Chytridiomycosis is an infectious disease in amphibians caused by two chytrid fungi, Batrachochytrium dendrobatidis (Bd) and Batrachochytrium salamandrivorans (Bsal), and is the worst infectious disease known in wildlife so far. Worldwide spread of the disease has caused unprecedented loss of global amphibian diversity. Although some lineages of Bd are enzootic and are not as deadly as the pandemic lineage, nearly 40% of amphibian species are still declining globally due to chytridiomycosis. Efficient surveillance and monitoring of chytridiomycosis are the immediate safeguard against rapid declines or extinctions of amphibian populations. Previous studies showed that existing diagnostic assays were not sensitive to certain Bd haplotypes like those from Korea, China, India, Japan, and Brazil and thereby, there is a need for a universal, sensitive, specific, reproducible, and affordable diagnostic assay. We designed a one-step SYBR green-based quantitative polymerase chain reaction (nSYBR qPCR) for robust detection of Bd. It amplifies an 82 base-pair segment between the 5.8S rRNA and ITS2 of the Bd genome. The primer pair was tested in-silico on 40 isolates from four known Bd lineages. Using skin swab samples of wild amphibians and cultured zoospores from Australia and Panama, we compared the clinical specificity and sensitivity of the newly described primers to the existing TaqMan-based qPCR assay. From India, we used samples which had been previously tested with Nested PCR to validate the new primer pairs. The newly described primer pair was then tested on swab samples from Anura, Caudata and Gymnophiona from India. We report widespread chytridiomycosis with varying infection loads on them. The new assay showed comparable efficiency to the TaqMan-based qPCR assay. This diagnostic assay can facilitate widespread surveillance of chytridiomycosis where it has been previously absent, which may reveal several reservoirs of the pathogen and can improve our understanding of this important wildlife disease.
Triplet nucleotide repeat (TNR) expansion has been linked to more than 40 inheritable neurological, neuromuscular and neurodegenerative disorders. Increase in copy number beyond a threshold causes further rapid expansion of the repeats, leading to instability and disease via gain/loss of function, toxic RNA products or chromosome instability. An analysis of these repeat regions across vertebrates shows that these repeats have consistently either arisen late or have increased in copy number in vertebrates, most significantly in primates and particularly in humans. Many of the known diseases have neurological basis, suggests positive selection of these repeats for neuronal function. Late occurrence of the diseases implicates a lack of negative selection. This evolutionary trade-off, a higher neuronal capability at the cost of disease susceptibility, is further supported by the observation that most of the genes associated with TNR expansion diseases have neuronal function.
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