Genetic Diversity and Molecular Evolution of Plum bark necrosis stem pitting-associated virus from China

Plum bark necrosis stem pitting-associated virus (PBNSPaV), a member of the genus Ampelovirus in the family Closteroviridae, infects different Prunus species and has a worldwide distribution. Yet the population structure and genetic diversity of the virus is still unclear. In this study, sequence analyses of a partial heat shock protein 70 homolog (HSP70h) gene and coat protein (CP) gene of PBNSPaV isolates from seven Prunus species grown in China revealed a highly divergent Chinese PBNSPaV population, sharing nucleotide similarities of 73.1–100% with HSP70h gene, and 83.9–98.6% with CP gene. Phylogenetic analysis of HSP70h and CP sequences revealed segregation of global PBNSPaV isolates into four phylo-groups (I–IV), of which two newly identified groups, II and IV, solely comprised Chinese isolates. Complete genome sequences of three PBNSPaV isolates, Pch-WH-1 and Pch-GS-3 from peaches, and Plm-WH-3 from a plum tree, were determined. The three isolates showed overall nucleotide identities of 90.0% (Pch-GS-3) and 96.4% (Pch-WH-1) with the type isolate PL186, and the lowest identity of 70.2–71.2% with isolate Nanjing. For the first time, to the best of our knowledge, we report evidence of significant recombination in the HSP70h gene of PBNSPaV variant Pch2 by using five programs implemented in RDP3; in addition, five codon positions in its CP gene (3, 8, 44, 57, and 88) were identified that appeared to be under positive selection. Collectively, these results indicate a divergent Chinese PBNSPaV population. In addition, our findings provide a foundation for elucidating the epidemiological characteristics of virus population.     

Isolation and Genomic Characterization of a Duck-Origin GPV-Related Parvovirus from Cherry Valley Ducklings in China

A newly emerged duck parvovirus, which causes beak atrophy and dwarfism syndrome (BADS) in Cherry Valley ducks, has appeared in Northern China since March 2015. To explore the genetic diversity among waterfowl parvovirus isolates, the complete genome of an identified isolate designated SDLC01 was sequenced and analyzed in the present study. Genomic sequence analysis showed that SDLC01 shared 90.8%–94.6% of nucleotide identity with goose parvovirus (GPV) isolates and 78.6%–81.6% of nucleotide identity with classical Muscovy duck parvovirus (MDPV) isolates. Phylogenetic analysis of 443 nucleotides (nt) of the fragment A showed that SDLC01 was highly similar to a mule duck isolate (strain D146/02) and close to European GPV isolates but separate from Asian GPV isolates. Analysis of the left inverted terminal repeat regions revealed that SDLC01 had two major segments deleted between positions 160–176 and 306–322 nt compared with field GPV and MDPV isolates. Phylogenetic analysis of Rep and VP1 encoded by two major open reading frames of parvoviruses revealed that SDLC01 was distinct from all GPV and MDPV isolates. The viral pathogenicity and genome characterization of SDLC01 suggest that the novel GPV (N-GPV) is the causative agent of BADS and belongs to a distinct GPV-related subgroup. Furthermore, N-GPV sequences were detected in diseased ducks by polymerase chain reaction and viral proliferation was demonstrated in duck embryos and duck embryo fibroblast cells.     

Low Genetic Diversity of the Coat Protein Gene among Blueberry Red Ringspot Virus Isolates

Blueberry red ringspot virus (BRRSV) isolates have been investigated for genetic diversity. Nucleotide sequences of the coat protein (CP) gene of 19 isolates from Poland, Czech Republic, Slovenia and the United States were analysed. The nucleotide and amino acid sequence identity were 92–100% and 89–100%, respectively. Estimations of the distribution of synonymous and non‐synonymous changes indicated negative selection within the analysed CP gene and confirmed the genetic stability of the virus. At a capsid protein level, our results revealed BRRSV to be distinct from other, recombination‐prone pararetroviruses.     

In Vitro and In Vivo Studies of the RNA Conformational Switch in Alfalfa Mosaic Virus

The 3′ termini of Alfalfa mosaic virus (AMV) RNAs adopt two mutually exclusive conformations, a coat protein binding (CPB) and a tRNA-like (TL) conformer, which consist of a linear array of stem-loop structures and a pseudoknot structure, respectively. Previously, switching between CPB and TL conformers has been proposed as a mechanism to regulate the competing processes of translation and replication of the viral RNA (R. C. L. Olsthoorn et al., EMBO J. 18:4856-4864, 1999). In the present study, the switch between CPB and TL conformers was further investigated. First, we showed that recognition of the AMV 3′ untranslated region (UTR) by a tRNA-specific enzyme (CCA-adding enzyme) in vitro is more efficient when the distribution is shifted toward the TL conformation. Second, the recognition of the 3′ UTR by the viral replicase was similarly dependent on the ratio of CBP and TL conformers. Furthermore, the addition of CP, which is expected to shift the distribution toward the CPB conformer, inhibited recognition by the CCA-adding enzyme and the replicase. Finally, we monitored how the binding affinity to CP is affected by this conformational switch in the yeast three-hybrid system. Here, disruption of the pseudoknot enhanced the binding affinity to CP by shifting the balance in favor of the CPB conformer, whereas stabilizing the pseudoknot did the reverse. Together, the in vitro and in vivo data clearly demonstrate the existence of the conformational switch in the 3′ UTR of AMV RNAs.Alfalfa mosaic virus (AMV) is a plant virus that belongs to one of the five genera in the family Bromoviridae, whose genomes consist of three genomic RNAs (RNAs 1, 2, and 3) and one subgenomic RNA (RNA4) that are capped at the 5′ end and lack polyadenylation at the 3′ terminus (3). RNAs 1 and 2 encode the viral subunits P1 and P2 of the replicase, respectively. RNA3 encodes the movement protein and serves as a template for the synthesis of RNA4, which encodes the coat protein (CP).The role of AMV CP has been the subject of extensive research in the past four decades. Initially, it was found that, in contrast to RNAs of the Bromo-, Cucumo-, and Oleavirus genera, the genomic RNAs of AMV and the closely related genus Ilarvirus were not infectious as such but required the presence of CP in the inoculum (15). This phenomenon was called genome activation and was long considered to compensate for the lack of a tRNA-like structure (TLS) at the 3′ end of their genomic RNAs, a prominent feature of bromo- and cucumovirus RNAs (3). However, in 1999 we demonstrated that the 3′ end of AMV RNAs can adopt an alternative conformation that shows many structural similarities to the TLS of other Bromoviridae, although it could not be charged with an amino acid (20). The tRNA-like (TL) conformation (Fig. ​(Fig.1)1) turned out to be the replicative form of the 3′ termini (19, 20), whereas the other, coat protein binding (CPB), conformer was subsequently shown to be required for translation (16-18). Although other models have been forwarded (9), we have proposed that switching between these two conformations, mediated by CP binding, plays a fundamental role in the life cycle of AMV and ilarviruses by regulating the competing processes of translation and replication of the viral RNAs.Open in a separate windowFIG. 1.The CPB and the TL conformations of the AMV RNA3 3′ terminus. The two conformers of AMV RNA3 3′ 145 nt are shown. (A) CPB conformer. The two major CP binding sites are indicated by brackets. Base pairing between loop D and stem A promotes TL conformation. (B) Secondary structure of the TL conformer.In the present study, the distribution between CPB and TL conformers was further investigated. We addressed how changes in this distribution would affect recognition of the AMV 3′ untranslated region (UTR) by a tRNA-specific enzyme (CCA-adding ezyme) and the viral polymerase in vitro. We also monitored how the binding affinity to CP is affected by this conformational switch in vivo using the yeast three-hybrid (Y3H) system (2, 11, 24). Together, the in vitro and in vivo data clearly demonstrate the existence and function of the conformational switch in the 3′ UTR of AMV RNAs.     

Identification of an Internal RNA Element Essential for Replication and Translational Enhancement of Tobacco Necrosis Virus A C

Different regulatory elements function are involved in plant virus gene expression and replication by long-distance RNA-RNA interactions. A cap-independent functional element of the Barley yellow dwarf virus (BYDV) – like translational enhancer (BTE) is present in Tobacco necrosis virus A (TNV-A), a Necrovirus member in the Tombusviridae family. In this paper, an RNA stretch flanking the 5′ proximal end of the TNV-A^C coat protein (CP) gene was shown to be essential for viral replication in Chenopodium amaranticolor plants and tobacco cells. This internal sequence functioned in transient expression of β-glucuronidase (GUS) when present at either the 5′ or 3′ sides of the GUS open reading frame. Serial deletion analyses revealed that nine nucleotides from nt 2609 to 2617 (−3 to +6 of the CP initiation site) within TNV-A^C RNA are indispensable for viral replication in whole plants and tobacco cells. Fusion of this RNA element in mRNAs translated in tobacco cells resulted in a remarkable enhancement of luciferase expression from in vitro synthesised chimaeric RNAs or DNA expression vectors. Interestingly, the element also exhibited increased translational activity when fused downstream of the reporter genes, although the efficiency was lower than with upstream fusions. These results provide evidence that an internal RNA element in the genomic (g) RNA of TNV-A^C, ranging approximately from nt 2543 to 2617, plays a bifunctional role in viral replication and translation enhancement during infection, and that this element may use novel strategies differing from those previously reported for other viruses.     

Global Analysis of Rice Tungro Spherical Virus Coat Proteins Reveals New Roles in Evolutionary Consequences

Rice tungro disease is caused by a combination of two viruses: Rice tungro spherical virus (RTSV) and Rice tungro bacilliform virus (RTBV). RTSV has a capsid comprising three coat proteins (CP) species. Three CP genes of RTSV-AP isolate were sequenced and compared with 9 other isolates reported worldwide for their phylogenetic survey of recombination events which revealed that in general Indian isolates are forming one separate cluster while those of Philippines and Malaysia forming a different cluster. A significant proportion of recombination sites were found in the CP1 gene, followed by CP2 and CP3 suggesting that it is a major phenomenon in the evolution of various isolates of RTSV. Some interesting domains and motifs such as; 3,4-dihydroxy-2-butanone 4-phosphate synthase in CP1, Type 1 glutamine amidotransferase domain and RNA binding motifs in CP2, domains of receptor proteins in CP3, and glycosylation motif in CP2 and CP3 were also obtained in RTSV coat protein. In addition, simple modular architecture research tool (SMART) analysis of coat proteins of RTSV predicted the coat protein domain of calicivirus suggesting evolutionary linkages between plant and animal viruses. This study provides an opportunity to establish the molecular evolution and sequence-function relationship of RTSV.     

Intra-farm diversity and evidence of genetic recombination of Citrus tristeza virus in Delhi region of India

Infection of Citrus tristeza virus (CTV) in different citrus orchards of New Delhi was detected by direct antigen coated-ELISA and RT-PCR. Sweet orange (Citrus sinensis) orchards were found to be susceptible to CTV with estimated disease incidence up to 39%. Kagzi kalan (C. lemon), Pumello (C. paradisi) and Kinnow mandarin (C. reticulata) orchards did not show CTV infection. Three CTV isolates, D1, D7 and D15 randomly selected from infected sweet orange orchards were considered for biological and molecular characterization. In the host range study, all the Delhi isolates infected Darjeeling mandarin (C. reticulata), Kagzi lime (C. aurantifolia), sour orange (C. aurantium) and sweet orange but not Kinnow mandarin. A fragment of 5??ORF1a and complete coat protein (CP) gene of these three isolates were cloned, sequenced and compared with other Indian and international CTV isolates. Delhi isolates shared 85?C92% sequence identity for 5??ORF1a fragment and 89?C91% for CP gene among them. Phylogenetic analysis segregated three Delhi isolates into three genogroups for each of 5??ORF1a fragment and CP gene, however phylogenetic relationships for both the genomic regions was incongruent. Recombination detecting program RDP3 detected CTV isolate D7 as recombinant, indicating genetic variability in CTV isolates might be the outcome of recombination events between divergent CTV sequences. An attempt was made in present study to characterize CTV isolates biologically and at genetic level, and to determine genetic diversity at farm level and study the recombination of CTV isolates in Delhi region.     

番木瓜环斑病毒海南分离株全基因组序列分析

番木瓜环斑病毒(Papaya ringspot virus,PRSV)是马铃薯Y病毒属(genus Potyvirus)的成员之一.病毒粒体呈线状,长700～900nm,直径为12.5nm.为单分体正链RNA病毒,由多种蚜虫以非持久方式传播.依寄主范围可划分为P型和W型两种.其中P型株系(PRSV-P)是制约生产的重要病原,除了给番木瓜生产带来严重危害,也会危害葫芦科作物.W型株系(PRSV-W)是危害葫芦科作物的主要病原,虽然和PRSV-P型株系血清学反应密切相关,但不侵染番木瓜.     

Comparative genomic analyses of freshly isolated Giardia intestinalis assemblage A isolates

Background

The diarrhea-causing protozoan Giardia intestinalis makes up a species complex of eight different assemblages (A-H), where assemblage A and B infect humans. Comparative whole-genome analyses of three of these assemblages have shown that there is significant divergence at the inter-assemblage level, however little is currently known regarding variation at the intra-assemblage level. We have performed whole genome sequencing of two sub-assemblage AII isolates, recently axenized from symptomatic human patients, to study the biological and genetic diversity within assemblage A isolates.

Results

Several biological differences between the new and earlier characterized assemblage A isolates were identified, including a difference in growth medium preference. The two AII isolates were of different sub-assemblage types (AII-1 [AS175] and AII-2 [AS98]) and showed size differences in the smallest chromosomes. The amount of genetic diversity was characterized in relation to the genome of the Giardia reference isolate WB, an assemblage AI isolate. Our analyses indicate that the divergence between AI and AII is approximately 1 %, represented by ~100,000 single nucleotide polymorphisms (SNP) distributed over the chromosomes with enrichment in variable genomic regions containing surface antigens. The level of allelic sequence heterozygosity (ASH) in the two AII isolates was found to be 0.25–0.35 %, which is 25–30 fold higher than in the WB isolate and 10 fold higher than the assemblage AII isolate DH (0.037 %). 35 protein-encoding genes, not found in the WB genome, were identified in the two AII genomes. The large gene families of variant-specific surface proteins (VSPs) and high cysteine membrane proteins (HCMPs) showed isolate-specific divergences of the gene repertoires. Certain genes, often in small gene families with 2 to 8 members, localize to the variable regions of the genomes and show high sequence diversity between the assemblage A isolates. One of the families, Bactericidal/Permeability Increasing-like protein (BPIL), with eight members was characterized further and the proteins were shown to localize to the ER in trophozoites.

Conclusions

Giardia genomes are modular with highly conserved core regions mixed up by variable regions containing high levels of ASH, SNPs and variable surface antigens. There are significant genomic variations in assemblage A isolates, in terms of chromosome size, gene content, surface protein repertoire and gene polymorphisms and these differences mainly localize to the variable regions of the genomes. The large genetic differences within one assemblage of G. intestinalis strengthen the argument that the assemblages represent different Giardia species.

Electronic supplementary material

The online version of this article (doi:10.1186/s12864-015-1893-6) contains supplementary material, which is available to authorized users.     

Viral Coat Protein Peptides with Limited Sequence Homology Bind Similar Domains of Alfalfa Mosaic Virus and Tobacco Streak Virus RNAs

An unusual and distinguishing feature of alfalfa mosaic virus (AMV) and ilarviruses such as tobacco streak virus (TSV) is that the viral coat protein is required to activate the early stages of viral RNA replication, a phenomenon known as genome activation. AMV-TSV coat protein homology is limited; however, they are functionally interchangeable in activating virus replication. For example, TSV coat protein will activate AMV RNA replication and vice versa. Although AMV and TSV coat proteins have little obvious amino acid homology, we recently reported that they share an N-terminal RNA binding consensus sequence (Ansel-McKinney et al., EMBO J. 15:5077–5084, 1996). Here, we biochemically compare the binding of chemically synthesized peptides that include the consensus RNA binding sequence and lysine-rich (AMV) or arginine-rich (TSV) environment to 3′-terminal TSV and AMV RNA fragments. The arginine-rich TSV coat protein peptide binds viral RNA with lower affinity than the lysine-rich AMV coat protein peptides; however, the ribose moieties protected from hydroxyl radical attack by the two different peptides are localized in the same area of the predicted RNA structures. When included in an infectious inoculum, both AMV and TSV 3′-terminal RNA fragments inhibited AMV RNA replication, while variant RNAs unable to bind coat protein did not affect replication significantly. The data suggest that RNA binding and genome activation functions may reside in the consensus RNA binding sequence that is apparently unique to AMV and ilarvirus coat proteins.     

Analysis of Coat Protein of Peanut stunt virus Subgroup II Isolates from Alfalfa Fields in West Iran

Alfalfa fields in three western provinces of Iran were surveyed for Peanut stunt virus (PSV) during 2011 and 2012. Forty‐seven of 115 samples tested (41%) were infected with PSV. Phylogenetic analysis using coat protein (CP) gene sequences showed that the Iranian isolates belong to the subgroup II of PSV. Pairwise identity analysis revealed four groups representing four phylogenetic subgroups. PSV strains in subgroups III and IV are closely related to each other, as supported by the lowest nucleotide diversity, high pairwise nucleotide identity and high haplotype diversity as evidence of a recent population expansion after a genetic bottleneck. Using the maximum likelihood method, amino acid 86S in the CP gene of the Iranian PSV isolates was found to be under positive selection, although the likelihood ratio test statistics is not significant. This is the first report of the occurrence and phylogenetic relationships of Iranian PSV isolates in west Iran.     

番木瓜环斑病毒畸叶株系的CP基因克隆和序列分析

采用RT－PCR方法合成了本研究室保存的番木瓜畸叶病毒（PMaLV）的外壳蛋白（CP）基因,将其CP基因克隆进Promega公司的pGEM-T and pGEM-T Easy Vector System（简称T－载体）,并进行了序列分析。结果表明,PMaLV CP基因核苷酸序列全长为861nt,推导其编码287个氨基酸。与番木瓜环斑病毒（PRSV）美国夏威HA株系和澳大利亚W株系的CP基因相比,在第66nt处开始连续缺失3个核苷酸。与PRSV的华南Ys、Sm和G株系以及夏威夷的HA和澳大利亚的W株系相比,其CP基因序列同源率分别为96％、98％、95％、89％和89％。其的氨基酸序列同源率分别为98％、97％、97％、96％和95％。此结果表明,PMaLV属于PRSV的一个株系,不是一种新病毒。因此,我们称其为番木瓜环斑病毒畸叶株系（ML株系）。     

Molecular characterization of Indian Sugarcane streak mosaic virus isolates reveals recombination and negative selection in the P1 gene

Sugarcane streak mosaic virus (SCSMV), a member of the genus Poacevirus is an important viral pathogen affecting sugarcane production in India. The P1 gene of ten Indian isolates was sequenced and compared with previously reported SCSMV isolates. Comparative sequence analysis revealed a high level of diversity in the P1 gene (83–98% nucleotide sequence identity; 87–100% amino acid sequence identity), and the Indian SCSMV isolates were found to be the most variable (up to 9% diversity at the amino acid level). Phylogenetic tree analysis showed clustering of 17 SCSMV isolates into two groups: group I included isolates from India (except SCSMV-TPT) and Pakistan, and group II consisted of isolates from Japan, Indonesia, Thailand and SCSMV-TPT. The results obtained from phylogenetic study were further supported by the different in silico analysis viz. SNPs (single nucleotide polymorphism), INDELs (insertion and deletion) and evolutionary distance analysis. A significant proportion of recombination sites were observed at the N terminal region of P1 gene. Analysis of selection pressure indicated that the P1 gene of the Indian SCSMV isolates is under strong negative or purifying selection. It is likely that recombination identified in Indian SCSMV isolates, along with strong purifying selection, enhances the speed of elimination of deleterious mutations in the P1 gene. The evolutionary processes (recombination and selection pressure) together contributed to the observed genetic diversity and population structure of Indian SCSMV isolates.     

Analysis of the Coat Protein Gene of Indian Strain of Apple Stem Grooving Virus

A survey was undertaken in the temperate fruit growing regions of Himachal Pradesh (HP) and Jammu & Kashmir (J&K). Apple stem grooving virus (ASGV), a Capillovirus, was detected in different cultivars of apple, nectarines, plum, cherry, quince and apricot by double antibody sandwich ELISA (DAS-ELISA). The coat protein (CP) gene sequence of an amplicon produced by RT-PCR, confirmed the association of ASGV in apple cultivar Starkrimson, collected from Himachal Pradesh. The CP of Indian ASGV isolate shared 100 % sequence identity with a Brazilian isolate (AF438409). Sequence analysis by Recombination Detection Program (RDP2) indicated no recombination event for the Indian isolate. However, recombination was detected in Chinese, Korean and Citrus tatter leaf virus-Taiwan (CTLV) strains of ASGV. The study describes first report of ASGV infection in India and characterization of its CP gene.     

cis Elements Required for High-Level Expression of Unspliced gag-Containing Message in Moloney Murine Leukemia Virus

The 441-nucleotide (nt) region (nt 5325 to 5766) around the splice acceptor (SA) site (nt 5491) was found to be necessary for high-level expression of gag-containing unspliced RNA of Moloney murine leukemia virus (M. Oshima, T. Odawara, T. Matano, H. Sakahira, K. Kuchino, A. Iwamoto, and H. Yoshikura, J. Virol. 70:2286–2295, 1996). Detailed genetic dissection of the 441-nt region revealed that the 5′-end 64 nt (nt 5325 to 5389) were necessary for high-level expression of the unspliced RNA when the spliced RNA was not produced, while the 3′-side 301 nt (nt 5466 to 5766) containing the SA site were necessary for producing spliced RNA. When the spliced RNA was produced, the unspliced RNA could be expressed at a high level even when the 5′-end 64 nt were absent. Probably the virus sequence ensuring the splicing could produce an RNA structure able to compensate for the function of the 5′-end 64-nt region responsible for the expression of the unspliced RNA.