Rapid macrolide and amikacin resistance testing for Mycobacterium abscessus in people with cystic fibrosis.

Introduction. Mycobacterium abscessus complex (MABSC) is an environmental organism and opportunistic pathogen. MABSC pulmonary infections in people with cystic fibrosis are of growing clinical concern. Resistance data guide the use of macrolides and amikacin in MABSC pulmonary disease treatment. MABSC can acquire resistance against macrolides or amikacin via 23S or 16S rRNA gene mutations, respectively.Gap Statement. Current culture-based methods for MABSC detection and antibiotic resistance characterization are typically prolonged, limiting their utility to directly inform treatment or clinical trials. Culture-independent molecular methods may help address this limitation.Aim. To develop real-time PCR assays for characterization of key 23S or 16S rRNA gene mutations associated with constitutive resistance in MABSC.Methodology. We designed two real-time PCR assays to detect the key 23S and 16S rRNA gene mutations. The highly conserved nature of rRNA genes was a major design challenge. To reduce potential cross-reactivity, primers included non-template bases and targeted single-nucleotide polymorphisms unique to MABSC. We applied these assays, as well as a previously developed real-time PCR assay for MABSC detection, to 968 respiratory samples from people with cystic fibrosis. The results from the molecular methods were compared to those for gold standard culture methods and 23S and 16S rRNA gene sequencing.Results.The real-time PCR MABSC detection assay provided a sensitivity of 83.8 % and a specificity of 97.8 % compared to culture. The results from the real-time PCR resistance detection assays were mostly concordant (>77.4 %) with cultured isolate sequencing. The real-time PCR resistance detection assays identified several samples harbouring both resistant and susceptible MABSC, while culture-dependent methods only identified susceptible MABSC in these samples.Conclusion. Using the molecular methods described here, results for health care providers or researchers could be available days or weeks earlier than is currently possible via culture-based antibiotic susceptibility testing.

Infectivity of Plasmodium falciparum in Malaria-Naive Individuals Is Related to Knob Expression and Cytoadherence of the Parasite.

Plasmodium falciparum is the most virulent human malaria parasite because of its ability to cytoadhere in the microvasculature. Nonhuman primate studies demonstrated relationships among knob expression, cytoadherence, and infectivity. This has not been examined in humans. Cultured clinical-grade P. falciparum parasites (NF54, 7G8, and 3D7B) and ex vivo-derived cell banks were characterized. Knob and knob-associated histidine-rich protein expression, CD36 adhesion, and antibody recognition of parasitized erythrocytes (PEs) were evaluated. Parasites from the cell banks were administered to malaria-naive human volunteers to explore infectivity. For the NF54 and 3D7B cell banks, blood was collected from the study participants for in vitro characterization. All parasites were infective in vivo However, infectivity of NF54 was dramatically reduced. In vitro characterization revealed that unlike other cell bank parasites, NF54 PEs lacked knobs and did not cytoadhere. Recognition of NF54 PEs by immune sera was observed, suggesting P. falciparum erythrocyte membrane protein 1 expression. Subsequent recovery of knob expression and CD36-mediated adhesion were observed in PEs derived from participants infected with NF54. Knobless cell bank parasites have a dramatic reduction in infectivity and the ability to adhere to CD36. Subsequent infection of malaria-naive volunteers restored knob expression and CD36-mediated cytoadherence, thereby showing that the human environment can modulate virulence.

Screening for H7N9 influenza A by matrix gene-based real-time reverse-transcription PCR.

Rapid detection of novel influenza A strains, including H7N9, is pivotal to ensuring appropriate public health-based responses and real-time reverse-transcription polymerase chain reaction (RT-PCR) methods are used typically for this purpose. However, the utility of such methods can be undermined by ongoing sequence variations, particularly when targeting the variable influenza A haemagglutinin (HA) and neuraminidase (NA) genes. This may often be a source of frustration for clinical laboratories that are implementing methods in preparation for potential pandemics as primers and probe targets may need to be checked regularly and updated. In this study, screening methods were developed for H7N9 influenza A strains based on the highly-conserved influenza A matrix gene. Three assays were developed and evaluated in parallel, and included two methods which simply involved inclusion of a single H7N9 probe sequence into an established influenza A and B multiplex RT-PCR (FluAB-PCR). The detection limits of the methods were compared using ten-fold dilutions of H7N9 RNA, and the specificity of the methods were tested using 32 influenza A RT-PCR-positive samples and a panel of 18 influenza A isolates, including representives of seasonal H3N2, seasonal H1N1, pandemic H1N1, H5N1, H5N3, H9N2 and H7N7. The detection limits of the three methods were the same, and no cross-reactions were observed with sH3N2, sH1N1, pH1N1 or H5N1. However, cross-reactions were observed with H5N3, H9N2 and H7N7. Overall, the results show that the methods are useful for front-line screening for H7N9.