The ribosomal transcription units of five echinostomes and their taxonomic implications for the suborder Echinostomata (Trematoda: Platyhelminthes).

Five newly obtained nuclear ribosomal transcription unit (rTU) sequences from Echinostomatidae and Echinochasmidae are presented. The inter- and intrafamilial relationships of these and other families in the suborder Echinostomata are also analyzed. The sequences obtained are the complete rTU of Artyfechinostomum malayanum (9,499 bp), the near-complete rTU of Hypoderaeum conoideum (8,076 bp), and the coding regions (from 5'-terminus of 18S to 3'-terminus of 28S rRNA gene) in Echinostoma revolutum (6,856 bp), Echinostoma miyagawai (6,854 bp), and Echinochasmus japonicus (7,150 bp). Except for the longer first internal transcribed spacer (ITS1) in Echinochasmus japonicus, all genes and spacers were almost identical in length. Comprehensive maximum-likelihood phylogenies were constructed using the PhyML software package. The datasets were either the concatenated 28S + 18S rDNA sequences (5.7-5.8 kb) from 60 complete rTUs of 19 families or complete 28S sequences only (about 3.8-3.9 kb) from 70 strains or species of 22 families. The phylogenetic trees confirmed Echinostomatoidea as monophyletic. Furthermore, a detailed phylogeny constructed from alignments of 169 28S D1-D3 rDNA sequences (1.1-1.3 kb) from 98 species of 50 genera of 10 families, including 154 echinostomatoid sequences (85 species/42 genera), clearly indicated known generic relationships within Echinostomatidae and Echinochasmidae and relationships of families within Echinostomata and several other suborders. Within Echinostomatidae, Echinostoma, Artyfechinostomum, and Hypoderaeum appeared as monophyletic, while Echinochasmus (Echinochasmidae) was polyphyletic. The Echinochasmidae are a sister group to the Psilostomidae. The datasets provided here will be useful for taxonomic reappraisal as well as studies of evolutionary and population genetics in the superfamily Echinostomatoidea, the sole superfamily in the suborder Echinostomata.

Molecular characterization of field isolates of infectious bursal disease virus from three decades, 1987-2018, reveals a distinct genotypic subgroup in Vietnam.

The complete nucleotide sequence of the viral protein 2 (VP2) ORF was determined for 26 Vietnamese infectious bursal disease isolates collected from clinical outbreaks in vaccinated flocks from 1987 to 2018 and two commercial vaccine specimens. These sequences were compared for molecular classification with 42 reference strains representing all four main classes of serotype 1, including very virulent (vvIBDV), classical (cvIBDV), antigenic variant (avIBDV) and attenuated (atIBDV) strains, and serotype 2 strains. Amino acids at nine key positions in the VP2-HVR in 20 Vietnamese isolates, A222, I242, Q253, I256, D279, A284, I294, S299, A329, which are typical of the vvIBDV class, were found to be identical in all of the isolates. Eighteen of these isolates had a unique change at residue 212 (D212N) located in the PAB loop. Phylogenetic analysis revealed a distinct lineage/subclade with strong nodal support (96%) that included recent Chinese IBDV strains that were distinct from typical vvIBDVs. Six isolates contained the amino acid substitutions P222, V242, Q253, V256, D279, A284, I294, N299, A329, which are present in two vaccine strains derived from strain 2512 and these isolates were also closely related to the classical virulent STC strain. Data from this study show that there is considerable genetic diversity among vvIBDVs, which vary according to geographic region. Antigenic drift and differences in genetic characteristics between virulent strains and IBDV vaccine strains may be the cause of vaccine failure. Better antigenic matching of vaccines to the strains circulating in Vietnam is therefore required.

Molecular genotyping of duck hepatitis A viruses (DHAV) in Vietnam.

INTRODUCTION: The aim of this study was to identify the genetic characteristics and molecular genotyping of duck hepatitis A virus (DHAV) isolated in Vietnam during 2009-2013. METHODOLOGY: Thirty duckling livers from outbreaks between 2009 and 2013 in seven provinces were collected and identified by polymerase chain reaction (PCR). Then, VP1 genes of eleven positive samples and two attenuated vaccine strains were sequenced and analyzed. RESULTS: Genotypic and phylogenetic analyses indicated that the 13 Vietnamese isolates were classified into two genotypes, DHAV-1 and DHAV-3. The rate of identity and homology was 91%-100% between the 10 Vietnamese and 26 global strains of DHAV-3, and 92%-100% between 3 Vietnamese and 16 strains of DHAV-1. Between the DHAV-3 and DHAV-1 strains, the divergence reached 30%. At the C-terminal of VP1 for the different strains, a hypervariable region was observed, and notably, six of the Vietnamese DHAV-3 strains in this study showed four consistent differences (at positions T184M, Q200H, K207N, and K214R) within this group that were distinct from all other DHAV-3 strains. CONCLUSIONS: This is the first report of molecular characterization of DHAVs in Vietnam. At least two genotypes were identified, DHAV-1 and DHAV-3, with diversified clades within and between genotypes. DHAV-3 seemed to be dominant in Vietnam.

Analysis of the RdRp, intergenic and structural polyprotein regions, and the complete genome sequence of Kashmir bee virus from infected honeybees (Apis mellifera) in Korea.

Kashmir bee virus (KBV) is one of the most common viral infections in honeybees. In this study, a phylogenetic analysis was performed using nine partial nucleotide sequences of RdRp and the structural polyprotein regions of South Korean KBV genotypes, as well as nine previously reported KBV genotypes from various countries and two closely related genotypes of Israeli acute paralysis virus (IAPV) and Acute bee paralysis virus (ABPV). The Korean KBV genotypes were highly conserved with 94-99 % shared identity, but they also shared 88-95 % identity with genotypes from various countries, and they formed a separate KBV cluster in the phylogenetic tree. The complete genome sequence of Korean KBV was also determined and aligned with previously reported complete reference genome sequences of KBV, IAPV, and ABPV to compare different genomic regions. The complete Korean KBV genome shared 93, 79, and 71 % similarity with the complete reference genomes of KBV, IAPV, and ABPV, respectively. The Korean KBV was highly conserved relative to the reference KBV genomes in the intergenic and 3' untranslated region (UTR), but it had a highly variable 5' UTR, whereas there was little divergence in the helicase and 3C-protease of the nonstructural protein, and the external domains of the structural polyprotein region. Thus, genetic recombination and geographical distance may explain the genomic variations between the Korean and reference KBV genotypes.

Molecular characterization and phylogenetic analysis of deformed wing viruses isolated from South Korea.

Deformed wing virus (DWV) is one of the most common viral infection in honeybees. Phylogenetic trees were constructed for 16 partial nucleotide sequences of the structural polyprotein region and the RNA helicase region of South Korean DWVs. The sequences were compared with 10 previously reported DWV sequences from different countries and the sequences of two closely related viruses, Kakugo virus (KGV) and Varroa destructor virus-1 (VDV-1). The phylogeny based on these two regions, the Korean DWV genomes were highly conserved with 95-100% identity, while they also shared 93-97% similarity with genotypes from other countries, although they formed a separate cluster. To investigate this phenomenon in more detail, the complete DWV genome sequences of Korea-1 and Korea-2 were determined and aligned with six previously reported complete DWV genome sequences from different countries, as well as KGV and VDV-1, and a phylogenetic tree was constructed. The two Korean DWVs shared 96.4% similarity. Interestingly, the Korea-2 genome was more similar to the USA (96.5%) genome than the Korea-1. The Korean genotypes highly conserved with USA (96%) but low similarity with the United Kingdom3 (UK3) genome (89%). The end of the 5' untranslated region (UTR), the start of the open reading frame (ORF) region, and the 3' UTR were variable and contained several substitutions/transitions. This phenomenon may be explained by intramolecular recombination between the Korean and other DWV genotypes.

Analysis of the nonstructural and structural polyprotein regions, and complete genome sequences of Israel acute paralysis viruses identified from honeybees (Apis mellifera) in Korea.

Phylogenetic trees were constructed for 24 partial nucleotide sequences of the nonstructural polyprotein (ORF1) and structural polyprotein regions (ORF2) of Korean IAPV genotypes, as well as eight previously reported IAPV sequences from various countries. Most of the Korean genotypes formed a distinct cluster, separate from other country genotypes. To investigate this phenomenon in more detail, three complete IAPV genome sequences were identified from different regions in Korea, i.e., Korea1, Korea2, and Korea3. These sequences were aligned with eight previously reported complete genome sequences and various genome regions were compared. The Korean IAPVs were very similar to those from China and Israel, but highly diverged from USA and Australian genotypes. Interestingly, they showed greater variability than the USA and Australian genotypes in ORF1, but highly similar to the Australian genotype in the ORF2 region. Thus, genetic recombination may account for the spatial distance between the Korean IAPV genotypes and those from other countries.

Phylogenetic analysis of black queen cell virus genotypes in South Korea.

The black queen cell virus (BQCV), a picorna-like honeybee virus, was first isolated from queen larvae and pupae of honeybees found dead in their cells. BQCV is the most common cause of death in queen larvae. Phylogenetic analysis of two Apis cerana and three Apis mellifera BQCV genotypes collected from honeybee colonies in different regions of South Korea, central European BQCV genotypes, and a South African BQCV reference genotype was performed on a partial helicase enzyme coding region (ORF1) and a partial structural polypeptide coding region (ORF2). The phylogeny based on the ORF2 region showed clustering of all the Korean genotypes corresponding to their geographic origin, with the exception of Korean Am str3 which showed more similarity to the central European and the South African reference genotype. However, the ORF1-based tree exhibited a different distribution of the Korean strains, in which A. cerana isolates formed one cluster and all A. mellifera isolates formed a separate cluster. The RT-PCR assay described in this study is a sensitive and reliable method for the detection and classification of BQCV strains from various regions of Korea. BQCV infection is present in both A. cerana and A. mellifera colonies. With this in mind, the present study examined the transmission of honeybee BQCV infections between A. cerana and A. mellifera.