Austen R. D. Ganley

Multilocus sequence typing suggests the chytrid pathogen of amphibians is a recently emerged clone

Chytridiomycosis is a recently identified fungal disease associated with global population declines of frogs. Although the fungus, Batrachochytrium dendrobatidis, is considered an emerging pathogen, little is known about its population genetics, including the origin of the current epidemic and how this relates to the dispersal ability of the fungus. In this study, we use multilocus sequence typing to examine genetic diversity and relationships among 35 fungal strains from North America, Africa and Australia. Only five variable nucleotide positions were detected among 10 loci (5918 bp). This low level of genetic variation is consistent with the description of B. dendrobatidis as a recently emerged disease agent. Fixed (i.e. 100%) or nearly fixed frequencies of heterozygous genotypes at two loci suggested that B. dendrobatidis is diploid and primarily reproduces clonally. In contrast to the lack of nucleotide polymorphism, electrophoretic karyotyping of multiple strains demonstrated a number of chromosome length polymorphisms.

The genomes of the fungal plant pathogens Cladosporium fulvum and Dothistroma septosporum reveal adaptation to different hosts and lifestyles but also signatures of common ancestry.

We sequenced and compared the genomes of the Dothideomycete fungal plant pathogens Cladosporium fulvum (Cfu) (syn. Passalora fulva) and Dothistroma septosporum (Dse) that are closely related phylogenetically, but have different lifestyles and hosts. Although both fungi grow extracellularly in close contact with host mesophyll cells, Cfu is a biotroph infecting tomato, while Dse is a hemibiotroph infecting pine. The genomes of these fungi have a similar set of genes (70% of gene content in both genomes are homologs), but differ significantly in size (Cfu >61.1-Mb; Dse 31.2-Mb), which is mainly due to the difference in repeat content (47.2% in Cfu versus 3.2% in Dse). Recent adaptation to different lifestyles and hosts is suggested by diverged sets of genes. Cfu contains an α-tomatinase gene that we predict might be required for detoxification of tomatine, while this gene is absent in Dse. Many genes encoding secreted proteins are unique to each species and the repeat-rich areas in Cfu are enriched for these species-specific genes. In contrast, conserved genes suggest common host ancestry. Homologs of Cfu effector genes, including Ecp2 and Avr4, are present in Dse and induce a Cf-Ecp2- and Cf-4-mediated hypersensitive response, respectively. Strikingly, genes involved in production of the toxin dothistromin, a likely virulence factor for Dse, are conserved in Cfu, but their expression differs markedly with essentially no expression by Cfu in planta. Likewise, Cfu has a carbohydrate-degrading enzyme catalog that is more similar to that of necrotrophs or hemibiotrophs and a larger pectinolytic gene arsenal than Dse, but many of these genes are not expressed in planta or are pseudogenized. Overall, comparison of their genomes suggests that these closely related plant pathogens had a common ancestral host but since adapted to different hosts and lifestyles by a combination of differentiated gene content, pseudogenization, and gene regulation.

The Effect of Replication Initiation on Gene Amplification in the rDNA and Its Relationship to Aging

In eukaryotes, the ribosomal DNA (rDNA) consists of long tandem repeat arrays. These repeated genes are unstable because homologous recombination between them results in copy number loss. To maintain high copy numbers, yeast has an amplification system that works through a pathway involving the replication fork barrier site and unequal sister chromatid recombination. In this study, we show that an active replication origin is essential for amplification, and the amplification rate correlates with origin activity. Moreover, origin activity affects the levels of extrachromosomal rDNA circles (ERC) that are thought to promote aging. Surprisingly, we found that reduction in ERC level results in shorter life span. We instead show that life span correlates with rDNA stability, which is preferentially reduced in mother cells, and that episomes can induce rDNA instability. These data support a model in which rDNA instability itself is a cause of aging in yeast.

Cellular Senescence in Yeast Is Regulated by rDNA Noncoding Transcription

Genomic instability is a conserved factor in lifespan reduction, although the molecular mechanism is not known. Studies in the yeast Saccharomyces cerevisiae over the past 20 years have found a connection between the ribosomal RNA gene cluster (rDNA) and lifespan. The highly repetitive rDNA exhibits genomic instability, and the antiaging histone deacetylase gene SIR2 regulates this instability. We previously proposed that SIR2 governs lifespan by repressing rDNA noncoding transcription and rDNA instability, but the extent to which lifespan is affected by SIR2 acting at the rDNA versus other genomic regions, and the relationship between rDNA noncoding transcription/rDNA stability and lifespan have remained controversial. To control rDNA noncoding transcription and rDNA instability, we use a strain in which the rDNA noncoding promoter is replaced with an inducible promoter. Here, we show that repression of noncoding transcription extends lifespan and makes SIR2 dispensable for lifespan extension. These results indicate that Sir2 maintains lifespan through repression of E-pro noncoding transcription in the rDNA cluster, rather than pleiotropically at other loci. The observation of rDNA instability in other organisms, including humans, suggests that this may be a conserved aging pathway.

The shared genomic architecture of human nucleolar organizer regions

The short arms of the five acrocentric human chromosomes harbor sequences that direct the assembly and function of the nucleolus, one of the key functional domains of the nucleus, yet they are absent from the current human genome assembly. Here we describe the genomic architecture of these human nucleolar organizers. Sequences distal and proximal to ribosomal gene arrays are conserved among the acrocentric chromosomes, suggesting they are sites of frequent recombination. Although previously believed to be heterochromatic, characterization of these two flanking regions reveals that they share a complex genomic architecture similar to other euchromatic regions of the genome, but they have distinct genomic characteristics. Proximal sequences are almost entirely segmentally duplicated, similar to the regions bordering centromeres. In contrast, the distal sequence is predominantly unique to the acrocentric short arms and is dominated by a very large inverted repeat. We show that the distal element is localized to the periphery of the nucleolus, where it appears to anchor the ribosomal gene repeats. This, combined with its complex chromatin structure and transcriptional activity, suggests that this region is involved in nucleolar organization. Our results provide a platform for investigating the role of NORs in nucleolar formation and function, and open the door for determining the role of these regions in the well-known empirical association of nucleoli with pathology.

Monitoring the Rate and Dynamics of Concerted Evolution in the Ribosomal DNA Repeats of Saccharomyces cerevisiae Using Experimental Evolution

Concerted evolution describes the unusual evolutionary pattern exhibited by certain repetitive sequences, whereby all the repeats are maintained in the genome with very similar sequences but differ between related species. The pattern of concerted evolution is thought to result from continual turnover of repeats by recombination, a process known as homogenization. Approaches to studying concerted evolution have largely been observational because of difficulties investigating repeat evolution in an experimental setting with large arrays of identical repeats. Here, we establish an experimental evolution approach to look at the rate and dynamics of concerted evolution in the ribosomal DNA (rDNA) repeats. A small targeted mutation was made in the spacer of a single rDNA unit in Saccharomyces cerevisiae so we could monitor the fate of this unit without the need for a selectable marker. The rate of loss of this single unit was determined, and the frequency of duplication was also estimated. The results show that duplication and deletion events occur at similar rates and are very common: An rDNA unit may be gained or lost as frequently as once every cell division. Investigation of the spatial dynamics of rDNA turnover showed that when the tagged repeat unit was duplicated, the copy predominantly, but not exclusively, ended up near to the tagged repeat. This suggests that variants in the rDNA spread in a semiclustered fashion. Surprisingly, large deletions that remove a significant fraction of total rDNA repeats were frequently found. We propose these large deletions are a driving force of concerted evolution, acting to increase homogenization efficiency over-and-above that afforded by turnover of individual rDNA units. Thus, the results presented here enhance our understanding of concerted evolution by offering insights into both the spatial and temporal dynamics of the homogenization process and suggest an important new aspect in our understanding of concerted evolution.

Yeast hypertrophy: cause or consequence of aging? Reply to Bilinski et al

Bilinski et al . (2012) recently presented a provocative commentary regarding yeast longevity and hypertrophy in this journal. We are compelled, as yeast aging researchers, to present our thinking on some of the critiques presented by Bilinski et al . First, Bilinski et al . argued against the presence of an aging factor because there is little evidence for a ‘soluble, diffusible, and degradable’ factor promoting aging. While perhaps originally defined as such, we consider an ‘aging factor’ to be something that incrementally attenuates lifespan, accumulates in mothers, and is (largely) not passed onto daughters. Thus, yeast hypertrophy, as proposed by Bilinski et al ., fits this definition. Bilinski et al . also note that yeast hypertrophy is usually ignored in articles proposing putative aging factors. While an explicit link between hypertrophy and these aging …

Biochar in Co-Contaminated Soil Manipulates Arsenic Solubility and Microbiological Community Structure, and Promotes Organochlorine Degradation

We examined the effect of biochar on the water-soluble arsenic (As) concentration and the extent of organochlorine degradation in a co-contaminated historic sheep-dip soil during a 180-d glasshouse incubation experiment. Soil microbial activity, bacterial community and structure diversity were also investigated. Biochar made from willow feedstock (Salix sp) was pyrolysed at 350 or 550°C and added to soil at rates of 10 g kg-1 and 20 g kg-1 (representing 30 t ha-1 and 60 t ha-1). The isomers of hexachlorocyclohexane (HCH) alpha-HCH and gamma-HCH (lindane), underwent 10-fold and 4-fold reductions in concentration as a function of biochar treatment. Biochar also resulted in a significant reduction in soil DDT levels (P < 0.01), and increased the DDE:DDT ratio. Soil microbial activity was significantly increased (P < 0.01) under all biochar treatments after 60 days of treatment compared to the control. 16S amplicon sequencing revealed that biochar-amended soil contained more members of the Chryseobacterium, Flavobacterium, Dyadobacter and Pseudomonadaceae which are known bioremediators of hydrocarbons. We hypothesise that a recorded short-term reduction in the soluble As concentration due to biochar amendment allowed native soil microbial communities to overcome As-related stress. We propose that increased microbiological activity (dehydrogenase activity) due to biochar amendment was responsible for enhanced degradation of organochlorines in the soil. Biochar therefore partially overcame the co-contaminant effect of As, allowing for enhanced natural attenuation of organochlorines in soil.

The Case of the Missing Ancient Fungal Polyploids

Polyploidy—the increase in the number of whole chromosome sets—is an important evolutionary force in eukaryotes. Polyploidy is well recognized throughout the evolutionary history of plants and animals, where several ancient events have been hypothesized to be drivers of major evolutionary radiations. However, fungi provide a striking contrast: while numerous recent polyploids have been documented, ancient fungal polyploidy is virtually unknown. We present a survey of known fungal polyploids that confirms the absence of ancient fungal polyploidy events. Three hypotheses may explain this finding. First, ancient fungal polyploids are indeed rare, with unique aspects of fungal biology providing similar benefits without genome duplication. Second, fungal polyploids are not successful in the long term, leading to few extant species derived from ancient polyploidy events. Third, ancient fungal polyploids are difficult to detect, causing the real contribution of polyploidy to fungal evolution to be underappreciated. We consider each of these hypotheses in turn and propose that failure to detect ancient events is the most likely reason for the lack of observed ancient fungal polyploids. We examine whether existing data can provide evidence for previously unrecognized ancient fungal polyploidy events but discover that current resources are too limited. We contend that establishing whether unrecognized ancient fungal polyploidy events exist is important to ascertain whether polyploidy has played a key role in the evolution of the extensive complexity and diversity observed in fungi today and, thus, whether polyploidy is a driver of evolutionary diversifications across eukaryotes. Therefore, we conclude by suggesting ways to test the hypothesis that there are unrecognized polyploidy events in the deep evolutionary history of the fungi.

The nucleolus: a raft adrift in the nuclear sea or the keystone in nuclear structure?

Abstract The nucleolus is a prominent nuclear structure that is the site of ribosomal RNA (rRNA) transcription, and hence ribosome biogenesis. Cellular demand for ribosomes, and hence rRNA, is tightly linked to cell growth and the rRNA makes up the majority of all the RNA within a cell. To fulfill the cellular demand for rRNA, the ribosomal RNA (rDNA) genes are amplified to high copy number and transcribed at very high rates. As such, understanding the rDNA has profound consequences for our comprehension of genome and transcriptional organization in cells. In this review, we address the question of whether the nucleolus is a raft adrift the sea of nuclear DNA, or actively contributes to genome organization. We present evidence supporting the idea that the nucleolus, and the rDNA contained therein, play more roles in the biology of the cell than simply ribosome biogenesis. We propose that the nucleolus and the rDNA are central factors in the spatial organization of the genome, and that rapid alterations in nucleolar structure in response to changing conditions manifest themselves in altered genomic structures that have functional consequences. Finally, we discuss some predictions that result from the nucleolus having a central role in nuclear organization.