Zofia Bakuła

Screening for Streptomycin Resistance-Conferring Mutations in Mycobacterium tuberculosis Clinical Isolates from Poland

Currently, mutations in three genes, namely rrs, rpsL, and gidB, encoding 16S rRNA, ribosomal protein S12, and 16S rRNA-specific methyltransferase, respectively, are considered to be involved in conferring resistance to streptomycin (STR) in Mycobacterium tuberculosis. The aim of this study was to investigate the spectrum and frequency of these mutations in M. tuberculosis clinical isolates, both resistant and susceptible to STR. Sixty-four M. tuberculosis isolates recovered from as many TB patients from Poland in 2004 were included in the study. Within the sample were 50 multidrug-resistant (32 STR-resistant and 18 STR-susceptible) and 14 pan-susceptible isolates. Preliminary testing for STR resistance was performed with the 1% proportion method. The MICs of STR were determined by the Etest method. Mutation profiling was carried out by amplifying and sequencing the entire rrs, rpsL, and gidB genes. Non-synonymous mutations in either rrs or rpsL gene were detected in 23 (71.9%) of the STR-resistant and none of the STR-susceptible isolates. Mutations in the gidB gene were distributed among 12 (37.5%) STR-resistant and 13 (40.6%) STR-susceptible isolates. Four (12.5%) STR-resistant isolates were wild-type at all three loci examined. None of the rrs, rpsL or gidB mutations could be linked to low, intermediate or high level of STR resistance. In accordance with previous findings, the gidB 47T→G (L16R) mutation was associated with the Latin American-Mediterranean genotype family, whereas 276A→C (E92D) and 615A→G (A205A) mutations of the gidB gene were associated with the Beijing lineage. The study underlines the usefulness of rrs and rpsL mutations as molecular markers for STR resistance yet not indicative of its level. The gidB polymorphisms can serve as phylogenetic markers.

Detection of mutations associated with isoniazid resistance in multidrug-resistant Mycobacterium tuberculosis clinical isolates

OBJECTIVES To determine the prevalence of isoniazid resistance-conferring mutations among multidrug-resistant (MDR) isolates of Mycobacterium tuberculosis from Poland. METHODS Nine genetic loci, including structural genes (katG, inhA, ahpC, kasA, ndh, nat and mshA) and regulatory regions (i.e. the mabA-inhA promoter and oxyR-ahpC intergenic region) of 50 MDR M. tuberculosis isolates collected throughout Poland were PCR-amplified in their entirety and screened for mutations by direct sequencing methodology. RESULTS Forty-six (92%) MDR M. tuberculosis isolates had mutations in the katG gene, and the katG Ser315Thr substitution predominated (72%). Eight (16%) isolates (six with a mutated katG allele) had mutations in the inhA promoter region and two such isolates also had single inhA structural gene mutations. Mutations in the oxyR-ahpC locus were found in five (10%) isolates, of which all but one had at least one additional mutation in katG. Mutations in the remaining genetic loci (kasA, ndh, nat and mshA) were detected in 12 (24%), 4 (8%), 5 (10%) and 17 (34%) MDR isolates, respectively. All non-synonymous mutants for these genes harboured mutations in katG. One isolate had no mutations in any of the analysed loci. CONCLUSIONS This study accentuates the usefulness of katG and inhA promoter mutations as predictive markers of isoniazid resistance. Testing only for katG 315 and inhA -15 mutations would detect isoniazid resistance in 84% of the MDR M. tuberculosis sample. This percentage would increase to 96% if the sequence analysis was extended to the entire katG gene. Analysis of the remaining genetic loci did not contribute greatly to the identification of isoniazid resistance.

Mutations in the embB Gene and Their Association with Ethambutol Resistance in Multidrug-Resistant Mycobacterium tuberculosis Clinical Isolates from Poland

Ethambutol (EMB) continues to be used as part of a standard drug regimen for the treatment of tuberculosis (TB). Mutations in the embB gene and those within its conserved EMB resistance determining region (ERDR) in particular have repeatedly been associated with resistance to EMB in Mycobacterium tuberculosis. The aim of this study was to examine the mutational “hot spots” in the embB gene, including the ERDR, among multidrug-resistant (MDR) M. tuberculosis clinical isolates and to find a possible association between embB mutations and resistance to EMB. An 863-bp fragment of the embB gene was sequenced in 17 EMB-resistant and 33 EMB-susceptible MDR-TB isolates. In total, eight embB mutation types were detected in 6 distinct codons of 27 (54%) M. tuberculosis isolates. Mutations in codon 306 were most common, found in both EMB-resistant (9) and EMB-susceptible (11) isolates. Only mutations in codons 406 and 507 were found exclusively in four and one EMB-resistant isolates, respectively. Sequence analysis of the ERDR in the embB gene is not sufficient for rapid detection of EMB resistance, and the codon 306 mutations are not good predictive markers of resistance to EMB.

Short Communication: Subtyping of Mycobacterium kansasii by PCR-Restriction Enzyme Analysis of the hsp65 Gene

Mycobacterium kansasii is one of the most common causes of pulmonary disease resulting from nontuberculous mycobacteria (NTM). It is also the most frequently isolated NTM species from clinical specimens in Poland. The aim of this study was to investigate the distribution of M. kansasii subtypes among patients suspected of having pulmonary NTM disease. Fifty clinical isolates of M. kansasii recovered from as many patients with suspected mycobacterial lung disease between 2000 and 2010 in Poland were genotyped by PCR-restriction enzyme analysis (PCR-REA) of partial hsp65 gene. Mycobacterium kansasii subtype I was the only genotype to be identified among the isolates, both disease-associated and non-disease-associated. Isolation of M. kansasii subtype I from clinical specimens may be indicative of infection but may also merely represent colonization.

Molecular taxonomy of scopulariopsis-like fungi with description of new clinical and environmental species.

The taxonomy of scopulariopsis-like fungi, comprising numerous human opportunistic species, has recently been reassessed with delineation of the genera Microascus, Pithoascus, Pseudoscopulariopsis, and Scopulariopsis, using morphological data and multilocus sequence analysis based on four loci (ITS, LSU, EF-1α, and TUB). In this study, the same genetic markers were used to investigate a set of clinical and environmental isolates, morphologically identified as Microascus and Scopulariopsis spp. The ingroups of the concatenated phylogenetic tree resolved 41 species clades, with isolates distributed in four main lineages corresponding to the genera Microascus, Pithoascus, Scopulariopsis, and newly established genus Fuscoannellis, typified by Scopulariopsis carbonaria. The new species Microascus chinensis, Microascus onychoides, Microascus pseudolongirostris, Pithoascus lunatus, and Scopulariopsis macurae were described. Microascus trigonosporus var. terreus and Scopulariopsis alboflavescens were found different from M. trigonosporus and Scopulariopsis brevicaulis, respectively. All the species identified in the study, except Fuscoannellis carbonaria and S. macurae, originated from clinical samples, suggesting their potential role in human disease. The use of a four marker combination was demonstrated an efficient and reliable approach to infer phylogenetic relationships among the scopulariopsis-like fungi. Yet, the only genetic marker able to discriminate all species was EF-1α, therefore proposed as a secondary barcode for the identification of these fungi.

Mutation profiling for detection of isoniazid resistance in Mycobacterium tuberculosis clinical isolates

OBJECTIVES Progress in the detection of drug-resistant TB has been underpinned by the development and implementation of new, reliable and rapid diagnostic tools. These rely mostly on the detection of specific mutations conferring resistance to anti-TB drugs. The aim of this study was to search for mutations associated with isoniazid resistance among Mycobacterium tuberculosis clinical isolates. METHODS A collection of 150 M. tuberculosis strains, including 50 MDR, 50 isoniazid-monoresistant and 50 pan-susceptible strains, was used. For all the strains, seven structural genes (katG, inhA, ahpC, kasA, ndh, nat and mshA) and two regulatory regions (mabA-inhA promoter and oxyR-ahpC intergenic region) were PCR amplified and sequenced in their entirety. RESULTS Sixty-six distinct mutations were detected at all nine loci investigated, accounting for 109 (72.7%) of the strains tested. The number of strains with any mutation among the MDR, isoniazid-monoresistant and pan-susceptible groups was 49 (98%), 37 (74%) and 23 (46%), respectively. Mutations in the katG gene predominated, with 29 different types distributed among 46 (92%) MDR, 31 (62%) isoniazid-monoresistant and 2 (4%) pan-susceptible strains. Twenty-nine and 19 mutations were found exclusively in MDR and isoniazid-monoresistant strains, respectively. CONCLUSIONS This study revealed 17 mutations, previously unreported, that might be of potential use as new surrogate markers of isoniazid resistance. Their diagnostic accuracy needs to be confirmed on larger strain samples and from different geographical settings. For isoniazid resistance detection, molecular approaches should still be a complement to rather than a replacement for conventional drug susceptibility testing. This is supported by the lack of mutations in any of the nine genetic loci investigated in 18 isoniazid-resistant strains from this study.

Proposal of a new method for subtyping of Mycobacterium kansasii based upon PCR restriction enzyme analysis of the tuf gene

Within this study, a new, rapid method for subtyping of Mycobacterium kansasii was developed based on the sequence analysis of the tuf gene coding for the Tu (thermo-unstable) elongation factor (EF-Tu). The method involves PCR amplification of ca. 740-bp tuf gene fragment, followed by digestion with the MvaI restriction endonuclease.

Draft Genome Sequences of Mycobacterium kansasii Strains 1010001454, 1010001458, 1010001468, 1010001493, 1010001495, and 1010001469, Isolated from Environmental Sources.

ABSTRACT Mycobacterium kansasii belongs to the nontuberculous mycobacteria (NTM) and causes opportunistic infections with both pulmonary and extrapulmonary manifestations. Here, we report the draft genome sequences of six environmental M. kansasii strains, designated 1010001495 (type I), 1010001469 (type II), 1010001468 (type III), 1010001458 (type IV), 1010001454 (type V), and 1010001493 (type V), originally isolated in five different European countries.

Evaluation of genotype MTBDRplus assay for rapid detection of isoniazid and rifampicin resistance in Mycobacterium tuberculosis clinical isolates from Pakistan

Background: GenoType MTBDRplus is a molecular assay for detection of Mycobacterium tuberculosis resistance to isoniazid (INH) and rifampicin (RMP), the two major anti-tuberculosis (TB) drugs. Identification of INH resistance is largely based on the occurrence of mutations in the katG gene, coding for the catalase-peroxidase, or in the promoter region of the inhA gene, coding for the NADH-dependent enoyl-ACP reductase. For testing the RMP resistance, mutations in the rpoB gene, coding for the RNA polymerase β subunit, particularly in the RMP resistance determining region (RRDR) of the gene are investigated. The GenoType MTBDRplus assay has been validated in several countries. The aim of this study was to evaluate the ability of the assay to detect INH and RMP resistance among strains of M. tuberculosis, isolated from Pakistani TB patients, and phenotypically identified as multidrug-resistant (MDR), that is resistant to both INH and RMP. Material/methods: The study included a collection of 100 MDR M. tuberculosis strains isolated from as many Pakistani TB patients over a 9-month period (i.e. between January and September 2014). Drug susceptibility testing was performed using the standard 1% proportion method on Löwenstein-Jensen medium, with INH and RMP critical concentrations of 0.2 mg/L and 40 mg/L, respectively. Genomic DNA was extracted by the cetyl-trimethyl ammonium bromide (CTAB) method. The GenoType MTBDRplus assay (Hain Lifescience, Germany) was done following the manufacturers instructions. Results: In the katG gene, with MTBDRplus assay, a specific mutation associated with INH resistance (i.e. G944C transition, conferring Ser315Thr amino acid change) was detected in 66 (66%) of the strains. Thirty-four (34%) strains did not carry the katG mutation detected by the assay. Mutations in the mabA-inhA promoter region were detected in 10 (10%) strains (C-15T – in 10 strains, and T-8C – in 2 strains). Seventy-seven (77%) strains tested harboured a mutation in rpoB gene. Mutations in the rpoB gene were of four types: C1349T, A1304T, C1333G, and TC1324CA found in 63 (63%), 11 (11%), 8 (8%), and one (1%) strain, respectively. Of the 100 strains designated as MDR by the proportion method, GenoType MTBDRplus confirmed this phenotype in only 62 strains. The results of GenoType MTBDRplus and the conventional drug susceptibility method were consistent in 70% (70/100) for INH, and 77% (77/100) for RMP. Conclusions: As evidenced in this study, the major concern with the GenoType MTBDRplus assay were false negative results. In comparison to conventional drug susceptibility testing, the assay was unable to detect 30 (30/100; 30%) strains resistant to INH and 23 (23/100; 23%) strains resistant to RMP. The GenoType MTBDRplus failed to identify 38 MDR (38/100; 38%) strains. Resistance in those strains probably originate from mutations in other codons and/or genes than those covered by the test. For detecting INH and RMP resistance in TB cases, especially in high TB incidence countries, such as Pakistan, molecular approaches should still be a complement rather than areplacement to conventional drug susceptibility testing.

Molecular typing of Mycobacterium kansasii using pulsed-field gel electrophoresis and a newly designed variable-number tandem repeat analysis

Molecular epidemiological studies of Mycobacterium kansasii are hampered by the lack of highly-discriminatory genotyping modalities. The purpose of this study was to design a new, high-resolution fingerprinting method for M. kansasii. Complete genome sequence of the M. kansasii ATCC 12478 reference strain was searched for satellite-like repetitive DNA elements comprising tandem repeats. A total of 24 variable-number tandem repeat (VNTR) loci were identified with potential discriminatory capacity. Of these, 17 were used to study polymorphism among 67 M. kansasii strains representing six subtypes (I-VI). The results of VNTR typing were compared with those of pulsed-field gel electrophoresis (PFGE) with AsnI digestion. Six VNTRs i.e. (VNTR 1, 2, 8, 14, 20 and 23) allow to differentiate analyzed strains with the same discriminatory capacities as use of a 17-loci panel. VNTR typing and PFGE in conjunction revealed 45 distinct patterns, including 11 clusters with 33 isolates and 34 unique patterns. The Hunter-Gaston’s discriminatory index was 0.95 and 0.66 for PFGE and VNTR typing respectively, and 0.97 for the two methods combined. In conclusion, this study delivers a new typing scheme, based on VNTR polymorphism, and recommends it as a first-line test prior to PFGE analysis in a two-step typing strategy for M. kansasii.