Identification of Cryptic Species of Four Candida Complexes in a Culture Collection.

Candida spp. are one of the most common causes of fungal infections worldwide. The taxonomy of Candida is controversial and has undergone recent changes due to novel genetically related species. Therefore, some complexes of cryptic species have been proposed. In clinical settings, the correct identification of Candida species is relevant since some species are associated with high resistance to antifungal drugs and increased virulence. This study aimed to identify the species of four Candida complexes (C. albicans, C. glabrata, C. parapsilosis, and C. haemulonii) by molecular methods. This is the first report of six cryptic Candida species in Honduras: C. dubliniensis, C. africana, C. duobushaemulonii, C. orthopsilosis, and C. metapsilosis, and it is also the first report of the allele hwp1-2 of C. albicans sensu stricto. It was not possible to demonstrate the existence of C. auris among the isolates of the C. haemulonii complex. We also propose a simple method based on PCR-RFLP for the discrimination of the multi-resistant pathogen C. auris within the C. haemulonii complex.

Identification of Candida Species from Clinical Samples in a Honduran Tertiary Hospital.

Candida species are one of the most important causes of human infections, especially in hospitals and among immunocompromised patients. The correct and rapid etiological identification of yeast infections is important to provide adequate therapy, reduce mortality, and control outbreaks. In this study, Candida species were identified in patients with suspected fungal infection, and phenotypic and genotypic identification methods were compared. A total of 167 axenic fungal cultures and 46 clinical samples were analyzed by HardyCHROM®, MicroScan®(Omron Microscan Systems Inc, Renton, WA, USA), and PCR-RFLP (Restriction Fragment Length Polymorphisms). The species of the C. albicans complex were the most frequent, followed by C. tropicalis and C. glabrata. Less common but clinically relevant species of Candida were also isolated. The comparison between the three methods was concordant, especially for the most common Candida species. Fungal DNA amplification was successful in all clinical samples.

Design and validation of an H5 TaqMan real-time one-step reverse transcription-PCR and confirmatory assays for diagnosis and verification of influenza A virus H5 infections in humans.

Increasing diversity among influenza H5N1 viruses has resulted in the need for sensitive and specific diagnostic assays, fully validated for the detection of H5 viruses belonging to all hemagglutinin (HA) clades, particularly the recently circulating H5N1 viruses of clade 2. In this report, the development and validation of a real-time, one-step TaqMan reverse transcription-PCR (RT-PCR) assay specific for the detection of influenza A H5 viruses from clades 1, 1', 2, and 3 is described. The real-time assay for H5 virus was shown to be highly sensitive, detecting H5 virus levels of <1 PFU from each of the HA clades. Specificity of the H5 RT-PCR for influenza A H5 viruses was demonstrated by using influenza A viruses of different subtypes, clinical samples containing influenza A viruses H1N1, H3N2, and H5N1, influenza B viruses, and other respiratory viruses. The usefulness of the inclusion of a distinguishable assay positive control and of confirmatory assays for the laboratory diagnosis and verification of H5 virus infections was demonstrated. A real-time RT-PCR pyrosequencing assay, a restriction enzyme digestion assay, and direct sequencing of the H5 real-time RT-PCR amplicon were validated for the confirmation of H5 detection by the diagnostic real-time assay. The H5 real-time assay was applied to diagnostic testing for suspected cases of influenza A virus H5 infection in the United Kingdom. Influenza A H5 viruses were not detected in the cases analyzed; however, influenza A H3N2 virus was detected in 57% of the suspected cases of H5. The H5 TaqMan real-time RT-PCR and confirmatory assays will be useful tools for the laboratory surveillance and rapid diagnosis of H5 infections in humans.

Evaluation of the Roche LightCycler parvovirus B19 quantification kit for the diagnosis of parvovirus B19 infections.

BACKGROUND: The rapid and quantitative detection of viral DNA is important in the diagnosis of parvovirus B19 infection in immunocompromised patients and in congenital infection. It is also valuable for monitoring progress following therapeutic interventions. OBJECTIVES: To evaluate the diagnostic sensitivity and specificity of the Roche LightCycler (LC) parvovirus B19 quantification kit in comparison with previously described nested PCR and dot blot hybridisation assays. STUDY DESIGN: Two hundred and twenty eight clinical samples and two standard B19 DNA sera were tested to assess the diagnositic performance of the Roche LC kit. RESULTS: Ten clinical samples (4.3%) gave invalid LC results, including three of five bone marrow samples but only two of 165 serum samples. In the remaining 218 samples, the LC assay detected B19 DNA in 97.5% (79/81) samples that were positive by the nested PCR. The two samples (from the same patient) that were LC negative were sequenced in a 511-nucleotide region of the NS gene and 42 nucleotide changes were found. The Roche LC assay detected B19 DNA in 9.5% (13/137) samples that were negative by nested PCR. Analysis of the available clinical and serological data associated with these samples suggested that the LC results in the majority of these cases were true positive. In patients with resolving persistent infection, the LC assay remained positive for longer than nested PCR. CONCLUSIONS: The Roche LC assay was more sensitive than the nested PCR used in this study. The additional sensitivity and the quantitative DNA measurements were valuable for monitoring patients with persistent B19 infection. Practical advantages of the LC assay include a short running time and the possibility to automate the assay. The LC assay provides a controlled and standardised method for quantitative detection of viral DNA for the diagnosis and monitoring of parvovirus B19 infections but failed to detect a variant strain.