Leprosy in wild chimpanzees.

Humans are considered as the main host for Mycobacterium leprae1, the aetiological agent of leprosy, but spillover has occurred to other mammals that are now maintenance hosts, such as nine-banded armadillos and red squirrels2,3. Although naturally acquired leprosy has also been described in captive nonhuman primates4-7, the exact origins of infection remain unclear. Here we describe leprosy-like lesions in two wild populations of western chimpanzees (Pan troglodytes verus) in Cantanhez National Park, Guinea-Bissau and Taï National Park, Côte d'Ivoire, West Africa. Longitudinal monitoring of both populations revealed the progression of disease symptoms compatible with advanced leprosy. Screening of faecal and necropsy samples confirmed the presence of M. leprae as the causative agent at each site and phylogenomic comparisons with other strains from humans and other animals show that the chimpanzee strains belong to different and rare genotypes (4N/O and 2F). These findings suggest that M. leprae may be circulating in more wild animals than suspected, either as a result of exposure to humans or other unknown environmental sources.

Mycobacterium leprae genomes from naturally infected nonhuman primates.

Leprosy is caused by the bacterial pathogens Mycobacterium leprae and Mycobacterium lepromatosis. Apart from humans, animals such as nine-banded armadillos in the Americas and red squirrels in the British Isles are naturally infected with M. leprae. Natural leprosy has also been reported in certain nonhuman primates, but it is not known whether these occurrences are due to incidental infections by human M. leprae strains or by M. leprae strains specific to nonhuman primates. In this study, complete M. leprae genomes from three naturally infected nonhuman primates (a chimpanzee from Sierra Leone, a sooty mangabey from West Africa, and a cynomolgus macaque from The Philippines) were sequenced. Phylogenetic analyses showed that the cynomolgus macaque M. leprae strain is most closely related to a human M. leprae strain from New Caledonia, whereas the chimpanzee and sooty mangabey M. leprae strains belong to a human M. leprae lineage commonly found in West Africa. Additionally, samples from ring-tailed lemurs from the Bezà Mahafaly Special Reserve, Madagascar, and chimpanzees from Ngogo, Kibale National Park, Uganda, were screened using quantitative PCR assays, to assess the prevalence of M. leprae in wild nonhuman primates. However, these samples did not show evidence of M. leprae infection. Overall, this study adds genomic data for nonhuman primate M. leprae strains to the existing M. leprae literature and finds that this pathogen can be transmitted from humans to nonhuman primates as well as between nonhuman primate species. While the prevalence of natural leprosy in nonhuman primates is likely low, nevertheless, future studies should continue to explore the prevalence of leprosy-causing pathogens in the wild.

Chimpanzees used for medical research shed light on the pathoetiology of leprosy.

Leprosy is a chronic infectious disorder caused by Mycobacterium leprae, which mainly affects skin and peripheral nerves. It is classified as either paucibacillary or multibacillary based upon clinical manifestations and slit-skin smear results. It is speculated that leprosy develops after a long latency period following M. leprae infection. However, the actual time of infection and the duration of latency have never been proven in human patients. To date, four cases of spontaneous leprosy have been reported in chimpanzees who were caught in West Africa in infancy and used for medical research in the USA and Japan. One of these chimpanzees was extensively studied in Japan, and single-nucleotide polymorphism analysis for the M. leprae genome was conducted. This analysis revealed that the chimpanzee was infected with M. leprae during infancy in West Africa and the pathognomonic signs of leprosy appeared after at least 30 years of incubation. Analysis of leprosy in chimpanzees can contribute not only to medical research but also to the understanding of the pathoetiology of leprosy.

[Leprosy in a chimpanzee].

Leprosy is suspected to develop after a long period of latency following infection with Mycobacterium leprae (M. leprae) during infancy, but definitive proof has been lacking. We found a rare case of leprosy in a chimpanzee (Pan troglodytes) born in West Africa (Sierra Leone) and brought to Japan around 2 years of age. At 31, the ape started exhibiting pathognomic signs of leprosy. Pathological diagnosis, skin smear, serum anti-phenolic glycolipid-I (PGL-I) antibody, and by PCR analysis demonstrated lepromatous leprosy. Single-nucleotide polymorphism (SNP) analysis verified the West African origin of the bacilli. This occurrence suggests the possibility of leprosy being endemic among wild chimpanzees in West Africa, potentially posing a zoonotic risk.

Infection during infancy and long incubation period of leprosy suggested in a case of a chimpanzee used for medical research.

The length of the incubation period of leprosy following Mycobacterium leprae infection has never been conclusively determined, owing to the lack of a method to demonstrate the presence of an asymptomatic infection. We report a rare case of leprosy in a chimpanzee in which a 30-year incubation period was strongly suggested by single nucleotide polymorphism (SNP) analysis.

Modeling signaling pathways leading to wrinkle formation: identification of the skin aging target.

BACKGROUND: In the present scenario, wrinkle formation, prominent sign of skin ageing, is one of the most demanding areas of research. This burgeoning research demand to reduce, delay and restore the effects of skin ageing has led to the study of various signaling pathways leading to wrinkle formation. Wrinkles appear on skin due to influence of intrinsic and extrinsic factors on mitogenic reactions and signal transduction pathways. AIM: The aim of the present study is to analyze each protein involved in the signaling pathway leading to dilapidation of collagen and an attempt has been made to compare different signal transduction pathways to identify a common target for skin ageing. METHODS: In the present work, bioinformatics tools have been used to extract information from already existing experimental data. The statistical techniques are used for further analysis and make useful predictions for skin ageing. RESULTS: Stressors like UV irradiation, osmotic stress and heat shock have been reported to activate epidermal growth factor receptor, interleukin 1 receptor, tumor necrosis factor receptor, platelet-derived growth factor receptor and platelet activation factor receptor signaling pathways, which lead to the production of matrix metalloproteinases, collagen degradation and, consequently, wrinkle formation. When all the five signaling pathways were modeled, the c-jun part of the AP-1 transcription factor was found to be a common intermediate protein involved in all the signaling cascades. Moreover, it shows differential expression in the skin on response to stressors. CONCLUSION: We proposed c-jun to be the most potent target for drug designing against wrinkle formation.

Lepra espontánea en chimpancé (pan Troglodytes). A propósito de cuatro casos / No disponible

La lepra en primates se describe cada vez con más frecuencia, y mucho de estos casos se originan de forma espontánea, tras determinadas condiciones de estrés o coinfección por Virus de la Inmunodeficiencia Simiesca (SIV). Descibimos un “brote” de lepra lepromatosa simiesca en cuatro chimpancés mantenidos en cautividad en un centro de experimentación animal. El tratamiento de estos animales dio lugar a una remisión completa de las lesiones a los 16 meses de tratamiento con MDT, sin embargo, uno de los animales, desarrolló una leprorreacción con aparición de un eritema nodoso leproso, a los dos meses de iniciado el tratamiento. Paralemente al estudio clínico-patológico, en estos cuatro casos pusimos de manifiesto la existencia de alteraciones inmunohistopatológicas dérmicas semejantes a las descritas para la forma lepromatosa de lepra humana (AU)

Leprosy in pimates is being reported more frequently, and many cases are “spontaneous”, because of stress conditions and Simian Immunodeficiency Virus (SIV) coinfection. We report an “outbreak” of simian lepromatose leprosy in four chiimpanzees kept in captivity in an animal research center. Therapy of these animals, showed a complete remission of lesions in 16 months after MDT treatment however, one animal develop a leproreaction with an erythema nodosum leprosum (ENL) two months after beginning the therapy. Equally wer report the existence, in these animals, of cutaneous immunohistopathologic changes similar to human lepromatose leprosy (AU)

Evolutionary conservation of major histocompatibility complex-DR/peptide/T cell interactions in primates.

Many major histocompatibility complex (MHC) polymorphisms originate from ancient structures that predate speciation. As a consequence, members of the Mhc-DRB1*03 allelic lineage are not only present in humans but in chimpanzees and rhesus macaques as well. This emphasizes that Mhc-DRB1*03 members must have been present in a common ancestor of these primate species that lived about 30 million years ago. Due to the accumulation of genetic variation, however, alleles of the Mhc-DRB1*03 lineage exhibit species-unique sequences. To investigate the biological importance of such conservation and variation, we have studied both the binding and antigen presentation capacity of various trans-species Mhc-DRB1*03 lineage members. Here we show that p3-13 of the 65-kD heat-shock protein (hsp65) of Mycobacterium leprae and M. tuberculosis binds not only to HLA-DR17(3) but also to some chimpanzee and rhesus macaque class II-positive cells. Comparison of the corresponding human, chimpanzee, and rhesus macaque Mhc-DRB1*03 lineage members revealed the presence of uniquely shared amino acid residues, at positions 9-13 and 26-31, of the antigen-binding site that are critical for p3-13 binding. In addition it is shown that several nonhuman primate antigen-presenting cells that bind p3-13 can activate HLA-DR17-restricted T cells. Certain amino acid replacements, however, in Mhc-DRB1*03 lineage members did not influence peptide binding or T cell recognition. Therefore, these studies demonstrate that some polymorphic amino acid residues (motifs) within the antigen-binding site of MHC class II molecules that are crucial for peptide binding and recognition by the T cell receptor have been conserved for over 30 million years.

Nonhuman sources of leprosy.

Our findings establish that there are known extrahuman reservoirs of M. leprae in three animal species. There is considerable evidence that the armadillo plays a role in the epidemiology of leprosy in humans in Texas and Louisiana. The elimination of leprosy as a public health problem (defined by the World Health Organization as one active patient per 10,000 population) may be attainable by the wide application of current control measures; however, the ultimate eradication of leprosy must take into account extrahuman reservoirs of M. leprae. The impact that attempts to control or to eliminate leprosy in such reservoirs (e.g., the armadillo in Louisiana and Texas) would have on environmental and wild-life considerations would be profound. Whether or not similar situations prevail in other leprosy-endemic geographic areas is not known. Based on the armadillo experience, there seems to be ample justification for undertaking, forthwith, carefully designed surveys for enzootic leprosy in some of the major endemic areas of leprosy. At the current state of our knowledge of the subject, such surveys should be initiated in the natural habitats of the mangabey monkey and chimpanzees--in West Africa.

A serologic study of naturally acquired leprosy in chimpanzees.

Data from longitudinally obtained serum samples spanning several years has permitted us to identify two chimpanzees with leprosy and to estimate the time of Mycobacterium leprae exposure/infection. The results confirm high levels of specific anti-M. leprae phenolic glycolipid-I (PGL-I) as well as anti-lipo-arabinomannan (anti-LAM) antibodies in both chimpanzees, and identify additional chimpanzees with possible M. leprae exposure. The observations are consistent with the hypothesis that leprosy exists in chimpanzees in the U.S.A. and suggest the possibility that M. leprae may be transmitted among chimpanzees. The data suggest that monitoring anti-PGL-I and anti-LAM IgG and IgM levels longitudinally in leprosy contacts may be useful in the recognition of preclinical leprosy.

Naturally acquired and experimental leprosy in nonhuman primates.

Naturally-acquired leprosy has been observed in chimpanzees and sooty mangabey monkeys. Experimental multibacillary leprosy was established in 24 of 36 mangabey monkeys, 7 of 34 rhesus monkeys, and 15 of 19 African green monkeys following intravenous and intradermal inoculation of Mycobacterium leprae. The experimental disease strongly resembles leprosy in humans clinically, histopathologically, and immunologically. Thus, in addition to nine-banded armadillos in Louisiana and Texas, chimpanzees and sooty mangabeys in Africa, in the wild or in captivity, may serve as a zoonotic source of M. leprae. Investigators using chimpanzees and monkeys should be alerted to the possibility of naturally-acquired leprosy.

Leprosy as a zoonosis: an update.

Naturally-acquired leprosy has been reported in nine-banded armadillos captured in the southern United States, a chimpanzee from Sierra Leone, and in two "sooty" mangabey monkeys from Nigeria. A significant prevalence of leprosy in wild armadillos establishes this animal as a reservoir of M. leprae, and exposure to armadillos has been implicated as a source of leprosy in humans. Current evidence suggests that leprosy is a zoonosis in certain nonhuman primate species. Control and eradication programs for leprosy should take into consideration the possible influence of extra-human sources of M. leprae, especially zoonotic leprosy.

Leprosy

TODAY, leprosy impairs the physical, social, and economic well-being of millions. Those who live in Third World countries suffer most, because living conditions are marginal and health care provision systems are undeveloped or disrupted by political ferment.