Rapid Evolution of Pandemic Noroviruses of the GII.4 Lineage

Over the last fifteen years there have been five pandemics of norovirus (NoV) associated gastroenteritis, and the period of stasis between each pandemic has been progressively shortening. NoV is classified into five genogroups, which can be further classified into 25 or more different human NoV genotypes; however, only one, genogroup II genotype 4 (GII.4), is associated with pandemics. Hence, GII.4 viruses have both a higher frequency in the host population and greater epidemiological fitness. The aim of this study was to investigate if the accuracy and rate of replication are contributing to the increased epidemiological fitness of the GII.4 strains. The replication and mutation rates were determined using in vitro RNA dependent RNA polymerase (RdRp) assays, and rates of evolution were determined by bioinformatics. GII.4 strains were compared to the second most reported genotype, recombinant GII.b/GII.3, the rarely detected GII.3 and GII.7 and as a control, hepatitis C virus (HCV). The predominant GII.4 strains had a higher mutation rate and rate of evolution compared to the less frequently detected GII.b, GII.3 and GII.7 strains. Furthermore, the GII.4 lineage had on average a 1.7-fold higher rate of evolution within the capsid sequence and a greater number of non-synonymous changes compared to other NoVs, supporting the theory that it is undergoing antigenic drift at a faster rate. Interestingly, the non-synonymous mutations for all three NoV genotypes were localised to common structural residues in the capsid, indicating that these sites are likely to be under immune selection. This study supports the hypothesis that the ability of the virus to generate genetic diversity is vital for viral fitness.     

Structural Evolution of the Emerging 2014-2015 GII.17 Noroviruses

Recent reports suggest that human genogroup II genotype 17 (GII.17) noroviruses are increasing in prevalence. We analyzed the evolutionary changes of three GII.17 capsid protruding (P) domains. We found that the GII.17 P domains had little cross-reactivity with antisera raised against the dominant GII.4 strains. X-ray structural analysis of GII.17 P domains from 2002 to 2014 and 2015 suggested that surface-exposed substitutions on the uppermost part of the P domain might have generated a novel 2014-2015 GII.17 variant.     

The Evolutionary Advantage of Recombination. II. Individual Selection for Recombination

Based on the Fisher-Muller theory of the evolution of recombination, an argument can be constructed predicting that a recessive allele favoring recombination will be favored, if there are either favorable or deleterious mutants occurring at other loci. In this case there is no clear distinction between individual and group selection. Computer simulation of populations segregating for recessive or dominant recombination alleles showed selection favoring recombination, except in the case of a dominant recombination allele with deleterious background mutants. The relationship of this work to parallel investigations by Williams and by Strobeck, Maynard Smith, and Charlesworth is explored. All seem to rely on the same phenomenon. There seems no reason to assume that the evolution of recombination must have occurred by group selection.     

Comparative Analysis of Miscanthus and Saccharum Reveals a Shared Whole-Genome Duplication but Different Evolutionary Fates

Multiple polyploidizations with divergent consequences in the grass subtribeSaccharinae provide a singular opportunity to study in situ adaptation of a genome tothe duplicated state, heretofore known primarily from paleogenomics. We show thatallopolyploidy in a common Miscanthus-Saccharumancestor ∼3.8 to 4.6 million years ago closely coincides in time with theirdivergence from the Sorghum lineage. SubsequentSaccharum-specific autopolyploidy may have createdpseudo-paralogous chromosome groups with random pairing within a group but infrequentpairing between groups. High chromosome number may reduce differentiation amongSaccharum pseudo-paralogs by increasing opportunities forrecombinations, with the lower chromosome numbers of Miscanthusfavoring the return to disomic inheritance. The widespread tendency of plantchromosome numbers to recursively return to a narrow range following genomeduplication appears to be occurring now in Saccharum spontaneumbased on rich polymorphism for chromosome number among genotypes, with pastreductions indicated by condensations of two ancestral chromosomes inMiscanthus (now n = 19) and perhaps as many as10 in the Narenga-Sclerostachya clade (n = 15).     

Complete Genome Sequence of a Novel H9N2 Subtype Influenza Virus FJG9 Strain in China Reveals a Natural Reassortant Event

A/chicken/FJ/G9/09 (FJ/G9) is an H9N2 subtype avian influenza virus (H9N2 AIV) strain causing high morbidity that was isolated from broilers in Fujian Province of China in 2009. FJ/G9 has been used as the vaccine strain against H9N2 AIV infection in Fujian Province of China. Here, we report the complete genome sequence of FJ/G9 with natural six-way reassortment, which is the most complex genotype strain in China and even in the world so far. The present findings will aid in understanding the complexity and diversity of H9N2 subtype avian influenza virus.     

Novel Glutaredoxin Activity of the Yeast Prion Protein Ure2 Reveals a Native-like Dimer within Fibrils

Ure2 is the protein determinant of the Saccharomyces cerevisiae prion [URE3]. Ure2 has structural similarity to glutathione transferases, protects cells against heavy metal and oxidant toxicity in vivo, and shows glutathione-dependent peroxidase activity in vitro. Here we report that Ure2 (which has no cysteine residues) also shows thiol-disulfide oxidoreductase activity similar to that of glutaredoxin enzymes. This demonstrates that disulfide reductase activity can be independent of the classical glutaredoxin CXXC/CXXS motif or indeed an intrinsic catalytic cysteine residue. The kinetics of the glutaredoxin activity of Ure2 showed positive cooperativity for the substrate glutathione in both the soluble native state and in amyloid-like fibrils, indicating native-like dimeric structure within Ure2 fibrils. Characterization of the glutaredoxin activity of Ure2 sheds light on its ability to protect yeast from heavy metal ion and oxidant toxicity and suggests a role in reversible protein glutathionylation signal transduction. Observation of allosteric enzyme behavior within amyloid-like Ure2 fibrils not only provides insight into the molecular structure of the fibrils but also has implications for the mechanism of [URE3] prion formation.The tripeptide glutathione (GSH)² is abundant in the cell. It plays an important role as a reducing agent in vivo, such as in endogenous free radical scavenging, reversible protein S-glutathionylation, and the reduction of the active sites of enzymes. One major class of enzyme that uses GSH as a reductant is glutaredoxin (GRX), which is a small protein involved in reduction of ribonucleotide reductase for the formation of deoxyribonucleotides for DNA synthesis (1), reduction of 3′-phosphoadenylylsulfate reductase (2) for generation of sulfite, signal transduction, and protection against oxidative stress (3). GRXs are ubiquitous thiol-disulfide oxidoreductases that belong to the thioredoxin superfamily (4). GRXs also show dehydroascorbic acid (DHA) reductase (DHAR) activity (5). Yeast Saccharomyces cerevisiae has at least seven GRXs, which can be divided into two classes according to the number of cysteines in their active site motif: dithiol GRXs with the active site motif CXXC and monothiol GRXs with the motif CXXS (6–9). The dithiol GRXs catalyze protein disulfide reduction using a dithiol mechanism for which both the active site cysteines are essential. On the other hand, both the dithiol and monothiol GRXs can catalyze the reduction of GSH-protein mixed disulfides using a monothiol mechanism that only requires the N-terminal active site cysteine. This reaction and mechanism is important for reversible protein glutathionylation in redox signaling and oxidative stress (10).Glutathione S-transferases (GSTs) are a large versatile family of enzymes with multiple functions, particularly associated with cellular detoxification (11). In terms of overall structure, they belong to the thioredoxin superfamily, like GRX (4). In general, GSTs catalyze the conjugation of reduced GSH to hydrophobic substrates containing an electrophilic atom. In addition, GSTs bind a broad spectrum of ligands and show many other functions. For example, some GSTs show overlapping functions with glutathione-dependent peroxidases (GPxs), which use GSH to reduce hydrogen peroxide and/or organic hydroperoxides and thus are responsible for protection against both endogenous and exogenous oxidant toxicity (11). Interestingly Omega class and Beta class GSTs (such as Escherichia coli GST (EGST)) possess typical GRX activity toward widely used substrates, such as 2-hydroxyethyl disulfide (HEDS) (12–16). These GSTs have an active site cysteine, which is indispensable for GRX activity but not GST activity.The yeast prion protein Ure2 is composed of a disordered protease-sensitive N-terminal prion domain and a compact globular C-terminal domain, which shows high structural similarity to EGST (17). The C-terminal domain of Ure2 can be further structurally divided into two subdomains, the all-α-helix subdomain and the thioredoxin fold subdomain, which shows high structural homology to GRX. Ure2 is involved in the regulation of nitrogen metabolism and resistance to heavy metal ion toxicity (especially cadmium) and oxidative stress in S. cerevisiae (18, 19). In addition, Ure2 shows GPx activity toward both hydrogen peroxide and organic hydroperoxides such as cumene hydroperoxide and tert-butyl hydroperoxide (20). The discovery of the GPx activity of Ure2 (20) provides an explanation for its ability to protect yeast cells from oxidant toxicity (18). However, the reason that ure2Δ yeast cells are hypersensitive to cadmium remains unclear. In general, cadmium ions have a drastic effect on yeast cell growth, and the reasons are complicated. One possible reason for cadmium ion toxicity is that thioltransferases or GRXs can be inhibited by direct binding of cadmium to the two essential cysteine residues present in the thioltransferase active site (21). The inhibition of GRXs leads to complex effects on cell growth. Therefore, we used an in vitro assay to provide a system that allows detailed analysis of the activity of Ure2 and its relationship to that of GRX enzymes. Characterization of the allosteric behavior of the GRX activity of Ure2 revealed that Ure2 forms an active dimer within fibrils. In addition to providing information about the molecular structure of Ure2 fibrils, this also has implications for the molecular mechanism of Ure2 prion formation.     

Characterization of Novel Phages Isolated in Coagulase-Negative Staphylococci Reveals Evolutionary Relationships with Staphylococcus aureus Phages

Despite increasing interest in coagulase-negative staphylococci (CoNS), little information is available about their bacteriophages. We isolated and sequenced three novel temperate Siphoviridae phages (StB12, StB27, and StB20) from the CoNS Staphylococcus hominis and S. capitis species. The genome sizes are around 40 kb, and open reading frames (ORFs) are arranged in functional modules encoding lysogeny, DNA metabolism, morphology, and cell lysis. Bioinformatics analysis allowed us to assign a potential function to half of the predicted proteins. Structural elements were further identified by proteomic analysis of phage particles, and DNA-packaging mechanisms were determined. Interestingly, the three phages show identical integration sites within their host genomes. In addition to this experimental characterization, we propose a novel classification based on the analysis of 85 phage and prophage genomes, including 15 originating from CoNS. Our analysis established 9 distinct clusters and revealed close relationships between S. aureus and CoNS phages. Genes involved in DNA metabolism and lysis and potentially in phage-host interaction appear to be widespread, while structural genes tend to be cluster specific. Our findings support the notion of a possible reciprocal exchange of genes between phages originating from S. aureus and CoNS, which may be of crucial importance for pathogenesis in staphylococci.     

A SNP Based High-Density Linkage Map of Apis cerana Reveals a High Recombination Rate Similar to Apis mellifera

Background

The Eastern honey bee, Apis cerana Fabricius, is distributed in southern and eastern Asia, from India and China to Korea and Japan and southeast to the Moluccas. This species is also widely kept for honey production besides Apis mellifera. Apis cerana is also a model organism for studying social behavior, caste determination, mating biology, sexual selection, and host-parasite interactions. Few resources are available for molecular research in this species, and a linkage map was never constructed. A linkage map is a prerequisite for quantitative trait loci mapping and for analyzing genome structure. We used the Chinese honey bee, Apis cerana cerana to construct the first linkage map in the Eastern honey bee.

Results

F2 workers (N = 103) were genotyped for 126,990 single nucleotide polymorphisms (SNPs). After filtering low quality and those not passing the Mendel test, we obtained 3,000 SNPs, 1,535 of these were informative and used to construct a linkage map. The preliminary map contains 19 linkage groups, we then mapped the 19 linkage groups to 16 chromosomes by comparing the markers to the genome of A. mellfiera. The final map contains 16 linkage groups with a total of 1,535 markers. The total genetic distance is 3,942.7 centimorgans (cM) with the largest linkage group (180 loci) measuring 574.5 cM. Average marker interval for all markers across the 16 linkage groups is 2.6 cM.

Conclusion

We constructed a high density linkage map for A. c. cerana with 1,535 markers. Because the map is based on SNP markers, it will enable easier and faster genotyping assays than randomly amplified polymorphic DNA or microsatellite based maps used in A. mellifera.     

Divergent Evolution of Norovirus GII/4 by Genome Recombination from May 2006 to February 2009 in Japan

Norovirus GII/4 is a leading cause of acute viral gastroenteritis in humans. We examined here how the GII/4 virus evolves to generate and sustain new epidemics in humans, using 199 near-full-length GII/4 genome sequences and 11 genome segment clones from human stool specimens collected at 19 sites in Japan between May 2006 and February 2009. Phylogenetic studies demonstrated outbreaks of 7 monophyletic GII/4 subtypes, among which a single subtype, termed 2006b, had continually predominated. Phylogenetic-tree, bootscanning-plot, and informative-site analyses revealed that 4 of the 7 GII/4 subtypes were mosaics of recently prevalent GII/4 subtypes and 1 was made up of the GII/4 and GII/12 genotypes. Notably, single putative recombination breakpoints with the highest statistical significance were constantly located around the border of open reading frame 1 (ORF1) and ORF2 (P ≤ 0.000001), suggesting outgrowth of specific recombinant viruses in the outbreaks. The GII/4 subtypes had many unique amino acids at the time of their outbreaks, especially in the N-term, 3A-like, and capsid proteins. Unique amino acids in the capsids were preferentially positioned on the outer surface loops of the protruding P2 domain and more abundant in the dominant subtypes. These findings suggest that intersubtype genome recombination at the ORF1/2 boundary region is a common mechanism that realizes independent and concurrent changes on the virion surface and in viral replication proteins for the persistence of norovirus GII/4 in human populations.Norovirus (NoV) is a nonenveloped RNA virus that belongs to the family Caliciviridae and can cause acute gastroenteritis in humans. The NoV genome is a single-stranded, positive-sense, polyadenylated RNA that encodes three open reading frames, ORF1, ORF2, and ORF3 (68). ORF1 encodes a long polypeptide (∼200 kDa) that is cleaved in the cells by the viral proteinase (3C^pro) into six proteins (4). These proteins function in NoV replication in host cells (19). ORF2 encodes a viral capsid protein, VP1. The capsid gene evolved at a rate of 4.3 × 10⁻³ nucleotide substitutions/site/year (7), which is comparable to the substitution rates of the envelope and capsid genes of human immunodeficiency virus (30). The capsid protein of NoV consists of a shell (S) and two protruding (P) domains: P1 and P2 (47). The S domain is relatively conserved within the same genetic lineages of NoVs (38) and is responsible for the assembly of VP1 (6). The P1 subdomain is also relatively conserved (38) and has a role in enhancing the stability of virus particles (6). The P2 domain is positioned at the most exposed surface of the virus particle (47) and forms binding clefts for putative infection receptors, such as human histo-blood group antigens (HBGA) (8, 13, 14, 60). The P2 domain also contains epitopes for neutralizing antibodies (27, 33) and is consistently highly variable even within the same genetic lineage of NoVs (38). ORF3 encodes a VP2 protein that is suggested to be a minor structural component of virus particles (18) and to be responsible for the expression and stabilization of VP1 (5).Thus far, the NoVs found in nature are classified into five genogroups (GI to GV) and multiple genotypes on the basis of the phylogeny of capsid sequences (71). Among them, genogroup II genotype 4 (GII/4), which was present in humans in the mid-1970s (7), is now the leading cause of NoV-associated acute gastroenteritis in humans (54). The GII/4 is further subclassifiable into phylogenetically distinct subtypes (32, 38, 53). Notably, the emergence and spread of a new GII/4 subtype with multiple amino acid substitutions on the capsid surface are often associated with greater magnitudes of NoV epidemics (53, 54). In 2006 and 2007, a GII/4 subtype, termed 2006b, prevailed globally over preexisting GII/4 subtypes in association with increased numbers of nonbacterial acute gastroenteritis cases in many countries, including Japan (32, 38, 53). The 2006b subtype has multiple unique amino acid substitutions that occur most preferentially in the protruding subdomain of the capsid, the P2 subdomain (32, 38, 53). Together with information on human population immunity against NoV GII/4 subtypes (12, 32), it has been postulated that the accumulation of P2 mutations gives rise to antigenic drift and plays a key role in new epidemics of NoV GII/4 in humans (32, 38, 53).Genetic recombination is common in RNA viruses (67). In NoV, recombination was first suggested by the phylogenetic analysis of an NoV genome segment clone: a discordant branching order was noted with the trees of the 3D^pol and capsid coding regions (21). Subsequently, many studies have reported the phylogenetic discordance using sequences from various epidemic sites in different study periods (1, 10, 11, 16, 17, 22, 25, 40, 41, 44-46, 49, 51, 57, 63, 64, 66). These results suggest that genome recombination frequently occurs among distinct lineages of NoV variants in vivo. However, the studies were done primarily with direct sequencing data of the short genome portion, and information on the cloned genome segment or full-length genome sequences is very limited (21, 25). Therefore, we lack an overview of the structural and temporal dynamics of viral genomes during NoV epidemics, and it remains unclear whether NoV mosaicism plays a role in these events.To clarify these issues, we collected 199 near-full-length genome sequences of GII/4 from NoV outbreaks over three recent years in Japan, divided them into monophyletic subtypes, analyzed the temporal and geographical distribution of the subtypes, collected phylogenetic evidence for the viral genome mosaicism of the subtypes, identified putative recombination breakpoints in the genomes, and isolated mosaic genome segments from the stool specimens. We also performed computer-assisted sequence and structural analyses with the identified subtypes to address the relationship between the numbers of P2 domain mutations at the times of the outbreaks and the magnitudes of the epidemics. The obtained data suggest that intersubtype genome recombination at the ORF1/2 boundary region is common in the new GII/4 outbreaks and promotes the effective acquisition of mutation sets of heterogeneous capsid surface and viral replication proteins.     

Comparative evolution of GII.3 and GII.4 norovirus over a 31-year period

Noroviruses are the most common cause of epidemic gastroenteritis. Genotype II.3 is one of the most frequently detected noroviruses associated with sporadic infections. We studied the evolution of the major capsid gene from seven archival GII.3 noroviruses collected during a cross-sectional study at the Children's Hospital in Washington, DC, from 1975 through 1991, together with capsid sequence from 56 strains available in GenBank. Evolutionary analysis concluded that GII.3 viruses evolved at a rate of 4.16 × 10(-3) nucleotide substitutions/site/year (strict clock), which is similar to that described for the more prevalent GII.4 noroviruses. The analysis of the amino acid changes over the 31-year period found that GII.3 viruses evolve at a relatively steady state, maintaining 4% distance, and have a tendency to revert back to previously used residues while preserving the same carbohydrate binding profile. In contrast, GII.4 viruses demonstrate increasing rates of distance over time because of the continued integration of new amino acids and changing HBGA binding patterns. In GII.3 strains, seven sites acting under positive selection were predicted to be surface-exposed residues in the P2 domain, in contrast to GII.4 positively selected sites located primarily in the shell domain. Our study suggests that GII.3 noroviruses caused disease as early as 1975 and that they evolve via a specific pattern, responding to selective pressures induced by the host rather than presenting a nucleotide evolution rate lower than that of GII.4 noroviruses, as previously proposed. Understanding the evolutionary dynamics of prevalent noroviruses is relevant to the development of effective prevention and control strategies.     

A Recombination Hotspot in a Schizophrenia-Associated Region of GABRB2

Background

Schizophrenia is a major disorder with complex genetic mechanisms. Earlier, population genetic studies revealed the occurrence of strong positive selection in the GABRB2 gene encoding the β₂ subunit of GABA_A receptors, within a segment of 3,551 bp harboring twenty-nine single nucleotide polymorphisms (SNPs) and containing schizophrenia-associated SNPs and haplotypes.

Methodology/Principal Findings

In the present study, the possible occurrence of recombination in this ‘S1–S29’ segment was assessed. The occurrence of hotspot recombination was indicated by high resolution recombination rate estimation, haplotype diversity, abundance of rare haplotypes, recurrent mutations and torsos in haplotype networks, and experimental haplotyping of somatic and sperm DNA. The sub-segment distribution of relative recombination strength, measured by the ratio of haplotype diversity (H_d) over mutation rate (θ), was indicative of a human specific Alu-Yi6 insertion serving as a central recombining sequence facilitating homologous recombination. Local anomalous DNA conformation attributable to the Alu-Yi6 element, as suggested by enhanced DNase I sensitivity and obstruction to DNA sequencing, could be a contributing factor of the increased sequence diversity. Linkage disequilibrium (LD) analysis yielded prominent low LD points that supported ongoing recombination. LD contrast revealed significant dissimilarity between control and schizophrenic cohorts. Among the large array of inferred haplotypes, H26 and H73 were identified to be protective, and H19 and H81 risk-conferring, toward the development of schizophrenia.

Conclusions/Significance

The co-occurrence of hotspot recombination and positive selection in the S1–S29 segment of GABRB2 has provided a plausible contribution to the molecular genetics mechanisms for schizophrenia. The present findings therefore suggest that genome regions characterized by the co-occurrence of positive selection and hotspot recombination, two interacting factors both affecting genetic diversity, merit close scrutiny with respect to the etiology of common complex disorders.     

Crystal structures of GII.10 and GII.12 norovirus protruding domains in complex with histo-blood group antigens reveal details for a potential site of vulnerability

Noroviruses are the dominant cause of outbreaks of gastroenteritis worldwide, and interactions with human histo-blood group antigens (HBGAs) are thought to play a critical role in their entry mechanism. Structures of noroviruses from genogroups GI and GII in complex with HBGAs, however, reveal different modes of interaction. To gain insight into norovirus recognition of HBGAs, we determined crystal structures of norovirus protruding domains from two rarely detected GII genotypes, GII.10 and GII.12, alone and in complex with a panel of HBGAs, and analyzed structure-function implications related to conservation of the HBGA binding pocket. The GII.10- and GII.12-apo structures as well as the previously solved GII.4-apo structure resembled each other more closely than the GI.1-derived structure, and all three GII structures showed similar modes of HBGA recognition. The primary GII norovirus-HBGA interaction involved six hydrogen bonds between a terminal αfucose1-2 of the HBGAs and a dimeric capsid interface, which was composed of elements from two protruding subdomains. Norovirus interactions with other saccharide units of the HBGAs were variable and involved fewer hydrogen bonds. Sequence analysis revealed a site of GII norovirus sequence conservation to reside under the critical αfucose1-2 and to be one of the few patches of conserved residues on the outer virion-capsid surface. The site was smaller than that involved in full HBGA recognition, a consequence of variable recognition of peripheral saccharides. Despite this evasion tactic, the HBGA site of viral vulnerability may provide a viable target for small molecule- and antibody-mediated neutralization of GII norovirus.     

Multilocus Sequence Type Analysis Reveals both Clonality and Recombination in Populations of Candida glabrata Bloodstream Isolates from U.S. Surveillance Studies

The human commensal yeast Candida glabrata is becoming increasingly important as an agent of nosocomial bloodstream infection. However, relatively little is known concerning the genetics and population structure of this species. We have analyzed 230 incident bloodstream isolates from previous and current population-based surveillance studies by using multilocus sequence typing (MLST). Our results show that in the U.S. cities of Atlanta, GA; Baltimore, MD; and San Francisco, CA during three time periods spanning 1992 to 2009, five populations of C. glabrata bloodstream isolates are defined by a relatively small number of sequence types. There is little genetic differentiation in the different C. glabrata populations. We also show that there has been a significant temporal shift in the prevalence of one major subtype in Atlanta. Our results support the concept that both recombination and clonality play a role in the population structure of this species.In the most recently available survey of nosocomial bloodstream infections, Candida species were the fourth most common organism, surpassed only by Staphylococcus and Enterococcus species (24). Although Candida albicans remains the most commonly isolated Candida species worldwide, the incidence of Candida glabrata infection has been increasing steadily so that it is now the second most common cause of Candida infection in the United States (14). C. glabrata is considered a normal component of the human epithelial flora but is capable of causing serious systemic infections in susceptible hosts. This increase in the relative proportion of infections due to C. glabrata has come during the period of the introduction and prophylactic use of azole antifungal drugs (21) and may be a reflection of the decreased susceptibility of C. glabrata to these azole antifungal drugs (7, 15). Many questions regarding the epidemiology of C. glabrata infections have a direct impact on public health and still remain unanswered. Is the decreased susceptibility due to a small number of clones expanding in a population, or are all isolates capable of developing resistance to azole drugs? Are some isolates more virulent than others and therefore more prevalent in a population? Can we monitor the expansion of clonal isolates that may be more virulent or have increased drug resistance? A better understanding of the population genetics of C. glabrata may allow us to answer some of these questions.Many DNA fingerprinting methods have been developed for the investigation of the population genetics of Candida species (19). Two of the most important aspects of a typing system are reproducibility between laboratories and the ability to archive strain types. Multilocus sequence typing (MLST) has been developed as a typing system which allows highly reproducible strain discrimination as well as the development of genotypic strain archives that can be stored digitally for both prospective and retrospective analysis of isolates (13, 22). An MLST system which utilizes six housekeeping genes on six separate chromosomes was developed for C. glabrata (4), and an online archive of sequence types (STs) was established (http://cglabrata.mlst.net). Several studies utilizing this typing system have described the molecular population structure of both regional and worldwide collections of C. glabrata isolates (4, 5, 11, 12).During the past 2 decades, the Centers for Disease Control and Prevention (CDC) and our partners have undertaken three active, population-based surveillance studies in order to determine the incidence of candidemia, the distribution of species causing bloodstream infection, and the prevalence of antifungal drug resistance (8, 10). In each case, two major metropolitan areas were included: San Francisco, CA, and Atlanta, GA (1992 to 1993); Baltimore, MD, and the state of Connecticut (1998 to 2000); and Atlanta, GA, and Baltimore, MD (2008 to 2010). Population-based surveillance is unique in that it includes the total population of a particular geographic area and avoids the biases associated with single or select institutional studies. During each of the surveillance studies, incident bloodstream isolates from all hospitals within each defined geographic area were collected and identified to the species level. While C. glabrata isolates comprised a smaller percentage of the isolates in the 1992-to-1993 and 1998-to-2000 surveillance studies (8, 10), they represent almost a third of the isolates collected during the current surveillance (N. Iqbal and S. Lockhart, unpublished observations).In the present work, we have characterized by MLST analysis 230 isolates of C. glabrata from five populations (excluding Connecticut) separated both geographically and temporally. This unique collection of isolates allowed an analysis of the changing population genetics of this organism. We identified 31 unique STs and showed the maintenance of a major ST both geographically and temporally that is unique to the United States. An analysis of the relatedness of specific C. glabrata populations and a strong indication for recombination within and between populations are provided.     

Complete Genome Sequence of a Novel Bovine Norovirus: Evidence for Slow Genetic Evolution in Genogroup III Genotype 2 Noroviruses

A new genogroup III genotype 2 bovine norovirus, B309/2003/BE, was entirely sequenced and genetically compared to the original Newbury2/1976/UK strain and to Dumfries/1994/UK, detected in 1976 and 1994, respectively. Interestingly, except in well-defined coding regions (N-terminal protein, 3A-like protease, hypervariable region of the capsid protein, and C-terminal part of the minor structural protein), very low genetic differences were noted between the entire genomes of these three strains along a 30-year-long period. It allowed some hypotheses of hotspots of genetic evolution through a low genetic evolution background in genotype 2 genogroup III bovine noroviruses.     

Species and Population Level Molecular Profiling Reveals Cryptic Recombination and Emergent Asymmetry in the Dimorphic Mating Locus of C. reinhardtii

Heteromorphic sex-determining regions or mating-type loci can contain large regions of non-recombining sequence where selection operates under different constraints than in freely recombining autosomal regions. Detailed studies of these non-recombining regions can provide insights into how genes are gained and lost, and how genetic isolation is maintained between mating haplotypes or sex chromosomes. The Chlamydomonas reinhardtii mating-type locus (MT) is a complex polygenic region characterized by sequence rearrangements and suppressed recombination between its two haplotypes, MT+ and MT−. We used new sequence information to redefine the genetic contents of MT and found repeated translocations from autosomes as well as sexually controlled expression patterns for several newly identified genes. We examined sequence diversity of MT genes from wild isolates of C. reinhardtii to investigate the impacts of recombination suppression. Our population data revealed two previously unreported types of genetic exchange in Chlamydomonas MT—gene conversion in the rearranged domains, and crossover exchanges in flanking domains—both of which contribute to maintenance of genetic homogeneity between haplotypes. To investigate the cause of blocked recombination in MT we assessed recombination rates in crosses where the parents were homozygous at MT. While normal recombination was restored in MT+×MT+ crosses, it was still suppressed in MT−×MT− crosses. These data revealed an underlying asymmetry in the two MT haplotypes and suggest that sequence rearrangements are insufficient to fully account for recombination suppression. Together our findings reveal new evolutionary dynamics for mating loci and have implications for the evolution of heteromorphic sex chromosomes and other non-recombining genomic regions.