Drug resistance in leprosy: An update following 70years of chemotherapy.

Leprosy is one of the oldest infectious diseases, reported for more than 2000years. Leprosy elimination goal as a public health problem set by the World Health Organization, aiming for a global prevalence rate<1 patient in a population of 10,000, was achieved in 2000 mainly thanks to the worldwide use of leprosy drugs starting in the 1980s and their access at no cost for patients since 1995. However, around 200,000 new cases are still reported each year, particularly in India, Brazil, and Indonesia. As with other bacteria of medical interest, antimicrobial resistance is observed in Mycobacterium leprae strains in several parts of the world, despite multidrug therapy being the recommended standard leprosy treatment to avoid resistance selection since 1982. Therefore, identifying and monitoring resistance is necessary. We provide an overview of the historical facts that led to the current drug resistance situation, the antibiotics effective against M. leprae, their mechanisms of action and resistance, and resistance detection methods. We also discuss therapeutic management of the resistant cases, new genes with potential roles in drug resistance and bacterial adaptation, new drugs under investigation, and the risk for resistance selection with the chemoprophylaxis measures.

Drug resistance in leprosy: an update following 70 years of chemotherapy

Leprosy is one of the oldest infectious diseases, reported for more than 2000 years. Leprosy elimination goal as a public health problem set by the World Health Organization, aiming for a global prevalence rate < 1 patient in a population of 10,000, was achieved in 2000 mainly thanks to the worldwide use of leprosy drugs starting in the 1980s and their access at no cost for patients since 1995. However, around 200,000 new cases are still reported each year, particularly in India, Brazil, and Indonesia. As with other bacteria of medical interest, antimicrobial resistance is observed in Mycobacterium leprae strains in several parts of the world, despite multidrug therapy being the recommended standard leprosy treatment to avoid resistance selection since 1982. Therefore, identifying and monitoring resistance is necessary. We provide an overview of the historical facts that led to the current drug resistance situation, the antibiotics effective against M. leprae, their mechanisms of action and resistance, and resistance detection methods. We also discuss therapeutic management of the resistant cases, new genes with potential roles in drug resistance and bacterial adaptation, new drugs under investigation, and the risk for resistance selection with the chemoprophylaxis measures.

Prospective study on antimicrobial resistance in leprosy cases diagnosed in France from 2001 to 2015.

Antimicrobial resistance (AMR) in leprosy is mostly unknown because Mycobacterium leprae does not grow in vitro and bacteriologic investigations have been abandoned. However, molecular detection of resistance can be applied to multibacillary cases. Patients living in France mainland or in the French territories and diagnosed with leprosy from 2001 to 2015 were prospectively studied for AMR by detecting mutations in rpoB for rifampicin resistance, in folP1 for dapsone and in gyrA for ofloxacin. Single nucleotide polymorphism (SNP) genotypes 1-4 were determined for resistant strains. Of 334 skin biopsy samples received for suspicion of leprosy, 184 (55.1%) were positive for M. leprae (acid-fast bacilli and M. leprae-specific repetitive element PCR) corresponding to 160 multibacillary cases. AMR was detected in 18 cases (11.3%): 13 cases (8.1%) of dapsone resistance, three (1.9%) rifampicin and two (1.3%) ofloxacin. There were no strains with multidrug resistance. The mutations (numbering system of M. leprae TN strain genome) found were P55L (n = 7), T53I (n = 5), T53A (n = 1) in folP1; S456L (n = 2) and S456F (n = 1) in rpoB; and A91V (n = 2) in gyrA. Resistance proportion differ significantly between new and relapse cases (9/127, 7.0%, vs. 9/33, 25.7%, p 0.003). The frequency distribution of SNP1-4 types of resistant strains was two, one, 12 and three with five SNP3 cases from New Caledonia harbouring the same T53I FolP1 substitution. This is the first report of AMR surveillance for new and relapse cases of leprosy in Europe. Detection of resistance helped in individual treatment as well as in epidemiologic investigations.

Antimicrobial resistance in leprosy: results of the first prospective open survey conducted by a WHO surveillance network for the period 2009-15.

OBJECTIVES: Antimicrobial resistance (AMR) is a priority for surveillance in bacterial infections. For leprosy, AMR has not been assessed because Mycobacterium leprae does not grow in vitro. We aim to obtain AMR data using molecular detection of resistance genes and to conduct a prospective open survey of resistance to antileprosy drugs in countries where leprosy is endemic through a WHO surveillance network. METHODS: From 2009 to 2015, multi-bacillary leprosy cases at sentinel sites of 19 countries were studied for resistance to rifampicin, dapsone and ofloxacin by PCR sequencing of the drug-resistance-determining regions of the genes rpoB, folP1 and gyrA. RESULTS: Among 1932 (1143 relapse and 789 new) cases studied, 154 (8.0%) M. leprae strains were found with mutations conferring resistance showing 182 resistance traits (74 for rifampicin, 87 for dapsone and 21 for ofloxacin). Twenty cases showed rifampicin and dapsone resistance, four showed ofloxacin and dapsone resistance, but no cases were resistant to rifampicin and ofloxacin. Rifampicin resistance was observed among relapse (58/1143, 5.1%) and new (16/789, 2.0%) cases in 12 countries. India, Brazil and Colombia reported more than five rifampicin-resistant cases. CONCLUSIONS: This is the first study reporting global data on AMR in leprosy. Rifampicin resistance emerged, stressing the need for expansion of surveillance. This is also a call for vigilance on the global use of antimicrobial agents, because ofloxacin resistance probably developed in relation to the general intake of antibiotics for other infections as it is not part of the multidrug combination used to treat leprosy.

Consensus numbering system for the rifampicin resistance-associated rpoB gene mutations in pathogenic mycobacteria.

The rpoB gene codes for the RNA polymerase ß subunit, which is the target of rifampicin, an essential drug in the treatment of tuberculosis and other mycobacterial infections. This gene is present in all bacteria, but its length and nucleotide sequence vary between bacterial species, including mycobacteria. Mutations in the rpoB gene alter the structure of this protein and cause drug resistance. To describe the resistance-associated mutations, the scientific and medical communities have been using, since 1993, a numbering system based on the Escherichia coli sequence annotation. Using E. coli reference for describing mutations in mycobacteria leads to misunderstandings, particularly with the increasing use of whole genome sequencing, which brought an alternative numbering system based on the Mycobacterium tuberculosis rpoB sequence. We propose using a consensus numbering system for the reporting of resistance mutations based on the reference genomes from the species interrogated (such as strain H37Rv for M. tuberculosis). This manuscript provides the necessary figures and tables allowing researchers, microbiologists and clinicians to easily convert other annotation systems into one common language.

Update on the epidemiology, diagnosis, and treatment of leprosy.

Leprosy is an infectious disease that has now been reported for more than 2000 years. The leprosy elimination goal set by the World Health Organization (WHO), i.e. a global prevalence rate <1 patient per 10,000 population, was achieved in the year 2000, but more than 200,000 new case patients are still reported each year, particularly in India, Brazil, and Indonesia. Leprosy is a specific infection: (i) it is a chronic infection primarily affecting the skin and peripheral nerves, (ii) Mycobacterium leprae is one of the last bacterial species of medical interest that cannot be cultured in vitro (mainly because of its reductive genome evolution), and (iii) transmission and pathophysiological data is still limited. The various presentations of the disease (Ridley-Jopling and WHO classifications) are correlated with the patient's immune response, bacillary load, and by the delay before diagnosis. Multidrug therapy (dapsone, rifampicin, with or without clofazimine) has been recommended since 1982 as the standard treatment of leprosy; 6 months for patients presenting with paucibacillary leprosy and 12 months for patients presenting with multibacillary leprosy. The worldwide use of leprosy drugs started in the 1980s and their free access since 1995 contributed to the drastic decline in the number of new case patients. Resistant strains are however emerging despite the use of multidrug therapy; identifying and monitoring resistance is still necessary.

Correlation between quinolone susceptibility patterns and sequences in the A and B subunits of DNA gyrase in mycobacteria.

The in vitro activities of seven quinolones and the sequences of the quinolone resistance-determining regions (QRDR) in the A and B subunits of DNA gyrase were determined for 14 mycobacterial species. On the basis of quinolone activity, quinolones were arranged from that with the greatest to that with the least activity as follows: sparfloxacin, levofloxacin, ciprofloxacin, ofloxacin, pefloxacin, flumequine, and nalidixic acid. Based on MICs, the species could be organized into three groups: resistant (Mycobacterium avium, M. intracellulare, M. marinum, M. chelonae, M. abscessus [ofloxacin MICs, >/=8 microg/ml]), moderately susceptible (M. tuberculosis, M. bovis BCG, M. kansasii, M. leprae, M. fortuitum third biovariant, M. smegmatis [ofloxacin MICs, 0.5 to 1 microg/ml]), and susceptible (M. fortuitum, M. peregrinum, M. aurum [ofloxacin MICs,

Sequences of conserved region in the A subunit of DNA gyrase from nine species of the genus Mycobacterium: phylogenetic analysis and implication for intrinsic susceptibility to quinolones.

The sequences of a conserved region in the A subunit of DNA gyrase corresponding to the quinolone resistance-determining region were determined for nine mycobacterial species and were compared. Although the nucleotide sequences were highly conserved, they clearly differentiated one species from another. The results of the phylogenetic analysis based on the sequences of the quinolone resistance-determining regions were compared with those provided by the 16S rRNA sequences. Deduced amino acid sequences were identical within the nine species except for amino acid 83, which was frequently involved in acquired resistance to quinolones in many genera, including mycobacteria. The presence at position 83 of an alanine for seven mycobacterial species (M. tuberculosis, M. bovis BCG, M. leprae, M. avium, M. kansasii, M. chelonae, and M. smegmatis) and of a serine for the two remaining mycobacterial species (M. fortuitum and M. aurum) correlated well with the MICs of ofloxacin for both groups of species, suggesting the role of this residue in intrinsic susceptibility to quinolones in mycobacteria.

Amplification and nucleotide sequence of the quinolone resistance-determining region in the gyrA gene of mycobacteria.

Chromosomal DNA of different species of mycobacteria, Mycobacterium tuberculosis, Mycobacterium leprae, Mycobacterium avium and Mycobacterium smegmatis, has been submitted to polymerase chain reaction using two oligonucleotide primers highly homologous to DNA sequences flanking the quinolone resistance-determining region in the gyrA gene of Escherichia coli and Staphylococcus aureus. For each of these mycobacterial species, a 150-bp DNA fragment hybridizing with an intragenic probe of the gyrA gene of E. coli K12 was obtained. The nucleotide sequences of the 108-bp fragments amplified from M. tuberculosis and M. avium were determined. The two sequences were 87% homologous. Except for one residue, their deduced amino acid sequences were identical and shared 67% homology with the quinolone resistance-determining region of the gyrase A subunits of E. coli and S. aureus. Sequencing of the 108-bp fragment amplified from an in vitro mutant of M. avium, highly resistant to fluoroquinolones, showed a point mutation leading to the substitution of Ala for Val at a position corresponding to residues involved in quinolone resistance in E. coli and S. aureus, i.e. Ser 83 for E. coli and Ser 84 for S. aureus.