Dheeraj Malhotra

Leprosy and the adaptation of human toll-like receptor 1.

Leprosy is an infectious disease caused by the obligate intracellular pathogen Mycobacterium leprae and remains endemic in many parts of the world. Despite several major studies on susceptibility to leprosy, few genomic loci have been replicated independently. We have conducted an association analysis of more than 1,500 individuals from different case-control and family studies, and observed consistent associations between genetic variants in both TLR1 and the HLA-DRB1/DQA1 regions with susceptibility to leprosy (TLR1 I602S, case-control P = 5.7×10−8, OR = 0.31, 95% CI = 0.20–0.48, and HLA-DQA1 rs1071630, case-control P = 4.9×10−14, OR = 0.43, 95% CI = 0.35–0.54). The effect sizes of these associations suggest that TLR1 and HLA-DRB1/DQA1 are major susceptibility genes in susceptibility to leprosy. Further population differentiation analysis shows that the TLR1 locus is extremely differentiated. The protective dysfunctional 602S allele is rare in Africa but expands to become the dominant allele among individuals of European descent. This supports the hypothesis that this locus may be under selection from mycobacteria or other pathogens that are recognized by TLR1 and its co-receptors. These observations provide insight into the long standing host-pathogen relationship between human and mycobacteria and highlight the key role of the TLR pathway in infectious diseases.

IL-10 promoter single nucleotide polymorphisms are significantly associated with resistance to leprosy

The minor haplotype −3575A/-2849G/-2763C in IL-10 promoter has been defined as a marker of disease resistance to leprosy and its severity in Brazilian population. Our investigation of six single-nucleotide polymorphisms (SNPs) in IL-10 promoter in 282 Indian leprosy patients and 266 healthy controls by direct PCR sequencing, however, showed that the extended haplotype: −3575T/-2849G/-2763C/-1082A/-819C/-592C was associated with resistance to leprosy per se and to the development of severe form of leprosy, using either a binomial (controls vs cases, P=0.01, OR=0.58, CI=0.37–0.89) or ordinal (controls vs paucibacillary vs multibacillary, P=0.004) model. Whereas, IL-10 haplotype −3575T/-2849G/-2763C/-1082A/-819T/-592A was associated with the risk of development of severe form of leprosy (P=0.0002) in contrast to the minor risk haplotype −3575T/-2849A/-2763C in the Brazilian population. The role of IL-10 promoter SNPs in Brazilian and Indian population strongly suggests the involvement of IL-10 locus in the outcome of leprosy.

Association study of major risk single nucleotide polymorphisms in the common regulatory region of PARK2 and PACRG genes with leprosy in an Indian population

Single nucleotide polymorphisms (SNPs) in the regulatory region shared by PARK2 and PACRG have been identified as major risk factors for leprosy susceptibility in two ethnically distinct populations. We investigated the association of six SNPs present in this regulatory region with leprosy susceptibility in an Indian population. Genotyping was performed by direct PCR sequencing in 286 leprosy patients and 350 healthy controls. Our results showed that T allele of SNPs PARK2_e01 (−2599) and 28 kb target_2_1 was significantly associated with susceptibility to leprosy per se (P=0.03 and 0.03, respectively). The T allele of SNPs PARK2_e01 (−2599) showed a significant recessive effect (P=0.04) in susceptibility to leprosy in Indian population as against the dominant effect of haplotype T-C of the major risk SNPs PARK2_e01 (−2599) and rs1040079 in Brazilian and Vietnamese population. However, after bonferroni corrections, these significant differences disappeared. Haplotype analysis also showed a lack of significant association of any haplotype with cases or controls. The noninvolvement of major risk SNPs in the regulatory region of PARK2 and PACRG locus with leprosy susceptibility in Indian population highlights the differential effect of these SNPs in regulating genetic susceptibility to leprosy in different populations.

Genetic variations and interactions in anti-inflammatory cytokine pathway genes in the outcome of leprosy: a study conducted on a MassARRAY platform.

BACKGROUND Mycobacterium leprae is the etiologic pathogen that causes leprosy. The outcome of disease is dependent on the host genetic background. METHODS We investigated the association of 51 single-nucelotide polymorphisms (SNPs) in anti-inflammatory cytokines (IL-10, TGFB1, IL-6, IL-4, and IL-13) and receptors (IL-10RA, IL-10RB, TGFBR1, TGFBR2, IL-6R, IL-4R, IL-5RA, IL-5RB, and IL-13RA1) with susceptibility to leprosy in a case-control study from New Delhi in northern India. This was followed by replication testing of associated SNPs in a geographically distinct and unrelated population from Orissa in eastern India. The functional potential of SNPs was established with in vitro reporter assays. RESULTS Significant associations (P < .05) were observed for 8 polymorphisms (rs1800871, rs1800872, and rs1554286 of IL-10; rs3171425 and rs7281762 of IL-10RB; rs2228048 and rs744751 of TGFBR2; and rs1800797 of IL-6) with leprosy. This association was replicated for 4 SNPs (rs1554286 of IL-10, rs7281762 of IL-10RB, rs2228048 of TGFBR2, and rs1800797 of IL-6). The interaction study revealed a significantly greater association with leprosy risk than was obtained for any SNP individually. CONCLUSIONS This study provides an interesting insight on the cumulative polygenic host component that regulates leprosy pathogenesis.

How Far Have We Reached in Tuberculosis Vaccine Development

Tuberculosis, a bacterial disease prevalent since ancient times, continues to cause the most deaths globally compared with all other diseases. The causative agent Mycobacterium tuberculosis is responsible for different types of tuberculosis in humans; however, pulmonary tuberculosis is the most common and causes the most deaths. Mycobacterium tuberculosis is an intracellular pathogenic bacterium, which has developed sophisticated mechanisms to survive inside host mononuclear phagocytes and thus evade the host immune system. This is attributed primarily to an inadequate immune response toward infecting bacteria, which results in temporary growth inhibition rather than death and subsequently allows the bacteria to multiply immensely, leading to full-blown disease in an individual. This disease has become a challenge due to poor diagnosis, a low-efficiency tuberculosis vaccine (Mycobacterium bovis Bacillus Calmette-Guèrin [BCG]), a long-term antibacterial chemotherapy regimen (approximately 6 months), and an emergence of multiple drug resistant strains of Mycobacterium tuberculosis especially in people with human immune deficiency virus (HIV) infection, for whom researchers worldwide must develop effective short-term chemotherapy and an effective vaccine. In this review different aspects of vaccines in tuberculosis are discussed, and these include the traditional BCG vaccine, the modern auxotrophic vaccine, the subunit or acellular vaccine; and a DNA vaccine. We discuss also the potential of mycobacterial lipids as a vaccine or as an adjuvant in the future. Since complete genome information of Mycobacterium tuberculosis H37Rv and bioinformatics tools are available, it is possible to develop new strategies for a better and effective tuberculosis vaccine, which can replace the traditional BCG vaccine.

Promoter and intron‐1 region polymorphisms in the IFNG gene in patients with hepatitis E

Allelic and genotype variations in the promoter region and the dinucleotide (CA)n repeat region in intron 1 of the interferon‐g (IFNG) gene were analysed by direct sequencing and simple sequence length polymorphism (SSLP), respectively, in patients with acute hepatitis, and the prevalence was compared with that in healthy controls. Our results showed a significant association of heterozygous genotypes (CA)12/(CA)14 and (CA)12/(CA)16 in intron 1 of the IFNG gene in all categories of patients with acute hepatitis, classified on the basis of presence or absence of hepatitis E virus (HEV), in comparison with healthy controls. A novel polymorphism, −288 A→T [from the translational start site, as per Human Genome Organization (HUGO) nomenclature], in the promoter region of the IFNG gene leading to a loss of the consensus domain for the interferon‐stimulated response element (ISRE), as predicted by in silico analysis, was observed in 12.5% of patients with acute HEV infection. However, no significant difference in allele or genotype frequency was observed for the −288 promoter polymorphism, although the heterozygous −288 A/T genotype showed a moderate risk in patients with acute HEV infection alone (P = 0.29, odds ratio = 1.964, confidence interval = 0.46–8.45). The data suggest that the genotype at intron 1 of IFNG might affect susceptibility to acute hepatitis in HEV infection, which warrants further elucidation in a larger sample and also functional studies.

Gel-Based Nonradioactive Single-Strand Conformational Polymorphism and Mutation Detection

Single-strand conformation polymorphism (SSCP) for screening mutations/single-nucleotide polymorphisms (SNPs) is a simple, cost-effective technique, saving an expensive exercise of sequencing each and every PCR reaction product and assisting in choosing only the amplicons of interest with expected mutation. The principle of detection of small changes in DNA sequences is based on the changes in single-strand DNA conformations. The changes in electrophoretic mobility that SSCP detects are sequence-dependent. The limitations faced in SSCP range from the routine polyacrylamide gel electrophoresis (PAGE) problems to the problems of resolving mutant DNA bands. Both these problems could be solved by controlling PAGE conditions and by varying physical and environmental conditions such as pH, temperature, voltage, gel type and percentage, addition of additives or denaturants, and others. Despite much upgrading of the technology for mutation detection, SSCP continues to remain the method of choice to analyze mutations and SNPs in order to understand genomic variations, spontaneous and induced, and the genetic basis of diseases.