Dear Sir:
I read with interest the recent article “Two Cases of Leprosy in Siblings Caused by Mycobacterium lepromatosis and Review of the Literature” by Sotiriou and others.1 I noted omission of a 2014 article that reported detection of M. lepromatosis in Brazil and Myanmar.2 The omission made the literature review incomplete, and more relevantly, failed to recognize wider geographic distribution of the agent that includes South America and Asia in addition to North and Central America. Worldwide, Brazil has the highest incidence of leprosy (1.7 per 10,000 population) with 33,955 new cases recorded in 2011.3
The 2014 article provided a systematic analysis of 96 leprosy cases from four countries.2 We confirmed an etiologic agent in 46 of the 52 patients from southern Brazil. Of the 46 patients, Mycobacterium leprae was detected in 36, M. lepromatosis in seven, and both agents in three. Thus, M. lepromatosis caused or contributed to 21.7% of cases. Methodologically, the species-specific polymerase chain reaction amplicons were all single band of designed length, and amplicons from two representative cases were sequenced to further verify specificity. The sequence of one amplicon was deposited in GenBank (http://www.ncbi.nlm.nih.gov/nuccore/GQ900374). We also detected M. lepromatosis in two of six patients from Myanmar, in accord with prior detection in Singapore.4
The editorial by Scollard5 accompanying the Sotiriou and others article was informative. However, the suggestion to lump M. lepromatosis and M. leprae as “M. leprae complex” is at odds with a genome-scale mismatch of ∼13% that was revealed recently.6,7 Intuitively, given that both organisms cause leprosy and are uncultivable so far, one tends to bundle them. But the genetic gap is simply too big to overlook. Somewhat analogously, the genomes of human and chimpanzee differ by ∼3%, and we cannot call us “human complex” or “chimpanzee complex.” By contrast, the term “Mycobacterium tuberculosis complex,” used in diagnostic microbiology, is appropriate because those organisms not only exhibit similar pathogenicity and phenotypic features but also have identical 16S rRNA genes and differ minimally (∼0.05%) in genome sequences. Microbiology today is defined by the inseparable features of morphology, culture characteristics, and genetics of a microbe.
The report of leprosy in red squirrels in Scotland is intriguing to note, particularly the 99% genetic match of its agent with M. lepromatosis.8 The study suggests likely presence of M. lepromatosis in Europe in addition to the Americas and Asia, and raises the question of why there have been no reports of human infections with M. lepromatosis in Europe.
Similar mycobacterial dermatitides in cows in France and in cats in Australia have been reported.9,10 The study of the cow agent analyzed portions of six conserved genes totaling 3,231 nucleotides.9 Judged from the GenBank deposits (KJ095004–KJ095009), the five protein-coding genes matched 88–93% in sequence with those of M. leprae and/or M. lepromatosis, and the 16S gene matched best with M. lepromatosis (98.4% identity). The cat agent was analyzed with a 556-bp segment of the 16S gene (AJ294740–AJ294746),10 with best matches with M. leprae, Mycobacterium haemophilum, and Mycobacterium malmoense (all 96.4–96.6%). Therefore, the cow and cat agents are likely two new Mycobacterium species. Thus far, none of the animal agents has been cultivated. Whether they contain pseudogenes—the hallmark of the leprosy bacilli—remains to be seen.
- 1.↑
Sotiriou MC, Stryjewska BM, Hill C, 2016. Two cases of leprosy in siblings caused by Mycobacterium lepromatosis and review of the literature. Am J Trop Med Hyg 95: 522–527.
- 2.↑
Han XY, Aung FM, Choon S-E, Werner B, 2014. Analysis of the leprosy agents Mycobacterium leprae and Mycobacterium lepromatosis in four countries. Am J Clin Pathol 142: 524–532.
- 3.↑
World Health Organization, 2012. Global leprosy situation, 2012. Wkly Epidemiol Rec 87: 317–328.
- 4.↑
Han XY, Sizer KC, Tan HH, 2012. Identification of the leprosy agent Mycobacterium lepromatosis in Singapore. J Drugs Dermatol 11: 168–172.
- 6.↑
Singh P, Benjak A, Schuenemann VJ, Herbig A, Avanzi C, Busso P, Nieselt K, Krause J, Vera-Cabrera L, Cole ST, 2015. Insight into the evolution and origin of leprosy bacilli from the genome sequence of Mycobacterium lepromatosis. Proc Natl Acad Sci USA 112: 4459–4464.
- 7.↑
Han XY, Mistry NA, Thompson EJ, Tang HL, Khanna K, Zhang L, 2015. Draft genome sequence of new leprosy agent Mycobacterium lepromatosis. Genome Announc 3: e00513–e00515.
- 8.↑
Meredith A, Del Pozo J, Smith S, Milne E, Stevenson K, McLuckie J, 2014. Leprosy in red squirrels in Scotland. Vet Rec 175: 285–286.
- 9.↑
Pin D, Guérin-Faublée V, Garreau V, Breysse F, Dumitrescu O, Flandrois JP, Lina G, 2014. Mycobacterium species related to M. leprae and M. lepromatosis from cows with bovine nodular thelitis. Emerg Infect Dis 20: 2111–2114.
- 10.↑
Malik R, Hughes MS, James G, Martin P, Wigney DI, Canfield PJ, Chen SC, Mitchell DH, Love DN, 2002. Feline leprosy: two different clinical syndromes. J Feline Med Surg 4: 43–59.