconstructions. Analysis of metabolic networks can provide insights into an organism's ability to grow under specific conditions. For example, given a specific set of nutrient conditions, flux balance analysis (FBA) of metabolic networks can accurately predict microbial cellular growth rates. In a recent work, a group of researchers used an approximate representation of in-host nutrient availability inferred from the literature to simulate the in-host metabolism of Salmonella typhimurium [7]. Moreover, metabolic network analyses can then be used to identify organism-specific essential genes by predicting the attenuation of microbial growth of specific deletion mutants [810].

The computational approach has been used to investigate novel drug targets in other pathogenic organisms such as Pseudomonas aeruginosa and in Helicobacter pylori [5, 11].

As most currently known, antibacterials are essentially inhibitors of certain bacterial enzymes; all enzymes specific to bacteria can be considered as potential drug targets [12]. In this study, we have adopted a strategy for comparative metabolic pathway analysis to find out some potential targets against M. tuberculosis (H37Rv). Only those enzymes which show unique properties than the host were selected as the target. Metabolic genes that are essential for pathogen growth but are not present in humans constitute actual and potential drug targets.

2. Materials and Methods

KEGG (Kyoto Encyclopedia of Gene and Genome) (http://www.genome.jp/pathways.html) [13] pathway database was used as a source of metabolic pathway information. Metabolic pathway identification numbers of the host H. sapiens and the pathogen M. tuberculosis (H37Rv) were extracted from the KEGG database. Pathways which do not appear in the host but are present in the pathogen according to KEGG database have been identified as pathways unique to M. tuberculosis as in comparison to the host H. sapiens. Enzymes in these unique pathways as well as enzymes involved in other metabolic pathways under carbohydrate metabolism, energy metabolism, lipid metabolism, nucleotide metabolism, amino acid metabolism, metabolism of other amino acids, and glycan biosynthesis were identified from the KEGG database. The corresponding protein sequences of enzymes involved in unique pathways were identified and their protein sequences were retrieved in FASTA format from KEGG database.

The unique enzymes were further analyzed for essentiality to pathogen by DEG (Database of Essential Genes) database (http://tubic.tju.edu.cn/deg/) [14], and considered cutoff score was >100 to enhance the specificity of enzyme in M. tuberculosis.

The obtained targets genes were further analyzed by UniProt (Universal Protein Resource) (http://www.uniprot.org/) database to find out their functions. This is required to find out the surface membrane proteins which could be probable vaccine targets.

3. Results and Discussion

3.1. Identification of Unique Pathways and Potential Drug Targets

Tuberculosis (TB) is a major cause of illness and death worldwide, especially in Asia and Africa. Globally, 9.2 million new cases and 1.7 million deaths from TB occurred in 2006, of which 0.7 million cases and 0.2 million deaths were in HIV-positive people [2]. The existing drugs have several shortcomings, the most important of them being the emergence of drug resistance.

No new anti-Mtb drugs have been developed for well over 20 years. In view of the increasing development of resistance to the current leading anti-Mtb drugs, novel strategies are desperately needed to avert the “global catastrophe” forecast by the WHO (World Health Organization). Therefore, computational approach for drug targets identification, specifically for Mtb, can produce a list of reliable targets very rapidly. These methods have the advantage of speed and low cost and, even more importantly, provide a systems view of the whole microbe at a time. Since it is generally believed that the genomes of bacteria contain genes both with and without homologues to the human host. Using computational approach for target identification it is very quick to produce a desirable list.

In the present study, 5 unique pathways, C5-branched dibasic acid metabolism, carbon fixation pathways in prokaryotes, methane metabolism, lipopolysaccharide biosynthesis, and peptidoglycan biosynthesis with 60 new nonhomologous targets were identified through in silico comparative metabolic pathway analysis of Homo sapiens and M. tuberculosis H37Rv using KEGG database. Pathways which are not present in the Homo sapiens but present in the Mycobacterium are designated as unique pathways. Design and targeting inhibitors against these nonhomologous sequences could be the better approach for generation of new drugs. Thus total 5 unique metabolic pathways have been taken in M. tuberculosis (Table 1).

Table 1.

Unique pathways of M. tuberculosis when compared to H. sapiens.

S. no. Pathway name Human Mycobacterium  tuberculosis H37Rv
1 Carbohydrate Metabolism
1.1  C5-Branched dibasic acid metabolism Absent Present
2 Energy Metabolism
2.1  Photosynthesis Absent Absent
2.2  Carbon fixation pathways in prokaryotes Absent Present
2.3  Methane metabolism Absent Present
3 Lipid Metabolism
3.1  Fatty acid elongation in mitochondria Present Absent
3.2  Sphingolipid metabolism Present Absent
3.3  Arachidonic acid metabolism Present Absent
4 Nucleotide Metabolism All Present All Present
5 Amino Acid Metabolism All Present All Present
6 Metabolism of Other Amino Acids All Present All Present
6.1  Phosphonate and phosphinate metabolism Absent Absent
7 Glycan Biosynthesis and Metabolism
7.1  N-Glycan biosynthesis Present Absent
7.2  Various types of N-glycan biosynthesis Absent
7.3  Mucin type O-Glycan biosynthesis Present Absent
7.4  Other types of O-glycan biosynthesis Present Absent
7.5  Glycosaminoglycan biosynthesis—chondroitin sulfate Present Absent
7.6  Glycosaminoglycan biosynthesis—heparan sulfate Present Absent
7.7  Glycosaminoglycan biosynthesis—keratan sulfate Present Absent
7.8  Glycosaminoglycan degradation Present Absent
7.9  Glycosylphosphatidylinositol (GPI)-anchor biosynthesis Present Absent
7.10  Glycosphingolipid biosynthesis—lacto and neolacto series Present Absent
7.11  Glycosphingolipid biosynthesis—globo series Present Absent
7.12  Glycosphingolipid biosynthesis—ganglio series Present Absent
7.13  Lipopolysaccharide biosynthesis Absent Present
7.14  Peptidoglycan biosynthesis Absent Present
7.15  Other Glycan degradation Present Absent
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3.2. Identification of Essential Genes

Essential genes are those indispensable for the survival of an organism, and their functions are, therefore, considered a foundation of life. Total 55 enzymes out of all were found to be essential for M. tuberculosis life cycle (Table 2). These targets were found to be potential targets and could be considered for rational drug design. Using metabolic pathway information as the starting point for the identification of potential targets has its advantages as each step in the pathway is validated as the essential function for the survival of the bacterium.

Table 2.

Essential enzymes using DEG.

S. no. Entry no. Protein name Essential enzyme
1. Rv1820 Acetolactate synthase Yes
2. Rv0951 Succinyl-CoA synthetase subunit beta Yes
3. Rv2987c Isopropylmalate isomerase small subunit Yes
4. Rv1475c Aconitate hydratase (EC: 4.2.1.3) Yes
5. Rv0066c Isocitrate dehydrogenase (EC: 1.1.1.42) Yes
6. Rv2454c 2-Oxoglutarate ferredoxin oxidoreductase subunit beta (EC: 1.2.7.3) Yes
7. Rv1240 Malate dehydrogenase (EC: 1.1.1.37) Yes
8. Rv1098c Fumarate hydratase (EC: 4.2.1.2) Yes
9. Rv0247c Fumarate reductase iron-sulfur subunit (EC: 1.3.99.1) Yes
10. Rv3356c Bifunctional 5,10-methylene-tetrahydrofolate dehydrogenase/5,10-methylene-tetrahydrofolate Cyclohydrolase (EC: 1.5.1.5 3.5.4.9) Yes
11. Rv0951 Succinyl-CoA synthetase subunit beta (EC: 6.2.1.5) Yes
12. Rv0904c Putative acetyl-coenzyme A carboxylase carboxyl transferase subunit beta (EC: 6.4.1.2) Yes
13. Rv0973c Acetyl-/propionyl-coenzyme A carboxylase subunit alpha (EC: 6.3.4.14) Yes
14. Rv1492 Methylmalonyl-CoA mutase small subunit (EC: 5.4.99.2) Yes
15. Rv3667 Acetyl-CoA synthetase (EC: 6.2.1.1) Yes
16. Rv0409 Acetate kinase (EC: 2.7.2.1) Yes
17. Rv0408 Phosphate acetyltransferase (EC: 2.3.1.8) Yes
18. Rv0243 Acetyl-CoA acetyltransferase (EC: 2.3.1.9) Yes
19. Rv0860 Fatty oxidation protein FadB Yes
20. Rv3667 Acetyl-CoA synthetase (EC: 6.2.1.1) Yes
21. Rv0373c Carbon monoxyde dehydrogenase large subunit (EC: 1.2.99.2) No
22. Rv2900c Formate dehydrogenase H (EC: 1.2.1.2) No
23. Rv1023 Phosphopyruvate hydratase (EC: 4.2.1.11) Yes
24. Rv1240 Malate dehydrogenase (EC: 1.1.1.37) Yes
25. Rv0070c Serine hydroxymethyltransferase (EC: 2.1.2.1) Yes
26. Rv2205c Hypothetical protein Yes
27. Rv0761c Zinc-containing alcohol dehydrogenase NAD dependent AdhB (EC: 1.1.1.1) Yes
28. Rv0489 Phosphoglyceromutase (EC: 5.4.2.1) Yes
29. Rv0363c Fructose-bisphosphate aldolase (EC: 4.1.2.13) Yes
30. Rv2029c Phosphofructokinase PfkB (phosphohexokinase) (EC: 2.7.1.—) Yes
31. Rv1908c Catalase-peroxidase-peroxynitritase T KatG (EC: 1.11.1.6) Yes
32. Rv0070c Serine hydroxymethyltransferase (EC: 2.1.2.1) Yes
33. Rv0728c D-3-phosphoglycerate dehydrogenase (EC: 1.1.1.95) Yes
34. Rv0505c Phosphoserine phosphatase (EC: 3.1.3.3) Yes
35. Rv0884c Phosphoserine aminotransferase (EC: 2.6.1.52) Yes
36. Rv0409 Acetate kinase (EC: 2.7.2.1) Yes
37. Rv0408 Phosphate acetyltransferase (EC: 2.3.1.8) Yes
38. Rv3667 Acetyl-CoA synthetase (EC: 6.2.1.1) Yes
39. Rv2611c Lipid A biosynthesis lauroyl acyltransferase (EC: 2.3.1. —) Yes
40. Rv0114 D-alpha,beta-D-heptose-1,7-biphosphate phosphatase (EC: 2. —.—.—) Yes
41. Rv0113 Phosphoheptose isomerase (EC: 5. —.—.—) Yes
42. Rv1315 UDP-N-acetylglucosamine 1-carboxyvinyltransferase (EC: 2.5.1.7) Yes
43. Rv0482 UDP-N-acetylenolpyruvoylglucosamine reductase (EC: 1.1.1.158) Yes
44. Rv2152c UDP-N-acetylmuramate-L-alanine ligase (EC: 6.3.2.8) Yes
45. Rv2155c UDP-N-acetylmuramoyl-L-alanyl-D-glutamate synthetase (EC: 6.3.2.9) Yes
46. Rv2157c UDP-N-acetylmuramoylalanyl-D-glutamyl-2,6-diaminopimelate-D-alanyl-D-alanyl ligase MurF Yes
47. Rv2156c Phospho-N-acetylmuramoyl-pentapeptide-transferase (EC: 2.7.8.13) Yes
48. Rv2153c Undecaprenyldiphospho-muramoylpentapeptide beta-N-acetylglucosaminyltransferase (EC: 2.4.1.227) Yes
49. Rv2911 D-alanyl-D-alanine carboxypeptidase (EC: 3.4.16.4) No
50. Rv2981c D-alanyl-alanine synthetase A (EC: 6.3.2.4) Yes
51. Rv2136c Undecaprenyl pyrophosphate phosphatase (EC: 3.6.1.27) Yes
52. Rv2911 D-alanyl-D-alanine carboxypeptidase (EC: 3.4.16.4) No
53. Rv2158c UDP-N-acetylmuramoylalanyl-D-glutamate-2,6-diaminopimelate ligase (EC: 6.3.2.13) Yes
54. Rv2157c UDP-N-acetylmuramoylalanyl-D-glutamyl-2,6-diaminopimelate-D-alanyl-D-alanyl ligase MurF Yes
55. Rv2156c Phospho-N-acetylmuramoyl-pentapeptide-transferase (EC: 2.7.8.13) Yes
56. Rv2153c Undecaprenyldiphospho-muramoylpentapeptide beta-N-acetylglucosaminyltransferase (EC: 2.4.1.227) Yes
57. Rv3910 Transmembrane protein Yes
58. Rv0016c Penicillin-binding protein PbpA Yes
59. Rv2163c Penicillin-binding membrane protein PbpB Yes
60. Rv2911 D-alanyl-D-alanine carboxypeptidase (EC: 3.4.16.4) No
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3.3. Identification of Drug Target's Functions Using UniProt

The subcellular localization analysis of all supposed essential and unique enzymes of M. tuberculosis were evaluated by UniProt server. As it was suggested that, membrane associated protein could be the better target for developing vaccines. After functional analysis unique enzymes involved in cellular components like cell wall, cytoplasm, extracellular region, plasma membrane, and so forth, their biological processes and their functions have been retrieved (Table 3).

Table 3.

Shows function of all Essential proteins.

S. no. Accession. no. Celllular component Biological process Molecular function
1 Rv1820 Not known Branched chain family amino acid biosynthetic process Acetolactate synthase activity, magnesium ion binding, thiamine pyrophosphate binding
2. Rv0951 Cell wall, cytosol Growth, tricarboxylic acid cycle ATP binding, metal ion binding, succinate-CoA ligase (ADP-forming) activity
3. Rv2987c Plasma membrane, 3-isopropylmalate dehydratase complex Growth, leucine biosynthetic process 3-Isopropylmalate dehydratase activity
4. Rv1475c Cell wall, cytosol, extracellular region, plasma membrane Growth, response to iron ion 4 iron, 4 sulfur cluster binding, aconitate hydratase activity, iron-responsive element binding
5. Rv0066c Cytosol, extracellular region, plasma membrane Tricarboxylic acid cycle NAD binding, isocitrate dehydrogenase (NADP+) activity, magnesium ion binding, protein homodimerization activity
6. Rv2454c Cell wall, cytosol Oxidation-reduction process 2-Oxoglutarate synthase activity, magnesium ion binding, thiamine pyrophosphate binding
7. Rv1240 Cytosol, plasma membrane Glycolysis, malate metabolic process, tricarboxylic acid cycle L-malate dehydrogenase activity, binding
8. Rv1098c Cytosol, extracellular region, plasma membrane Growth, tricarboxylic acid cycle Fumarate hydratase activity
9. Rv0247c Plasma membrane Tricarboxylic acid cycle Electron carrier activity, iron-sulfur cluster binding, succinate dehydrogenase activity
10. Rv3356c Extracellular region, plasma membrane Folic acid-containing compound biosynthetic process, growth, histidine biosynthetic process, methionine biosynthetic process, one-carbon metabolic process, oxidation-reduction process, purine nucleotide biosynthetic process Binding, methenyltetrahydrofolate cyclohydrolase activity, methylenetetrahydrofolate dehydrogenase (NADP+) activity
11. Rv0951 Cell wall, cytosol Growth, tricarboxylic acid cycle ATP binding. metal ion binding, succinate-CoA ligase (ADP-forming) activity
12. Rv0904c Acetyl-CoA carboxylase complex, plasma membrane Mycolic acid biosynthetic process ATP binding, acetyl-CoA carboxylase activity, protein binding
13. Rv0973c Plasma membrane Growth ATP binding, biotin binding, biotin carboxylase activity
14. Rv1492 Cell wall, cytosol, plasma membrane Lactate fermentation to propionate and acetate, propionate metabolic process, methylmalonyl pathway Cobalamin binding, metal ion binding, methylmalonyl-CoA mutase activity
15. Rv3667 Cell wall, plasma membrane Not known AMP binding, ATP binding, acetate-CoA ligase activity
16. Rv0409 Cytoplasm Organic acid metabolic process ATP binding, acetate kinase activity
17. Rv0408 Cytoplasm, extracellular region Not known Phosphate acetyltransferase activity
18. Rv0243 Cytosol, plasma membrane Growth of symbiont in host cell Acetyl-CoA C-acyltransferase activity
19. Rv0860 Cytosol, plasma membrane Fatty acid metabolic process, oxidation-reduction process Coenzyme binding, oxidoreductase activity
20. Rv3667 Cell wall, plasma membrane Not known AMP binding, ATP binding, acetate-CoA ligase activity
21. Rv1023 Cell surface, extracellular region, phosphopyruvate hydratase complex, plasma membrane Glycolysis, growth Magnesium ion binding, phosphopyruvate hydratase activity
22. Rv1240 Cytosol, plasma membrane Glycolysis, malate metabolic process, tricarboxylic acid cycle L-malate dehydrogenase activity, binding
23. Rv0070c Not known Not known Not known
24. Rv2205c Not known Organic acid phosphorylation Glycerate kinase activity
25. Rv0761c Oxidation-reduction process Cytoplasm, plasma membrane alcohol dehydrogenase (NAD) activity, zinc ion binding
26. Rv0489 Plasma membrane Glycolysis Phosphoglycerate mutase activity
27. Rv0363c Extracellular region, plasma membrane Glycolysis, protein homotetramerization Fructose-bisphosphate aldolase activity, zinc ion binding
28. Rv2029c Not known Carbohydrate metabolic process Kinase activity, phosphotransferase activity, alcohol group as acceptor
29. Rv1908c Not known Hydrogen peroxide catabolic process, oxidation-reduction process, response to antibiotic Catalase activity, heme binding
30. Rv0070c Not Known Not Known Not known
31. Rv0728c Not Known Oxidation-reduction process NAD binding, phosphoglycerate dehydrogenase activity
32. Rv0505c Integral to plasma membrane Not Known Metal ion binding, phosphatase activity
33. Rv0884c Cytoplasm, extracellular region, plasma membrane L-serine biosynthetic process, growth, pyridoxine biosynthetic process O-phospho-L-serine: 2-oxoglutarate aminotransferase activity, pyridoxal phosphate binding
34. Rv0409 Cytoplasm Organic acid metabolic process ATP binding, acetate kinase activity
35. Rv0408 Cytoplasm, extracellular region Not known Phosphate acetyltransferase activity
36. Rv3667 Cell wall, plasma membrane Not known AMP binding, ATP binding, acetate-CoA ligase activity
37. Rv2611c Integral to membrane, plasma membrane Glycolipid biosynthetic process, growth, lipopolysaccharide core region biosynthetic process Acyltransferase activity
38. Rv0114 Cytoplasm Carbohydrate metabolic process, histidine biosynthetic process Histidinol-phosphatase activity
39. Rv0113 Cytoplasm Carbohydrate metabolic process D-sedoheptulose 7-phosphate isomerase activity, metal ion binding, sugar binding
40. Rv1315 Cytoplasm UDP-N-acetylgalactosamine biosynthetic process, cell cycle, cell division, cellular cell wall organization, growth, peptidoglycan biosynthetic process, regulation of cell shape UDP-N-acetylglucosamine 1-carboxyvinyltransferase activity
41. Rv0482 Cytoplasm Cell cycle, cell division, cellular cell wall organization, oxidation-reduction process, peptidoglycan biosynthetic process, regulation of cell shape UDP-N-acetylmuramate dehydrogenase activity, flavin adenine dinucleotide binding
42. Rv2152c Cytoplasm Cell cycle, cell division, cellular cell wall organization, growth, peptidoglycan biosynthetic process, regulation of cell shape ATP binding, UDP-N-acetylmuramate-L-alanine ligase activity
43. Rv2155c Cytosol Cell cycle, cell division, cellular cell wall organization, growth, peptidoglycan biosynthetic process, regulation of cell shape ATP binding, UDP-N-acetylmuramoylalanine-D-glutamate ligase activity, protein binding
44. Rv2157c Cytoplasm Cell cycle, cell division, cellular cell wall organization, growth, peptidoglycan biosynthetic process, regulation of cell shape ATP binding, UDP-N-acetylmuramoyl-tripeptide-D-alanyl-D-alanine ligase activity, UDP-N-acetylmuramoylalanyl-D-glutamyl-2,6-diaminopimelate-D-alanyl-D-alanine ligase activity
45. Rv2156c Integral to membrane, plasma membrane Cell cycle, cell division, cellular cell wall organization, growth, peptidoglycan biosynthetic process, regulation of cell shape Phospho-N-acetylmuramoyl-pentapeptide-transferase activity
46. Rv2153c Plasma membrane Cell cycle, cell division, cellular cell wall organization, growth, regulation of cell shape, UDP-N-acetylgalactosamine biosynthetic process, lipid glycosylation, peptidoglycan biosynthetic process Carbohydrate binding, undecaprenyldiphospho-muramoylpentapeptide beta-N-acetylglucosaminyltransferase activity
47. Rv2981c Cell wall, cytoplasm, plasma membrane Cellular cell wall organization, growth, peptidoglycan biosynthetic process, regulation of cell shape ATP binding, D-alanine-D-alanine ligase activity, metal ion binding
48. Rv2136c Integral to membrane, plasma membrane Cellular cell wall organization, peptidoglycan biosynthetic process, regulation of cell shape, dephosphorylation, response to antibiotic, response to nitrosative stress Undecaprenyl-diphosphatase activity
49. Rv2158c Cytosol, plasma membrane Cell cycle, cell division, cellular cell wall organization, peptidoglycan biosynthetic process, regulation of cell shape ATP binding, UDP-N-acetylmuramoylalanyl-D-glutamate-2,6-diaminopimelate ligase activity
50. Rv2157c Cytoplasm Cell cycle, cell division, cellular cell wall organization, growth, peptidoglycan biosynthetic process, regulation of cell shape ATP binding, UDP-N-acetylmuramoyl-tripeptide-D-alanyl-D-alanine ligase activity, UDP-N-acetylmuramoylalanyl-D-glutamyl-2,6-diaminopimelate-D-alanyl-D-alanine ligase activity
51. Rv2156c Integral to membrane, plasma membrane Cell cycle, cell division, cellular cell wall organization, growth, peptidoglycan biosynthetic process, regulation of cell shape Phospho-N-acetylmuramoyl-pentapeptide-transferase activity
52. Rv2153c Plasma membrane Cell cycle, cell division, cellular cell wall organization, growth, peptidoglycan biosynthetic process, regulation of cell shape, UDP-N-acetylgalactosamine biosynthetic process Carbohydrate binding, undecaprenyldiphospho-muramoylpentapeptide beta-N-acetylglucosaminyltransferase activity
53. Rv3910 Integral to plasma membrane Not known Not known
54. Rv0016c Cell septum, cytosol, integral to membrane, plasma membrane Cellular cell wall organization, peptidoglycan biosynthetic process, regulation of cell shape Penicillin binding, transferase activity
55. Rv2163c Extracellular region Growth, peptidoglycan-based cell wall biogenesis Penicillin binding, protein binding
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In conclusion, the computational genomic approach has facilitated the search for potential drug targets against M. tuberculosis. Use of the DEG database is more efficient than conventional methods for identification of essential genes and it facilitates the exploratory identification of the most relevant drug targets in the pathogen. The current study can be carried forward to design a drug that can block these drug targets. The microorganisms are fast in gaining resistance to the existing drugs, so designing better and effective drugs needs a faster method.

Appendix

See Tables 1, 2, and 3.

Conflict of Interests

The authors declare that there is no conflict of interests regarding the publication of this paper.

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