[The genetic susceptibility to leprosy in humans].

The capacity of certain individuals to resist certain diseases, including leprosy, has for a long time been considered as being influenced by genetic factors. The clinical and pathological spectrum of leprosy, epidemiological heterogeneity, both geographic and ethnic, in the prevalence of polar forms, may be explained by genetic differences in host resistance. While the specific genes in question have not been identified, recent studies suggest a genetic basis for differences in the capacity of macrophages in the host to reduce bacterial multiplication. Experimental models analyzing the reactions of antimycobacterial defence have underscored at existing differences in resistance or vulnerability to infection (M. bovis, BCG, M. lepraemurium, M. tuberculosis) were guided by a dominant gene which exists in two allelic forms, bcgr and bcg5. The bcgr allele confers resistance and is more dominant than the bcgs allele which represents greater vulnerability to infection. The murine candidate gene for the bcg gene has been named NRAMP (Natural Resistance-associated Macrophage Protein). Even though the exact function of NRAMP is not currently known, it has been demonstrated that this gene is expressed mainly in macrophages, and that it brings about increased bacteriostatic capacity in these cells. NRAMP is structurally homologous to the family of membranous proteins having a transport function linking ATP. NRAMP is similar to the membranous bacterial system transporting nitrites. The NRAMP protein is also involved as a signal of transduction during the activation of macrophages. It is therefore possible to conceive of genetic polymorphism at this locus intervening in specific and non-specific immune responses to infection. Apart from such potential polymorphism during the initial phase of infection, immunogenetic studies suggest that the polymorphism of class II HLA molecules could intervene in the evolution of secondary immune response to M. leprae. Knowing that HLA molecules are expressed in a co-dominant form, and attributing extraordinary allelic polymorphism to this locus, there may be a rather wide range of immune responses to the M. leprae antigens in subjects with discordant HLA and in populations which have varied genetic profiles. In general it has been acknowledged that HLA-DR isotypes are associated with protective response, while HLA-DQ isotypes are said to be associated with multibacillary lepromatous forms. The chief role of the HLA systems controlling cell-mediated immunity leads to the probability that differences in HLA haplotypes could contribute to the wide spectrum of immune responses observed in leprosy. Genetic determinants of resistance to leprosy cannot be described in a straightforward manner using a classic approach because the complex mechanisms of resistance, yet to be clarified and for which at least two loci are believed to be contributory, may be re-assessed like a multifactorial, multigenetic complex in which environmental events linked to the transmission of M. leprae, its duration, intensity and host factors, varying as a function of time, intervene. A close study of each element and better understanding of the physiological and pathological mechanisms of infection and disease are necessary in order to state the influence of genetic factors on each of them with greater precision.