A guardian of grasses: specific origin and conservation of a unique disease-resistance gene in the grass lineage

The maize Hm1 gene provides protection against a lethal leaf blight and ear mold disease caused by Cochliobolus carbonum race 1 (CCR1). Although it was the first disease-resistance (DR) gene to be cloned, it remains a novelty because, instead of participating in the plant recognition and response system as most DR genes do, Hm1 disarms the pathogen directly. It does so by encoding an NADPH-dependent reductase, whose function is to inactivate Helminthosporium carbonum (HC) toxin, an epoxide-containing cyclic tetrapeptide, which the pathogen produces as a key virulence factor to colonize maize. Although CCR1 is strictly a pathogen of maize, orthologs of Hm1 and the HC-toxin reductase activity are present in the grass family, suggesting an ancient and evolutionarily conserved role of this DR trait in plants. Here, we provide proof for such a role by demonstrating its involvement in nonhost resistance of barley to CCR1. Barley leaves in which expression of the Hm1 homologue was silenced became susceptible to infection by CCR1, but only if the pathogen was able to produce HC toxin. Phylogenetic analysis indicated that Hm1 evolved exclusively and early in the grass lineage. Given the devastating ability of CCR1 to kill maize, these findings imply that the evolution and/or geographical distribution of grasses may have been constrained if Hm1 did not emerge.     

Native root-associated bacteria rescue a plant from a sudden-wilt disease that emerged during continuous cropping

Plants maintain microbial associations whose functions remain largely unknown. For the past 15 y, we have planted the annual postfire tobacco Nicotiana attenuata into an experimental field plot in the plant’s native habitat, and for the last 8 y the number of plants dying from a sudden wilt disease has increased, leading to crop failure. Inadvertently we had recapitulated the common agricultural dilemma of pathogen buildup associated with continuous cropping for this native plant. Plants suffered sudden tissue collapse and black roots, symptoms similar to a Fusarium–Alternaria disease complex, recently characterized in a nearby native population and developed into an in vitro pathosystem for N. attenuata. With this in vitro disease system, different protection strategies (fungicide and inoculations with native root-associated bacterial and fungal isolates), together with a biochar soil amendment, were tested further in the field. A field trial with more than 900 plants in two field plots revealed that inoculation with a mixture of native bacterial isolates significantly reduced disease incidence and mortality in the infected field plot without influencing growth, herbivore resistance, or 32 defense and signaling metabolites known to mediate resistance against native herbivores. Tests in a subsequent year revealed that a core consortium of five bacteria was essential for disease reduction. This consortium, but not individual members of the root-associated bacteria community which this plant normally recruits during germination from native seed banks, provides enduring resistance against fungal diseases, demonstrating that native plants develop opportunistic mutualisms with prokaryotes that solve context-dependent ecological problems.Eukaryotes maintain many complex relationships with the microbes they host, which can be so abundant and diverse that they frequently are considered a eukaryote’s second genome. The complex relationships mediated by microbial associates are being revealed rapidly, thanks to the advances in sequencing, microbial culturing techniques, and the reconstitution of associated microbial communities in gnotobiotic systems (1, 2), even if some of these putative functional roles may need to be evaluated more critically (3).When plants germinate from their seed banks, they typically acquire a selection of the diverse fungi and bacteria that exist in native soils, and a subset of this community becomes root-associated. The best characterized are the bacterial microbiomes of Arabidopsis thaliana. Approximately half of the bacterial community in the plant root is representative of the soil flora; the remainder is a conserved core consisting of a smaller number of bacterial lineages from three phyla: Actinobacteria, Proteobacteria, and Bacteroidetes (2, 4). Because these bacterial communities occur in nondiseased plants, they are thought to represent commensalistic or possibly mutualistic associations.Root-associated microbes could benefit plants in many ways, and a recent review (5) highlighted the parallel functional roles of the microbiomes of the human gut and those of plant roots. The best-characterized beneficial functions for plants are (i) the plant growth-promoting rhizobacteria (PGPR), which promote growth by a variety of direct and indirect means that include increasing nutrient availability, interfering with ethylene (ET) signaling, and preventing diseases (6), and (ii) the bacteria that elicit induced systemic resistance (ISR) (7) by activating jasmonic acid (JA) and ET signaling (8). PGPR and ISR have been studied in a variety of cultivated and model plants, usually with model microbes (5), but little is known about their ecological context or whether they increase the growth and fitness of native plants. Whether PGPR and ISR functions occur among the well-characterized root-associated bacterial communities of Arabidopsis, either collectively or individually, also remains unknown.The well-described agricultural phenomenon of disease-suppressive soils that harbor microbiomes that suppress particular soil-borne pathogens (9) illustrates the complexity of the dynamics involved. Native soils have a certain degree of pathogen-suppressive ability, frequently seen when a crop is grown continuously in a soil, suffers an outbreak of a disease, and subsequently becomes resistant to the disease (5). Perhaps the mechanisms involved are best understood in a root disease of wheat caused by Gaeumannomyces graminis var Tritici infections, known as “take-all” disease. After many years of continuous wheat cropping with several disease outbreaks, the disease suddenly wanes, apparently because of the build-up of antagonistic Pseudomonas spp. (9). Whether any of these interactions also occur in native plants remains unknown.Nicotiana attenuata, a native annual tobacco of North America, germinates from long-lived seed banks to grow in the immediate postfire environment (10). When N. attenuata seeds germinate from their seed banks, they acquire a root-associated microbiome from their native soils which has been characterized by pyrosequencing and culture-dependent approaches (11–14). The composition of the root-associated microbiome is not influenced by a plant’s ability to elicit JA signaling (14), but ET signaling, as mediated by the ability both to produce and to perceive ET, plays a decisive role in shaping the “immigration policy” for the root-associated microbiome (12). A certain Bacillus strain, B55, was isolated from the roots of an ET-insensitive N. attenuata plant (35S etr-1) and was able to rescue the impaired-growth and high-mortality phenotype of ET-insensitive plants under field conditions (15). Beneficial effects were attributed to B55’s ability to reduce sulfur and produce dimethyl disulfide, which N. attenuata uses to alleviate sulfur deficiencies. This rescue provided one of the first demonstrations that the soil bacteria recruited by plants during germination can form opportunistic mutualistic relationships with their host based on the host plant’s ecological context. Here we provide a second example that involves protection against a sudden wilt disease, which accumulated in a field plot after consecutive planting of N. attenuata seedlings.     

Birth of a new gene on the Y chromosome of Drosophila melanogaster

Contrary to the pattern seen in mammalian sex chromosomes, where most Y-linked genes have X-linked homologs, the Drosophila X and Y chromosomes appear to be unrelated. Most of the Y-linked genes have autosomal paralogs, so autosome-to-Y transposition must be the main source of Drosophila Y-linked genes. Here we show how these genes were acquired. We found a previously unidentified gene (flagrante delicto Y, FDY) that originated from a recent duplication of the autosomal gene vig2 to the Y chromosome of Drosophila melanogaster. Four contiguous genes were duplicated along with vig2, but they became pseudogenes through the accumulation of deletions and transposable element insertions, whereas FDY remained functional, acquired testis-specific expression, and now accounts for ∼20% of the vig2-like mRNA in testis. FDY is absent in the closest relatives of D. melanogaster, and DNA sequence divergence indicates that the duplication to the Y chromosome occurred ∼2 million years ago. Thus, FDY provides a snapshot of the early stages of the establishment of a Y-linked gene and demonstrates how the Drosophila Y has been accumulating autosomal genes.The mammalian Y chromosome has the lowest gene density of any chromosome, and most of its genes have a homolog on the X. This pattern is consistent with the mammalian sex chromosomes having originated from an ordinary pair of chromosomes, followed by massive gene loss from the Y (1–4). In contrast, the closest homologs of all Drosophila melanogaster Y-linked protein-encoding genes are autosomal, strongly suggesting that its Y chromosome has been acquiring genes from the autosomes (5–7). Indeed, gene gains, and not gene losses, have played the major role in shaping the gene content of the Drosophila Y, at least in the last ∼63 million years (My) (8, 9). Hence, the Drosophila Y chromosome seems to be evolving noncanonically (10) and is an ideal model to investigate the dynamics of gene gain on a nonrecombining Y chromosome.The Drosophila Y chromosome has long been known to contain genes essential for male fertility (11, 12). Due to its heterochromatic state, progress in the molecular identification of the Y-linked single-copy genes has been slow. male fertility factor kl5 (kl-5), the first single-copy gene identified, was found serendipitously; it encodes a motor protein (dynein heavy chain) required for flagellar beating (13). More recently, a combination of computational and experimental methods identified 11 single-copy Y-linked genes among the unmapped sequence scaffolds produced by the Drosophila Genome Project (5–7). These genes have two striking features: (i) their closest paralogs are autosomal and not X linked, and (ii) they have male-specific functions, such as the beating of sperm flagella reported for the kl-5 gene (14). The most likely explanation for this pattern is that Y-linked genes were acquired from the autosomes and have been retained because they confer a specific fitness advantage to their carriers. An autosomal origin has previously been reported for a few Y-linked genes in humans and a repetitive gene on the Drosophila Y (4, 15). However, unequivocal evidence of the autosomal origin of Drosophila Y-linked genes, and of the specific mechanism that originated them, is lacking due to their antiquity. The 11 known single-copy genes (kl-2, kl-3, kl-5, ARY, WDY, PRY, Pp1-Y1, Pp1-Y2, Ppr-Y, ORY, and CCY) represent ancient duplications, with amino acid identities to the putative ancestors ranging from 30% to 74%, and poor (if any) alignment at the nucleotide level. Most of them have introns in conserved positions compared with their autosomal paralogs, ruling out retrotransposition and suggesting DNA-based duplication as the mechanism. The original size of these putative duplications is unknown, because the similarity between autosomal and Y-linked regions is restricted to one gene in each case. Flanking sequences and contiguous genes either were not duplicated or were subsequently mutated and deleted beyond recognition.Here we describe flagrante delicto Y (FDY), a single copy Y-linked gene present only in D. melanogaster, and which is 98% identical at the nucleotide level to the autosomal gene vig2. Because its origin is very recent (it occurred after the split between D. melanogaster and Drosophila simulans, ∼4 Mya), it was possible to demonstrate that FDY arose from a DNA-based duplication of chromosome 3R to the Y: the duplicated segment spans 11 kb of autosomal sequence and includes five contiguous genes (vig2, Mocs2, CG42503, Clbn, and Bili); the last four genes became pseudogenes by rapid accumulation of deletions, point mutations, and transposable element insertions or by lack of expression. Thus, FDY unequivocally demonstrates that the Drosophila Y has acquired genes from autosomes. Several Y-linked genes such as kl-2, kl-3, and PRY are shared by distant Drosophila species that diverged ∼60 Mya, implying ancient acquisitions. FDY dates the more recent acquisition to ∼2 My, and hence strongly suggests that Drosophila Y has been continuously acquiring autosomal genes.     

Circuit theory predicts gene flow in plant and animal populations

Maintaining connectivity for broad-scale ecological processes like dispersal and gene flow is essential for conserving endangered species in fragmented landscapes. However, determining which habitats should be set aside to promote connectivity has been difficult because existing models cannot incorporate effects of multiple pathways linking populations. Here, we test an ecological connectivity model that overcomes this obstacle by borrowing from electrical circuit theory. The model vastly improves gene flow predictions because it simultaneously integrates all possible pathways connecting populations. When applied to data from threatened mammal and tree species, the model consistently outperformed conventional gene flow models, revealing that barriers were less important in structuring populations than previously thought. Circuit theory now provides the best-justified method to bridge landscape and genetic data, and holds much promise in ecology, evolution, and conservation planning.     

Evolutionary origin of the amnioserosa in cyclorrhaphan flies correlates with spatial and temporal expression changes of zen

Higher cyclorrhaphan flies including Drosophila develop a single extraembryonic epithelium (amnioserosa), which closes the germband dorsally. In most other insects two extraembryonic epithelia, serosa and amnion, line the inner eggshell and the ventral germband, respectively. How the two extraembryonic epithelia evolved into one is unclear. Recent studies have shown that, in the flour beetle Tribolium and in the milkweed bug Oncopeltus, the homeobox gene zerknüllt (zen) controls the fusion of the amnion with the serosa before dorsal closure. To understand the origin of the amnioserosa in evolution, we examined the expression and function of zen in the extraembryonic tissue of lower Cyclorrhapha. We show that Megaselia abdita (Phoridae) and Episyrphus balteatus (Syrphidae) develop a serosa and a dorsal amnion, suggesting that a dorsal amnion preceded the origin of the amnioserosa in evolution. Using Krüppel (Kr) and pannier (pnr) homologues of Megaselia as markers for serosal and amniotic tissue, respectively, we show that after zen RNAi all extraembryonic tissue becomes indistinguishable from amniotic cells, like in Tribolium but unlike in Drosophila, in which zen controls all aspects of extraembryonic development. Compared with Megaselia and Episyrphus, zen expression in Drosophila is extended to cells that form the amnion in lower Cyclorrhapha and is down-regulated at the developmental stage, when serosa cells in lower Cyclorrhapha begin to expand. These expression differences between species with distinct extraembryonic tissue organizations and the conserved requirement of zen for serosa development suggest that the origin of an amnioserosa-like epithelium was accompanied by expression changes of zen.     

Evolution of host range in Coleosporium ipomoeae,a plant pathogen with multiple hosts

Plants and their pathogens coevolve locally. Previous investigations of one host–one pathogen systems have demonstrated that natural selection favors pathogen genotypes that are virulent on a broad range of host genotypes. In the present study, we examine a system consisting of one pathogen species that infects three host species in the morning glory genus Ipomoea. We show that many pathogen genotypes can infect two or three of the host species when tested on plants from nonlocal communities. By contrast, pathogen genotypes are highly host-specific, infecting only one host species, when tested on host species from the local community. This pattern indicates that within-community evolution narrows the host breadth of pathogen genotypes. Possible evolutionary mechanisms include direct selection for narrow host breadth due to costs of virulence and evolution of ipomoea resistance in the host species.Much of plant-pathogen coevolution is mediated by “gene-for-gene” (GFG) interactions. These interactions involve R genes in plants and corresponding virulence/avirulence genes in the pathogen (1). At a given pair of corresponding loci, a host may carry either a resistant (Res) or a susceptible (Sus) allele, or both, with Res typically being dominant. The pathogen may carry either a virulent (Vir) allele or an avirulent (Avr) allele. Infection results, unless at one pair of corresponding loci, the plant R locus has a Res allele and the pathogen has the Avr allele. Models of the evolution of GFG systems generally predict that generalist pathogens (those able to infect multiple host-resistance genotypes) will be favored by natural selection over highly specialized genotypes that can infect only one resistance genotype (2–6). Experimental analyses of pathogen host breadth in natural plant–pathogen systems are consistent with these expectations in that pathogen isolates are generally able to infect multiple host-resistance genotypes, especially in host populations with high levels of resistance (7–10).With very few exceptions (11, 12), the evolution of pathogen host range has been examined, both theoretically and empirically, for a single pathogen species interacting with a single host species. Many pathogens, however, are capable of infecting multiple host species. Predictions of evolutionary models based on a single evolving host species cannot be clearly extrapolated to this situation. Moreover, there are reasons to believe that, with multiple host species, selection for generalism may not be as prevalent. Maintaining infectivity on multiple hosts requires continued success in the coevolutionary arms race with more than one independently evolving host genome. The conditions under which this maintained infectivity can occur are likely more restrictive than with only one host, although this possibility has not been examined theoretically. In addition, selection to maintain infectivity on a particular host is likely weaker when the pathogen population can successfully reproduce on another host (see ref. 13 for an analogous argument with respect to partial resistance). Finally, costs associated with the ability to infect multiple host species (e.g., ref. 14) are likely greater than costs associated with the ability to infect multiple genotypes within the same host. All of these factors would tend to weaken selection for a broad host range and thus promote the evolution of specialist pathogen genotypes within populations.One approach to determining whether there is an evolutionary tendency for host breadth to be narrowed within populations is to compare pathogen host breadth in its local native community with host breadth on hosts from outside its native community (e.g., refs. 9 and 13). The latter constitutes an estimate of host breadth on host species with which the pathogen has presumably not recently coevolved and is also an estimate of host breadth for a pathogen strain that has recently immigrated into a new community. If evolutionary processes within local communities act to promote specialization, host breadth should be lower on hosts from the native community. In this report, we demonstrate that this pattern is exhibited for a host–pathogen system consisting of one pathogen and three host species.     

PRDM1 is a tumor suppressor gene in natural killer cell malignancies

Natural killer cell lymphoma (NKCL) constitutes a rare and aggressive form of non-Hodgkin lymphoma, and there is little insight into its pathogenesis. Here we show that PRDM1 is a tumor suppressor gene in NKCLs that is inactivated by a combination of monoallelic deletion and promoter CpG island hypermethylation. We observed monoallelic deletion of PRDM1 loci in 8 of 18 (44%) NKCL cases. The other allele showed significant promoter methylation in 12 of 17 (71%) cases. In support of its role as a tumor suppressor gene, the reconstitution of PRDM1 in PRDM1-null NK cell lines led to G2/M cell cycle arrest, increased apoptosis, and a strong negative selection pressure with progressive elimination of PRDM1-expressing cells, which was enhanced when IL-2 concentration is limiting. We observed a progressive increase in PRDM1 expression--in particular, PRDM1α--in normal NK cells in response to IL-2 and in normal NK cells activated with an engineered NK cell target, K562-Cl9-mb21, suggesting its role in NK cell homeostasis. In support of this role, knockdown of PRDM1 by shRNA in normal NK cells resulted in the positive selection of these cells. We identified MYC and 4-1BBL as targets of PRDM1 in NK cells. Disruption of homeostatic control by PRDM1 may be an important pathogenetic mechanism for NKCL.     

Distinct deregulation of the hypoxia inducible factor by PHD2 mutants identified in germline DNA of patients with polycythemia

Background

Congenital secondary erythrocytoses are due to deregulation of hypoxia inducible factor resulting in overproduction of erythropoietin. The most common germline mutation identified in the hypoxia signaling pathway is the Arginine 200-Tryptophan mutant of the von Hippel-Lindau tumor suppressor gene, resulting in Chuvash polycythemia. This mutant displays a weak deficiency in hypoxia inducible factor α regulation and does not promote tumorigenesis. Other von Hippel-Lindau mutants with more deleterious effects are responsible for von Hippel-Lindau disease, which is characterized by the development of multiple tumors. Recently, a few mutations in gene for the prolyl hydroxylase domain 2 protein (PHD2) have been reported in cases of congenital erythrocytosis not associated with tumor formation with the exception of one patient with a recurrent extra-adrenal paraganglioma.

Design and Methods

Five PHD2 variants, four of which were novel, were identified in patients with erythrocytosis. These PHD2 variants were functionally analyzed and compared with the PHD2 mutant previously identified in a patient with polycythemia and paraganglioma. The capacity of PHD2 to regulate the activity, stability and hydroxylation of hypoxia inducible factor α was assessed using hypoxia-inducible reporter gene, one-hybrid and in vitro hydroxylation assays, respectively.

Results

This functional comparative study showed that two categories of PHD2 mutants could be distinguished: one category with a weak deficiency in hypoxia inducible factor α regulation and a second one with a deleterious effect; the mutant implicated in tumor occurrence belongs to the second category.

Conclusions

As observed with germline von Hippel-Lindau mutations, there are functional differences between the PHD2 mutants with regards to hypoxia inducible factor regulation. PHD2 mutation carriers do, therefore, need careful medical follow-up, since some mutations must be considered as potential candidates for tumor predisposition.     

Interspecific introgressive origin of genomic diversity in the house mouse

We report on a genome-wide scan for introgression between the house mouse (Mus musculus domesticus) and the Algerian mouse (Mus spretus), using samples from the ranges of sympatry and allopatry in Africa and Europe. Our analysis reveals wide variability in introgression signatures along the genomes, as well as across the samples. We find that fewer than half of the autosomes in each genome harbor all detectable introgression, whereas the X chromosome has none. Further, European mice carry more M. spretus alleles than the sympatric African ones. Using the length distribution and sharing patterns of introgressed genomic tracts across the samples, we infer, first, that at least three distinct hybridization events involving M. spretus have occurred, one of which is ancient, and the other two are recent (one presumably due to warfarin rodenticide selection). Second, several of the inferred introgressed tracts contain genes that are likely to confer adaptive advantage. Third, introgressed tracts might contain driver genes that determine the evolutionary fate of those tracts. Further, functional analysis revealed introgressed genes that are essential to fitness, including the Vkorc1 gene, which is implicated in rodenticide resistance, and olfactory receptor genes. Our findings highlight the extent and role of introgression in nature and call for careful analysis and interpretation of house mouse data in evolutionary and genetic studies.Classical laboratory mouse strains, as well as newly established wild-derived ones, are widely used by geneticists for answering a diverse array of questions (1). Understanding the genome contents and architecture of these strains is important for studies of natural variation and complex traits, as well as evolutionary studies in general (2). Mus spretus, a sister species of Mus musculus, impacts the findings in M. musculus investigations for at least two reasons. First, it was deliberately interbred with laboratory M. musculus strains to introduce genetic variation (3). Second, Mus musculus domesticus is partially sympatric (naturally cooccurring) with M. spretus (Fig. 1).Open in a separate windowFig. 1.Species ranges and samples used in our study. The species range of M. spretus is shown in green (4), and the species range of M. m. domesticus includes the blue regions, the range of M. spretus, and beyond (1). M. m. domesticus and M. spretus samples were obtained from locations marked with red circles and purple diamonds, respectively. The samples originated from within and outside the area of sympatry between the two species. (SI Appendix, Table S1, provides additional details about the samples used in our study.)Recent studies have examined admixture between subspecies of house mice (5–8), but have not studied introgression with M. spretus. In at least one case (5), the introgressive descent of the mouse genome was hidden due to data postprocessing that masked introgressed genomic regions as missing data. In another study reporting whole-genome sequencing of 17 classical laboratory strains (6), M. spretus was used as an outgroup for phylogenetic analysis. The authors were surprised to find that 12.1% of loci failed to place M. spretus as an outgroup to the M. musculus clade. The authors concluded that M. spretus was not a reliable outgroup but did not pursue their observation further. On the other hand, in a 2002 study (9), Orth et al. compiled data on allozyme, microsatellite, and mitochondrial variation in house mice from Spain (sympatry) and nearby countries in western and central Europe. Interestingly, allele sharing between the species was observed in the range of sympatry but not outside in the range of allopatry. The studies demonstrated the possibility of natural hybridization between these two sister species. Further, the study of Song et al. (10) demonstrated a recent adaptive introgression from M. spretus into some M. m. domesticus populations in the wild, involving the vitamin K epoxide reductase subcomponent 1 (Vkorc1) gene, which was later shown to be more widespread in Europe, albeit geographically restricted to parts of southwestern and central Europe (11).Major, unanswered questions arise from these studies. First, is the vicinity around the Vkorc1 gene an isolated case of adaptive introgression in the house mouse genome, or do many other such regions exist? Second, is introgression between M. spretus and M. m. domesticus common outside the range of sympatry? Third, have there been other hybridization events, and, in particular, more ancient ones? Fourth, what role do introgressed genes, and, more generally, genomic regions, play?To investigate these open questions, we used genome-wide variation data from 20 M. m. domesticus samples (wild and wild-derived) from the ranges of sympatry and allopatry, as well as two M. spretus samples. For detecting introgression, we used PhyloNet-HMM (12), a newly developed method for statistical inference of introgression in genomes while accounting for other evolutionary processes, most notably incomplete lineage sorting (ILS).Our analysis provides answers to the questions posed above. First, we find signatures of introgression between M. spretus and each of the M. m. domesticus samples. The amount of introgression varies across the autosomes of each genome, with a few chromosomes harboring all detectable introgression, and most of the chromosomes have none. We detected no introgression on the X chromosome. Further, the amount of introgression varied widely across the samples. Our analyses demonstrate introgression outside the range of sympatry. In fact, our results show more signatures of introgression in the genomes of allopatric samples from Europe than in sympatric samples from Africa. For the third question, we used the length distribution and sharing patterns of introgressed regions across the samples to show support for at least three hybridization events: an ancient hybridization event that predates the colonization of Europe by M. m. domesticus and two more recent events, one of which presumably occurred about 50 y ago and is related to warfarin resistance selection (10). For the fourth question, our functional analysis of the introgressed genes shows enrichment for certain categories, most notably olfaction—an essential trait for the fitness of rodents. Understanding the genomic architecture and evolutionary history of the house mouse has broad implications on various aspects of evolutionary, genetic, and biomedical research endeavors that use this model organism. The PhyloNet-HMM method (12) can be used to detect introgression in other eukaryotic species, further broadening the impact of this work.     

First Isolation of a Giant Virus from Wild Hirudo medicinalis Leech: Mimiviridae isolation in Hirudo medicinalis

Giant viruses and amoebae are common in freshwater, where they can coexist with other living multicellular organisms. We screened leeches from the species Hirudo medicinalis for giant viruses. We analyzed five H. medicinalis obtained from Tunisia (3) and France (2). The leeches were decontaminated and then dissected to remove internal parts for co-culture with Acanthamoeba polyphaga. The genomes of isolated viruses were sequenced on a 454 Roche instrument, and a comparative genomics analysis was performed. One Mimivirus was isolated and the strain was named Hirudovirus. The genome assembly generated two scaffolds, which were 1,155,382 and 25,660 base pairs in length. Functional annotations were identified for 47% of the genes, which corresponds to 466 proteins. The presence of Mimividae in the same ecological niche as wild Hirudo may explain the presence of the mimivirus in the digestive tract of the leech, and several studies have already shown that viruses can persist in the digestive tracts of leeches fed contaminated blood. As leeches can be used medically and Mimiviruses have the potential to be an infectious agent in humans, patients treated with leeches should be surveyed to investigate a possible connection.     

Edwardsiella tarda bacteremia. A rare but fatal water- and foodborne infection: Review of the literature and clinical cases from a single centre

BACKGROUND:Edwardsiella tarda bacteremia (ETB) can be a fatal disease in humans.OBJECTIVES:To determine the significant risk factors associated with death caused by ETB, and to examine the geographical, seasonal, environmental and dietary factors of the disease.METHODS:A retrospective, observational, case control study was performed. The PubMed MEDLINE and Japanese Medical Abstract Society (www.jamas.or.jp) databases were searched for ETB case reports and meeting abstracts. In additon, retrospective chart reviews of patients with ETB at the Tokyo Women’s Medical University Hospital (Tokyo, Japan) were conducted to evaluate the risk factors associated with death using multivariate analyses.RESULTS:The literature search yielded 46 publications, comprising 72 cases from the English (n=30), French (n=1), Spanish (n=1) and Japanese (n=14) literature. Five cases at the Tokyo Women’s Medical University Hospital were also included. Of the included 77 cases, the mean age was 61 years and 39% of patients were female; 77.2% of the cases occurred between June and November, and 45.5% were reported in Japan. Dietary factors (raw fish/meat exposure) were reported for 10.4% of patients and 12.9% reported environmental (ie, brackish water) exposure. The overall mortality rate was 44.6%; however, this rate increased to 61.1% for ETB patients with soft tissue infections. Liver cirrhosis was determined to be an independent risk factor associated with death (OR 12.0 [95% CI 2.46 to 58.6]; P=0.00213) using multivariate analyses.DISCUSSION:To our knowledge, the present analysis was the first and largest multi-language review of ETB. Clinical characteristics of ETB resemble those of Aeromonas, typhoid fever and Vibrio vulnificus infections, in addition to sharing similar risk factors.CONCLUSION:ETB should be categorized as a severe food- and waterborne infection, which results in high mortality for patients with liver cirrhosis.