PLoS ONE (Jan 2012)

Combined species identification, genotyping, and drug resistance detection of Mycobacterium tuberculosis cultures by MLPA on a bead-based array.

  • Indra Bergval,
  • Sarah Sengstake,
  • Nadia Brankova,
  • Viktoria Levterova,
  • Edgar Abadía,
  • Nino Tadumaze,
  • Nino Bablishvili,
  • Maka Akhalaia,
  • Kiki Tuin,
  • Anja Schuitema,
  • Stefan Panaiotov,
  • Elizabeta Bachiyska,
  • Todor Kantardjiev,
  • Rina de Zwaan,
  • Anita Schürch,
  • Dick van Soolingen,
  • Anja van 't Hoog,
  • Frank Cobelens,
  • Rusudan Aspindzelashvili,
  • Christophe Sola,
  • Paul Klatser,
  • Paul Klatser,
  • Richard Anthony

DOI
https://doi.org/10.1371/journal.pone.0043240
Journal volume & issue
Vol. 7, no. 8
p. e43240

Abstract

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The population structure of Mycobacterium tuberculosis is typically clonal therefore genotypic lineages can be unequivocally identified by characteristic markers such as mutations or genomic deletions. In addition, drug resistance is mainly mediated by mutations. These issues make multiplexed detection of selected mutations potentially a very powerful tool to characterise Mycobacterium tuberculosis. We used Multiplex Ligation-dependent Probe Amplification (MLPA) to screen for dispersed mutations, which can be successfully applied to Mycobacterium tuberculosis as was previously shown. Here we selected 47 discriminative and informative markers and designed MLPA probes accordingly to allow analysis with a liquid bead array and robust reader (Luminex MAGPIX technology). To validate the bead-based MLPA, we screened a panel of 88 selected strains, previously characterised by other methods with the developed multiplex assay using automated positive and negative calling. In total 3059 characteristics were screened and 3034 (99.2%) were consistent with previous molecular characterizations, of which 2056 (67.2%) were directly supported by other molecular methods, and 978 (32.0%) were consistent with but not directly supported by previous molecular characterizations. Results directly conflicting or inconsistent with previous methods, were obtained for 25 (0.8%) of the characteristics tested. Here we report the validation of the bead-based MLPA and demonstrate its potential to simultaneously identify a range of drug resistance markers, discriminate the species within the Mycobacterium tuberculosis complex, determine the genetic lineage and detect and identify the clinically most relevant non-tuberculous mycobacterial species. The detection of multiple genetic markers in clinically derived Mycobacterium tuberculosis strains with a multiplex assay could reduce the number of TB-dedicated screening methods needed for full characterization. Additionally, as a proportion of the markers screened are specific to certain Mycobacterium tuberculosis lineages each profile can be checked for internal consistency. Strain characterization can allow selection of appropriate treatment and thereby improve treatment outcome and patient management.