Identification and characterization of SNJ2, the first temperate pleolipovirus integrating into the genome of the SNJ1‐lysogenic archaeal strain

Proviral regions have been identified in the genomes of many haloarchaea, but only a few archaeal halophilic temperate viruses have been studied. Here, we report a new virus, SNJ2, originating from archaeal strain Natrinema sp. J7‐1. We demonstrate that this temperate virus coexists with SNJ1 virus and is dependent on SNJ1 for efficient production. Here, we show that SNJ1 is an icosahedral membrane‐containing virus, whereas SNJ2 is a pleomorphic one. Instead of producing progeny virions and forming plaques, SNJ2 integrates into the host tRNA^Met gene. The virion contains a discontinuous, circular, double‐stranded DNA genome of 16 992 bp, in which both nicks and single‐stranded regions are present preceded by a ‘GCCCA’ motif. Among 25 putative SNJ2 open reading frames (ORFs), five of them form a cluster of conserved ORFs homologous to archaeal pleolipoviruses isolated from hypersaline environments. Two structural protein encoding genes in the conserved cluster were verified in SNJ2. Furthermore, SNJ2‐like proviruses containing the conserved gene cluster were identified in the chromosomes of archaea belonging to 10 different genera. Comparison of SNJ2 and these proviruses suggests that they employ a similar integration strategy into a tRNA gene.     

Resequencing and comparison of whole mitochondrial genome to gain insight into the evolutionary status of the Shennongjia golden snub‐nosed monkey (SNJ R. roxellana)

Shennongjia Rhinopithecus roxellana (SNJ R. roxellana) is the smallest geographical population of R. roxellana. The phylogenetic relationships among its genera and species and the biogeographic processes leading to their current distribution are largely unclear. To address these issues, we resequenced and obtained a new, complete mitochondrial genome of SNJ R. roxellana by next‐generation sequencing and standard Sanger sequencing. We analyzed the gene composition, constructed a phylogenetic tree, inferred the divergence ages based on complete mitochondrial genome sequences, and analyzed the genetic divergence of 13 functional mtDNA genes. The phylogenetic tree and divergence ages showed that R. avunculus (the Tonkin snub‐nosed monkey) was the first to diverge from the Rhinopithecus genus ca. 2.47 million years ago (Ma). Rhinopithecus bieti and Rhinopithecus strykeri formed sister groups, and the second divergence from the Rhinopithecus genus occurred ca. 1.90 Ma. R. roxellana and R. brelichi diverged from the Rhinopithecus genus third, ca. 1.57 Ma. SNJ R. roxellana was the last to diverge within R. roxellana species in 0.08 Ma, and the most recent common ancestor of R. roxellana is 0.10 Ma. The analyses on gene composition showed SNJ R. roxellana was the newest geographic population of R. roxellana. The work will help to develop a more accurate protection policy for SNJ R. roxellana and facilitate further research on selection and adaptation of R. roxellana.     

Molecular characterization of a new badnavirus associated with streak symptoms on enset (Ensete ventricosum,Musaceae)

Electron microscopy of leaf samples displaying streak symptoms from enset (Ensete ventricosum), a banana‐like plant widely cultivated in Ethiopia, showed the presence of bacilliform shaped virions as known for badnaviruses. DNA extracts subjected to rolling circle amplification (RCA), polymerase chain reaction (PCR) and cloning and sequence analysis revealed that the virus has a circular double‐stranded DNA genome of 7,163 nucleotides encoding predicted proteins of 21.5 kDa, 14.5 kDa and 202.5 kDa, a genome organization known for badnaviruses. The virus is phylogenetically most closely related to Sugarcane bacilliform Guadeloupe D virus with a nucleotide sequence identity of 77.2% at the conserved RT/RNase‐H region and 73.6% for the whole genome. Following the current species demarcation criteria, the virus should be considered as an isolate of a new species in the genus Badnavirus for which the name Enset leaf streak virus (ELSV) is suggested. Leaf samples from enset and banana were screened using virus‐specific primers, and ELSV was detected in six of 40 enset but not found in any of 61 banana samples. On the other hand, Banana streak OL virus (BSOLV) was detected from the majority (60%) of symptomatic banana samples but not from enset samples. This paper reports the first full‐genome sequence of a putative new badnavirus species infecting plants in the genus Ensete. In addition, this is the first report of the occurrence of BSOLV in Ethiopia.     

Unique genome replication mechanism of the archaeal virus AFV1

The exceptional genomic content and genome organization of the Acidianus filamentous virus 1 (AFV1) that infects the hyperthermophilic archaeon Acidianus hospitalis suggest that this virus might exploit an unusual mechanism of genome replication. An analysis of replicative intermediates of the viral genome by two‐dimensional (2D) agarose gel electrophoresis revealed that viral genome replication starts by the formation of a D‐loop and proceeds via strand displacement replication. Characterization of replicative intermediates using dark‐field electron microscopy, in combination with the 2D agarose gel electrophoresis data, suggests that recombination plays a key role in the termination of AFV1 genome replication through the formation of terminal loops. A terminal protein was found to be attached to the ends of the viral genome. The results allow us to postulate a model of genome replication that relies on recombination events for initiation and termination.     

MORE ACCURATE PHYLOGENIES INFERRED FROM LOW‐RECOMBINATION REGIONS IN THE PRESENCE OF INCOMPLETE LINEAGE SORTING

When speciation events occur in rapid succession, incomplete lineage sorting (ILS) can cause disagreement among individual gene trees. The probability that ILS affects a given locus is directly related to its effective population size (N_e), which in turn is proportional to the recombination rate if there is strong selection across the genome. Based on these expectations, we hypothesized that low‐recombination regions of the genome, as well as sex chromosomes and nonrecombining chromosomes, should exhibit lower levels of ILS. We tested this hypothesis in phylogenomic datasets from primates, the Drosophila melanogaster clade, and the Drosophila simulans clade. In all three cases, regions of the genome with low or no recombination showed significantly stronger support for the putative species tree, although results from the X chromosome differed among clades. Our results suggest that recurrent selection is acting in these low‐recombination regions, such that current levels of diversity also reflect past decreases in the effective population size at these same loci. The results also demonstrate how considering the genomic context of a gene tree can assist in more accurate determination of the true species phylogeny, especially in cases where a whole‐genome phylogeny appears to be an unresolvable polytomy.     

Isolation and characterization of a single‐stranded RNA virus that infects the marine planktonic diatom Chaetoceros sp. (SS08‐C03)

Diatoms are the major primary producers in the world's aquatic environment; hence, their dynamics are an important focus in current studies. Viruses, along with other physical, chemical, and biological factors, have recently been recognized as potential factors of diatom mortality. We isolated and characterized a new diatom virus (Csp03RNAV) that causes lysis of the marine planktonic diatom Chaetoceros sp. strain SS08‐C03 isolated from Hiroshima Bay, Japan. Here, we present the physiology, morphology, and genome characteristics of this virus. Csp03RNAV was isolated from surface waters of Yatsushiro Sea, Japan. Virions were icosahedral and 32 nm in diameter, and accumulated in the cytoplasm of the host cells. The latent period was estimated to be <48 h. Csp03RNAV harbors a single‐stranded RNA genome, which has 9417 bases encoding two open reading frames that code for putative replication‐related proteins and putative structural proteins, respectively. The monophyly of Csp03RNAV and the other known diatom‐infecting single‐stranded RNA viruses (genus Bacillarnavirus), Rhizosolenia setigera RNA virus, Chaetoceros socialis f. radians RNA virus, and Chaetoceros tenuissimus RNA virus was strongly supported by phylogenetic analysis based on the amino acid sequence of the RNA‐dependent RNA polymerase domain. On the basis of these results, Csp03RNAV is considered to be a new member of the genus Bacillarnavirus.     

Sequence Analysis of the Mitochondrial Genome of Sarcophyton glaucum: Conserved Gene Order Among Octocorals

The nucleotide sequence for an 11,715-bp segment of the mitochondrial genome of the octocoral Sarcophyton glaucum is presented, completing the analysis of the entire genome for this anthozoan member of the phylum Cnidaria. The genome contained the same 13 protein-coding and 2 ribosomal RNA genes as in other animals. However, it also included an unusual mismatch repair gene homologue reported previously and codes for only a single tRNA gene. Intermediate in length compared to two other cnidarians (17,443 and 18,911 bp), this organellar genome contained the smallest amount of noncoding DNA (428, compared to 1283 and 781 nt, respectively), making it the most compact one found for the phylum to date. The mitochondrial genes of S. glaucum exhibited an identical arrangement to that found in another octocoral, Renilla kolikeri, with five protein-coding genes in the same order as has been found in insect and vertebrate mitochondrial genomes. Although gene order appears to be highly conserved among octocorals, compared to the hexacoral, Metridium senile, few similarities were found. Like other metazoan mitochondrial genomes, the A + T composition was elevated and a general bias against codons ending in G or C was observed. However, an exception to this was the infrequent use of TGA compared to TGG to code for tryptophan. This divergent codon bias is unusual but appears to be a conserved feature among two rather distantly related anthozoans. Received: 27 January 1998 / Accepted: 25 May 1998     

Complete Genome Sequence,Phylogenetic Relationships and Molecular Diagnosis of an Indian Isolate of Potato Virus X

The complete genome of a Potato virus X (PVX) isolate from India (ptDel‐9), which occurred symptomlessly in potato but induced ringspots on Nicotiana tabacum cv. Xanthi and necrotic mosaic on Nicotiana benthamiana, was sequenced. The genome was 6435 nucleotides long ( JF430080 ) and contained five open reading frames. The isolate was closely related to those reported from the Eurasian region (95.1–97.1% sequence similarity) and distantly related to those reported from South America (77.2–77.9%). The CP gene was expressed in Escherichia coli as a 76‐kDa fusion protein with maltose‐binding protein and used to generate polyclonal antibodies, which successfully detected PVX in field samples of potato by ELISA. In 20% of field samples, for which ELISA failed, the virus was successfully detected by RT‐PCR. This is the first report of molecular characterization of PVX occurring in India.     

A Turnip crinkle virus Isolate Lacking the CP Counter‐Defence Protein Gene Providing Protection Against the Wild‐Type Strain is Associated with Highly Localized RNA Silencing

Cross‐protection has been used successfully and commercially to control a range of virus diseases for which the selection of suitable mild strains of plant viruses is necessary. Turnip crinkle virus (TCV) is highly pathogenic on Arabidopsis plants and its silencing suppressor‐defective mutant, TCVΔCP, can induce highly localized RNA silencing which is differs from that of other protective strains. We found that TCVΔCP provides some protection against wild‐type TCV but lacks complete protection, and the relative locations of the protective virus and challenge virus affect the degree of cross‐protection. However, similar cross‐protection afforded by TCVΔCP is not observed in Nicotiana benthamiana plants. As expected, TCVΔCP pre‐infected Arabidopsis plants fail to protect against infection with the unrelated Cucumber mosaic virus, strain Fhy. It appears that cross‐protection afforded by TCVΔCP requires that the challenge virus be very similar in sequence, which is a characteristic of RNA silencing. In order to investigate whether the protection is associated with the highly localized RNA silencing, mutant plants involved in key silencing pathway genes of RNA silencing machinery, including dcl2, dcl4 and triple dcl2/dcl3/dcl4 mutants were used. The results demonstrate that cross‐protection afforded by TCVΔCP is dependent on host RNA silencing, and both DCL2 and DCL4 play important roles in this process.     

EXPERIMENTAL EVOLUTION OF AN EMERGING PLANT VIRUS IN HOST GENOTYPES THAT DIFFER IN THEIR SUSCEPTIBILITY TO INFECTION

This study evaluates the extent to which genetic differences among host individuals from the same species condition the evolution of a plant RNA virus. We performed a threefold replicated evolution experiment in which Tobacco etch potyvirus isolate At17b (TEV‐At17b), adapted to Arabidopsis thaliana ecotype Ler‐0, was serially passaged in five genetically heterogeneous ecotypes of A. thaliana. After 15 passages we found that evolved viruses improved their fitness, showed higher infectivity and stronger virulence in their local host ecotypes. The genome of evolved lineages was sequenced and putative adaptive mutations identified. Host‐driven convergent mutations have been identified. Evidences supported selection for increased translational efficiency. Next, we sought for the specificity of virus adaptation by infecting all five ecotypes with all 15 evolved virus populations. We found that some ecotypes were more permissive to infection than others, and that some evolved virus isolates were more specialist/generalist than others. The bipartite network linking ecotypes with evolved viruses was significantly nested but not modular, suggesting that hard‐to‐infect ecotypes were infected by generalist viruses whereas easy‐to‐infect ecotypes were infected by all viruses, as predicted by a gene‐for‐gene model of infection.     

A genome‐wide SNP scan reveals two loci associated with the chicken resistance to Marek's disease

Marek's disease (MD) is a neoplastic disease in chickens, caused by the Marek's disease virus (MDV). To investigate host genetic resistance to MD, we conducted a genome‐wide association study (GWAS) on 67 MDV‐infected chickens based on a case and control design, including 57 susceptible chickens in the case group and 10 resistant chickens as controls. After searching 38 655 valid genomic markers, two SNPs were found to be associated with host resistance to MD. One SNP, rs14527240, reaching chromosome‐wide significance level (P < 0.01) was located in the SPARC‐related modular calcium‐binding 1 (SMOC1) gene on GGA5. The other one, GGaluGA156129, reaching genome‐wide significance (P < 0.05), was located in the protein tyrosine phosphatase, non‐receptor type 3 (PTPN3) gene on GGA2. In addition, expression patterns of these two genes in spleens were detected by qPCR. The expression of SMOC1 was significantly up‐regulated (P < 0.05), whereas the expression of PTNP3 did not show significance when the case group was compared with the control group. Up‐regulation of SMOC1 in susceptible spleens suggests its important roles in MD tumorigenesis. This is the first study to investigate MD‐resistant loci, and it demonstrates the power of GWASs for mapping genes associated with MD resistance.     

Genome characterization of an extensively drug‐resistant Streptococcus pneumoniae serotype 11A strain

In this study, the whole genome sequences of two Streptococcus pneumoniae clinical isolates from South Korea were determined and compared. They were found to be the same serotype (11 A) and multilocus sequence typing analysis showed that they are single‐locus variants (SLVs; ST8279 and ST166) of each other, differing at one allele (aroE). However, the ST8279 strain is extensively drug‐resistant (XDR) whereas the ST166 strain is not. The genome of the XDR strain is very similar in structure to that of two previously reported genomes, AP200 (11 A:ST62) and 70585 (5:ST5803); however, some regions were inverted and there were some exogenous regions in the ST8279 strain. It was found that 6,502 single nucleotide polymorphisms are dispersed across the genome between the two serotype 11 A ST8279 and ST166 strains. Many of them are located in genes associated with antibiotic resistance. In addition, many amino acid differences were also identified in genes involved in DNA repair (mutL, uvrA and uvrC) and recombination (recU, recR and recA). On the basis of these results, it was inferred that the XDR strain did not evolve from its SLV via a single recombination event involving a large portion of the genome including the aroE gene. Rather, the strain likely evolved through many point mutations and recombination events involving small portions of the genome.     

Complete mitochondrial genome of a carabid beetle,Damaster mirabilissimus mirabilissim (Coleoptera: Carabidae)

In the present study, we report the 16 823‐bp long complete mitochondrial genome (mitogenome) of a carabid beetle, Damaster mirabilissimus mirabilissim (Coleoptera: Carabidae), which is endangered in Korea. The gene arrangement of D. m. mirabilissim mitogenome is identical to the most common type found in insects. The start codon of the D. m. mirabilissim COI gene is a typical ATN codon. On the other hand, the initiation codon for ND1 gene is TTG, instead of ATN. All transfer RNAs (tRNAs) exhibit a stable canonical clover‐leaf structure, except for tRNA^Ser(AGN), the dihydrouridine arm of which forms a simple loop. The 1703‐bp long A+T‐rich region is the second longest among the complete adephagan mitogenome sequences, next to Macrogyrus oblongus belonging to Gyrinoidea. One of the unusual features of the genome is the presence of a tRNA^Leu(UUR)‐like sequence in the A+T‐rich region. This sequence displays the proper anticodon sequence and the potential to form secondary structures, but also harbors many mismatches in the stems.     

Genome plasticity in response to stress in Tetrahymena thermophila: selective and reversible chromosome amplification and paralogous expansion of metallothionein genes

Extreme stress situations can induce genetic variations including genome reorganization. In ciliates like Tetrahymena thermophila, the approximately 45‐fold ploidy of the somatic macronucleus may enable adaptive responses that depend on genome plasticity. To identify potential genome‐level adaptations related to metal toxicity, we isolated three Tetrahymena thermophila strains after an extended adaptation period to extreme metal concentrations (Cd²⁺, Cu²⁺ or Pb²⁺). In the Cd‐adapted strain, we found a approximately five‐fold copy number increase of three genes located in the same macronuclear chromosome, including two metallothionein genes, MTT1 and MTT3. The apparent amplification of this macronuclear chromosome was reversible and reproducible, depending on the presence of environmental metal. We also analysed three knockout (KO) and/or knockdown (KD) strains for MTT1 and/or MTT5. In the MTT5KD strain, we found at least two new genes arising from paralogous expansion of MTT1, which encode truncated variants of MTT1. The expansion can be explained by a model based on somatic recombination between MTT1 genes on pairs of macronuclear chromosomes. At least two of the new paralogs are transcribed and upregulated in response to Cd²⁺. Altogether, we have thus identified two distinct mechanisms, both involving genomic plasticity in the polyploid macronucleus that may represent adaptive responses to metal‐related stress.     

Characterization of two temperature-sensitive mutants of Sigma virus (authors transl)

Summary Temperature-sensitive mutants have been isolated from Drosophila Sigma virus, a Rhabdovirus inducing CO₂ sensitivity in Drosophila melanogaster. We have studied the decay of infectious centers at non permissive temperature. The proportion of destroyed infectious centers is the same for the wild type, ts⁺, and for ts9. On the opposite, it is more important for ts 4. Temperature-sensitive function of ts 4 appears necessary to the viral genome replication. With the three clones, ts⁺, ts 4 and ts 9, we have obtained stabilized Drosophila females able to transmit Sigma virus to their whole progeny. We have tried to see in each case, if stabilized flies could transmit the virus to their progeny at non permissive temperature. Flies stabilized with ts⁺ and ts 9 can, flies stabilized with ts 4 cannot. Therefore two categories of mutants are defined: those that are transmitted hereditarily. at non permissive temperature, and not blocked in genome replication. Those that are blocked in genome replication and not transmitted. When the virus cannot replicate, the divisions in the germ line cells dilute the viral genomes. The consequence will be a real healing of germ line cells, and then a break in hereditary transmission by stabilized flies. All the results with temperature-sensitive mutants are coherent with this hypothesis.

---

Étude de mutants thermosensibles du virus Sigma

---

Mémoire présenté par F. Gros     

Historical geographic dispersal of the golden snub-nosed monkey (Rhinopithecus roxellana) and the influence of climatic oscillations

Current understanding of historic climate oscillations that have occurred over the past few million years has modified scientific views on evolution. Major climatic events have caused local and global extinction of plants and animals and have impacted the spatial distribution of many species. The endangered golden snub‐nosed monkey (Rhinopithecus roxellana) currently inhabits three isolated regions of China: the Sichuan and Gansu provinces (SG), the Qinling Mountains in Shaanxi province (QL), and the Shennongjia Forestry District in Hubei province (SNJ). However, considerable uncertainty still exists about their historical dispersal routes under the influence of environment change. To date, two dispersal routes have been proposed: (1) the QL and SNJ populations originated from the SG population; and (2) the SG population recolonized from the QL and SNJ populations. We used the mitochondrial DNA complete control region to perform statistical assessments of the relative probability of alternative migration scenarios and the role of environmental change on the geographic dispersal of Rhinopithecus roxellana. Thirty haplotypes were identified from the three geographic regions and a high degree of genetic structure was observed. The most recent common ancestor among the mitochondrial DNA haplotypes was estimated to live around 0.47–1.88 million years ago and five notable haplotype clusters were found. Phylogenetic analysis and historical gene flow estimates suggested that the QL and SNJ populations originated from the SG population, with at least two dispersal events from the SG population occurring during the Pleistocene (1.17±0.70 and 0.53±0.30 Ma). Composite dispersal history of the golden snub‐nosed monkey can be explained by both environmental change inducing global climate change and the influence of the Tibetan Plateau uplift. Such range shifts involved considerable demographic changes, as revealed in the dramatic decreases in population size during the last 25,000 years.     

Antiviral activity of extracts from Morinda citrifolia leaves and chlorophyll catabolites,pheophorbide a and pyropheophorbide a,against hepatitis C virus

The development of complementary and/or alternative drugs for treatment of hepatitis C virus (HCV) infection is still needed. Antiviral compounds in medicinal plants are potentially good targets to study. Morinda citrifolia is a common plant distributed widely in Indo‐Pacific region; its fruits and leaves are food sources and are also used as a treatment in traditional medicine. In this study, using a HCV cell culture system, it was demonstrated that a methanol extract, its n‐hexane, and ethyl acetate fractions from M. citrifolia leaves possess anti‐HCV activities with 50%‐inhibitory concentrations (IC₅₀) of 20.6, 6.1, and 6.6 μg/mL, respectively. Bioactivity‐guided purification and structural analysis led to isolation and identification of pheophorbide a, the major catabolite of chlorophyll a, as an anti‐HCV compound present in the extracts (IC₅₀ = 0.3 μg/mL). It was also found that pyropheophorbide a possesses anti‐HCV activity (IC₅₀ = 0.2 μg/mL). The 50%‐cytotoxic concentrations (CC₅₀) of pheophorbide a and pyropheophorbide a were 10.0 and 7.2 μg/mL, respectively, their selectivity indexes being 33 and 36, respectively. On the other hand, chlorophyll a, sodium copper chlorophyllin, and pheophytin a barely, or only marginally, exhibited anti‐HCV activities. Time‐of‐addition analysis revealed that pheophorbide a and pyropheophorbide a act at both entry and the post‐entry steps. The present results suggest that pheophorbide a and its related compounds would be good candidates for seed compounds for developing antivirals against HCV.     

Biogenesis of photosynthetic complexes in the chloroplast of Chlamydomonas reinhardtii requires ARSA1, a homolog of prokaryotic arsenite transporter and eukaryotic TRC40 for guided entry of tail‐anchored proteins

as1, for antenna size mutant 1, was obtained by insertion mutagenesis of the unicellular green alga Chlamydomonas reinhardtii. This strain has a low chlorophyll content, 8% with respect to the wild type, and displays a general reduction in thylakoid polypeptides. The mutant was found to carry an insertion into a homologous gene, prokaryotic arsenite transporter (ARSA), whose yeast and mammal counterparts were found to be involved in the targeting of tail‐anchored (TA) proteins to cytosol‐exposed membranes, essential for several cellular functions. Here we present the characterization in a photosynthetic organism of an insertion mutant in an ARSA‐homolog gene. The ARSA1 protein was found to be localized in the cytosol, and yet its absence in as1 leads to a small chloroplast and a strongly decreased chlorophyll content per cell. ARSA1 appears to be required for optimal biogenesis of photosynthetic complexes because of its involvement in the accumulation of TOC34, an essential component of the outer chloroplast membrane translocon (TOC) complex, which, in turn, catalyzes the import of nucleus‐encoded precursor polypeptides into the chloroplast. Remarkably, the effect of the mutation appears to be restricted to biogenesis of chlorophyll‐binding polypeptides and is not compensated by the other ARSA homolog encoded by the C. reinhardtii genome, implying a non‐redundant function.