14 research outputs found
Mycobiome of the Bat White Nose Syndrome (WNS) Affected Caves and Mines reveals High Diversity of Fungi and Local Adaptation by the Fungal Pathogen Pseudogymnoascus (Geomyces) destructans
The investigations of the bat White Nose Syndrome (WNS) have yet to provide
answers as to how the causative fungus Pseudogymnoascus (Geomyces) destructans
(Pd) first appeared in the Northeast and how a single clone has spread rapidly
in the US and Canada. We aimed to catalogue Pd and all other fungi (mycobiome)
by the culture-dependent (CD) and culture-independent (CI) methods in four
Mines and two Caves from the epicenter of WNS zoonotic. Six hundred sixty-five
fungal isolates were obtained by CD method including the live recovery of Pd.
Seven hundred three nucleotide sequences that met the definition of operational
taxonomic units (OTUs) were recovered by CI methods. Most OTUs belonged to
unidentified clones deposited in the databases as environmental nucleic acid
sequences (ENAS). The core mycobiome of WNS affected sites comprised of 46
species of fungi from 31 genera recovered in culture, and 17 fungal genera and
31 ENAS identified from clone libraries. Fungi such as Arthroderma spp.,
Geomyces spp., Kernia spp., Mortierella spp., Penicillium spp., and
Verticillium spp. were predominant in culture while Ganoderma spp., Geomyces
spp., Mortierella spp., Penicillium spp. and Trichosporon spp. were abundant is
clone libraries. Alpha diversity analyses from CI data revealed that fungal
community structure was highly diverse. However, the true species diversity
remains undetermined due to under sampling. The frequent recovery of Pd
indicated that the pathogen has adapted to WNS-afflicted habitats. Further,
this study supports the hypothesis that Pd is an introduced species. These
findings underscore the need for integrated WNS control measures that target
both bats and the fungal pathogen.Comment: 59 pages, 7figure
Clonal Genotype of Geomyces destructans among Bats with White Nose Syndrome, New York, USA
The dispersal mechanism of Geomyces destructans, which causes
geomycosis (white nose syndrome) in hibernating bats, remains unknown. Multiple
gene genealogic analyses were conducted on 16 fungal isolates from diverse sites
in New York State during 2008â2010. The results are consistent with the
clonal dispersal of a single G. destructans genotype
Antifungal Testing and High-Throughput Screening of Compound Library against Geomyces destructans, the Etiologic Agent of Geomycosis (WNS) in Bats
Bats in the northeastern U.S. are affected by geomycosis caused by the fungus Geomyces destructans (Gd). This infection is commonly referred to as White Nose Syndrome (WNS). Over a million hibernating bats have died since the fungus was first discovered in 2006 in a cave near Albany, New York. A population viability analysis conducted on little brown bats (Myotis lucifugus), one of six bat species infected with Gd, suggests regional extinction of this species within 20 years. The fungus Gd is a psychrophile (âcold lovingâ), but nothing is known about how it thrives at low temperatures and what pathogenic attributes allow it to infect bats. This study aimed to determine if currently available antifungal drugs and biocides are effective against Gd. We tested five Gd strains for their susceptibility to antifungal drugs and high-throughput screened (HTS) one representative strain with SpectrumPlus compound library containing 1,920 compounds. The results indicated that Gd is susceptible to a number of antifungal drugs at concentrations similar to the susceptibility range of human pathogenic fungi. Strains of Gd were susceptible to amphotericin B, fluconazole, itraconazole, ketoconazole and voriconazole. In contrast, very high MICs (minimum inhibitory concentrations) of flucytosine and echinocandins were needed for growth inhibition, which were suggestive of fungal resistance to these drugs. Of the1,920 compounds in the library, a few caused 50% - to greater than 90% inhibition of Gd growth. A number of azole antifungals, a fungicide, and some biocides caused prominent growth inhibition. Our results could provide a theoretical basis for future strategies aimed at the rehabilitation of most affected bat species and for decontamination of Gd in the cave environment
Novel partitivirus infection of bat white-nose syndrome (WNS) fungal pathogen pseudogymnoascus destructans links Eurasian and North American isolates
Bat White-nose Syndrome (WNS) fungus Pseudogymnoascus destructans had caused mass mortality in the North American bats. A single clone of the pathogen (Hap_1) was likely introduced in the United States while Eurasian population comprised of several haplotypes. The origin and spread of P. destructans remain enigmatic due in part to a lack of precise population markers. We searched for P. destructans mycoviruses as they are highly host-specific, and their spread could provide a window on the origin of the host fungus. We discovered a P. destructans bipartite virus PdPV-1 with two double-stranded RNA (dsRNA) segments - LS (1,683 bp) and SS (1,524 bp) with motifs similar to viral RNA-dependent RNA polymerase (RdRp) and putative capsid proteins (CPs), respectively. Both LS and SS ORFs were embedded only in the positive strand of each dsRNA segment. Sequence alignments and phylogenetic analysis suggested that both segments constitute the genome of a new virus similar to the mycoviruses in the family Partitiviridae genus Gammapartitivirus. Purified viral particles appeared as isometric virions with approximately 33 nm diameters typical of partitiviruses. A newly developed RT-PCR assay revealed that all US isolates and only a few Eurasian isolates were infected with PdPV-1. PdPV-1 was P. destructans - specific as closely related non-pathogenic fungi P. appendiculatus and P. roses tested negative. Thus, PdPV-1 establishes a link between the Eurasian and North American P. destructans. PdPV-1 could be used as an experimental tool to further investigate fungal biogeography, and the host â pathogen interactions
Novel partitivirus infection of bat white-nose syndrome (WNS) fungal pathogen pseudogymnoascus destructans links Eurasian and North American isolates
Bat White-nose Syndrome (WNS) fungus Pseudogymnoascus destructans had caused mass mortality in the North American bats. A single clone of the pathogen (Hap_1) was likely introduced in the United States while Eurasian population comprised of several haplotypes. The origin and spread of P. destructans remain enigmatic due in part to a lack of precise population markers. We searched for P. destructans mycoviruses as they are highly host-specific, and their spread could provide a window on the origin of the host fungus. We discovered a P. destructans bipartite virus PdPV-1 with two double-stranded RNA (dsRNA) segments - LS (1,683 bp) and SS (1,524 bp) with motifs similar to viral RNA-dependent RNA polymerase (RdRp) and putative capsid proteins (CPs), respectively. Both LS and SS ORFs were embedded only in the positive strand of each dsRNA segment. Sequence alignments and phylogenetic analysis suggested that both segments constitute the genome of a new virus similar to the mycoviruses in the family Partitiviridae genus Gammapartitivirus. Purified viral particles appeared as isometric virions with approximately 33 nm diameters typical of partitiviruses. A newly developed RT-PCR assay revealed that all US isolates and only a few Eurasian isolates were infected with PdPV-1. PdPV-1 was P. destructans - specific as closely related non-pathogenic fungi P. appendiculatus and P. roses tested negative. Thus, PdPV-1 establishes a link between the Eurasian and North American P. destructans. PdPV-1 could be used as an experimental tool to further investigate fungal biogeography, and the host â pathogen interactions
Phyla distribution in culture-independent (CI) clones.
<p>A) Relative proportions of different phyla of all clones; B) Relative proportions of different phyla of LSU clones; C) Relative proportions of different phyla of ITS clones. The zero percent assigned in pie chart represents clones with less than 1% relative distribution.</p
Rarefaction curves of estimated OTUs richness across bat WNS-afflicted niches environmental samples.
<p>A) LSU clones rarefaction curves analyses, cutoffsâ=â0.03, 0.05, 0.10, respectively; B) ITS clones rarefaction curves analyses, cutoffâ=â0.03.</p