Echovirus 9 genetic diversity detected in whole-capsid genome sequences obtained directly from clinical specimens using next generation sequencing.

Echovirus 9 (E9) has been detected in an increased number of symptomatic patient samples received by the National Enterovirus Reference Laboratory in Hungary during 2018 compared to previously reported years.Formerly identified E9 viruses from different specimen types detected from patients of various ages and showing differing clinical signs were chosen for the detailed analysis of genetic relationships and potential variations within the viral populations. We used next generation sequencing (NGS) analysis of 3,900 nucleotide long amplicons covering the entire capsid coding region of the viral genome without isolation, directly from clinical samples.Compared to the E9 reference strain, the viruses showed about 79% nucleotide and around 93% amino acid sequence similarity. The four new viral genome sequences had 1-20 nucleotide differences between them also resulting in 6 amino acid variances in the coding region, including 3 in the structural VP1 capsid protein. One virus from a patient with hand, foot, and mouth disease had two amino acid changes in the VP1 capsid protein. An amino acid difference was also detected in the non-structural 2C gene of one virus sequenced from a throat swab sample from a patient with meningitis, compared to the faecal specimen taken two days later. Two amino acid changes, one in the capsid protein, were found between faecal samples of meningitis patients of different ages.Sequencing the whole capsid genome revealed several nucleotide and amino acid differences between E9 virus strains detected in Hungary in 2018.

Molecular characterization of echovirus 9 strains isolated from hand-foot-and-mouth disease in Kunming, Yunnan Province, China.

Echovirus 9 (E9) belongs to the species Enterovirus B. So far, 12 whole genome sequences of E9 are available in GenBank. In this study, we determined the whole genomic sequences of five E9 strains isolated from the stools of patients with hand-foot-and-mouth disease in Kunming, Yunnan Province, China, in 2019. Their nucleotide and amino acid sequences shared 80.8-80.9% and 96.4-96.8% identity with the prototype Hill strain, respectively, and shared 99.3-99.9% and 99.1-99.8% mutual identity, respectively. Recombination analyses revealed that intertype recombination had occurred in the 2C and 3D regions of the five Yunnan E9 strains with coxsackieviruses B5 and B4, respectively. This study augmented the whole genome sequences of E9 in the GenBank database and extended the molecular characterization of this virus in China.

Direct next-generation sequencing diagnosis of echovirus 9 meningitis, France.

The prognosis of central nervous system infections caused by enteroviruses partially depends on the viral genotype, which is not provided by current point-of-care diagnostic methods. In this study, next-generation sequencing identified an echovirus 9 directly from the cerebrospinal fluid of a patient presenting with meningitis.

Rubella virus genotype 1G and echovirus 9 as etiologic agents of exanthematous diseases in Brazil: insights from phylogenetic analysis.

The aim of the present study was to identify the rubella virus (RV) and enterovirus (EV) genotypes detected during the Epidemiological Surveillance on Exanthematic Febrile Diseases (VIGIFEX) study and to perform phylogenetic analysis. Ten RV- and four EV-positive oropharyngeal samples isolated from cell culture were subjected to RT-PCR and sequencing. Genotype 1G and echovirus 9 (E-9) was identified in RV- and EV-positive samples, respectively. The RV 1G genotype has been persisting in Brazil since 2000-2001. No evidence of E-9 being involved in exanthematic illness in Brazil has been reported previously. Differential laboratory diagnosis is essential for management of rash and fever disease.

[Complete genome sequence characteristics of human echovirus 9 strain isolated in Yunnan, China].

To analyze the genomic sequence characteristics of a human Echovirus 9(ECHO-9) strain isolated from a child with Hand-foot-mouth disease (HFMD) in Kunming, Yunnan Province, in 2010. The complete genome sequence of a human echovirus 9 strain, MSH-KM812-2010 was determined. As other human enterovirus, its genome was 7,424 nucleotides (nts) in length and encoded for 2,203 amino acids (aas). In comparison to other human enteroviruses, MSH-KM812-2010 strain had the highest homology with other strains of human echovirus 9 in structural genomic regions and more homologous to other serotypes of B specie than to human echovirus 9 in non-structural genomic regions. Phylogenetic analysis based on complete VP1 gene revealed that the sequences of human echovirus 9 segregated into three distinct clades A, B and C with more than 15. 0% diversity between clades. All Chinese isolates belonged to the same clade. RDP3 and Blast revealed evident recombination in non-structural genomic regions. This report is the first to, describe the complete genome of the human echovirus 9 in China and provide an overview of the diversity of genetic characteristics of a circulating human echovirus 9.

A single amino acid substitution in viral VP1 protein alters the lytic potential of clone-derived variants of echovirus 9 DM strain in human pancreatic islets.

In vitro studies with primary human pancreatic islets suggest that several enterovirus serotypes are able to infect and replicate in beta cells. Some enterovirus strains are highly cytolytic in vitro whereas others show virus replication with no apparent islet destruction. The capability to induce islet destruction is determined only partially by the virus serotype, since strain specific differences have been detected within some serotypes including echovirus 9 (E-9). In this study, the viral genetic factors determining the outcome of islet infection (i.e., destructive vs. benign) were investigated by constructing parallel infectious clones of lytic E-9-DM strain that was isolated from a small child at the clinical onset of type 1 diabetes. The capabilities of these clone-derived viruses to induce islet destruction were monitored and the lytic potential of clones was modified by site-directed mutagenesis. The lytic capabilities of these clone-derived viruses in human pancreatic islets were modified by a single amino acid substitution (T81A) in the capsid protein VP1. The data presented outline the importance of amino acid point mutations in the pathogenetic process leading to islet necrosis. However, although the amino acid substitution (T81A) modifies the lytic capabilities of E-9-DM strain-derived microvariant strains, it is likely that additional viral genetic determinants of pancreatic islet pathogenicity exist in other E-9 strains.

Prolonged viral RNA detection in the central nervous system of one-week-old Swiss albino mice following coxsackievirus B4 and echovirus 9 infection.

OBJECTIVES: Type B coxsackieviruses (CV-B), together with echoviruses (E), are among the most common pathogens encountered in aseptic meningitis and meningoencephalitis. They frequently infect the central nervous system (CNS). The mechanisms of virus spreading in the CNS are poorly understood. In the present study, we investigated CV-B4 and E-9 spreading and neurotropism within intraperitoneally inoculated one-week-old Swiss albino mice. METHODS: Seminested RT-PCR and virus isolation were used to assay viral distribution. RESULTS: Viral RNA was present in various organs: brain, spinal cord, spleen and heart at various times post-infection (p.i.); ranging from 1 day p.i. up to 30, 60 and 90 days p.i, respectively, for CV-B4-JVB-, E-9 Barty- and CV-B4-E2-infected mice. Organs became negative for virus isolation after 5 days p.i., except for brain and heart from CV-B4 E2-infected mice, which remained positive for up to 10 and 15 days p.i., respectively. Negative viral RNA strand was detected mainly in brain and spinal cord of infected mice until 30 and 60 days p.i. CONCLUSION: This is the first report on the persistence of CV-B4 and E-9 in the CNS of intraperitoneally inoculated mice.

[Molecular genetic echovirus 9 variants identified in patients with aseptic meningitis in Russia in 2007-2009].

In 2009 echovirus 9 caused a higher seasonal incidence of enterovirus infection (EVI) and its several outbreaks in a number of regions of Russia. Analysis of the partial VP1 coding region differentiated 4 phylogenetic lineages of echoviruses 9 variants identified in patients with aseptic meningitis and EVI in 2007-2009. One variant of echovirus 9 was most commonly encountered in 2009. Echoviruses 9 identified in different areas, which had a high (98.2-100%) homology of nucleotide sequences of the partial VP1 coding region, varied in the amino acid sequences within the B-C loop.

Enterovirus infection in human pancreatic islet cells, islet tropism in vivo and receptor involvement in cultured islet beta cells.

AIMS/HYPOTHESIS: It is thought that enterovirus infections cause beta-cell damage and contribute to the development of Type 1 diabetes by replicating in the pancreatic islets. We sought evidence for this through autopsy studies and by investigating known enterovirus receptors in cultured human islets. METHODS: Autopsy pancreases from 12 newborn infants who died of fulminant coxsackievirus infections and from 65 Type 1 diabetic patients were studied for presence of enteroviral ribonucleic acid by in situ hybridisation. Forty non-diabetic control pancreases were included in the study. The expression and role of receptor candidates in cultured human islets were investigated with receptor-specific antibodies using immunocytochemistry and functional assays. RESULTS: Enterovirus-positive islet cells were found in some of both autopsy specimen collections, but not in control pancreases. No infected cells were seen in exocrine tissue. The cell surface molecules, poliovirus receptor and integrin alphavbeta3, which act as enterovirus receptors in established cell lines, were expressed in beta cells. Antibodies to poliovirus receptor, human coxsackievirus and adenovirus receptor and integrin alphavbeta3 protected islets and beta cells from adverse effects of poliovirus, coxsackie B viruses, and several of the arginine-glycine-aspartic acid motifs containing enteroviruses and human parechovirus 1 respectively. No evidence was found for expression of the decay-accelerating factor which acts as a receptor for several islet-cell-replicating echoviruses in established cell lines. CONCLUSIONS/INTERPRETATION: The results show a definite islet-cell tropism of enteroviruses in the human pancreas. Some enteroviruses seem to use previously identified cell surface molecules as receptors in beta cells, whereas the identity of receptors used by other enteroviruses remains unknown.

Molecular and biological analysis of echovirus 9 strain isolated from a diabetic child.

The full-length infectious cDNA clone was constructed and sequenced from the strain DM of echovirus 9, which was recently isolated from a 6-week-old child at the clinical onset of type 1 diabetes. Parallel with the isolate DM, the full-length infectious cDNA clone of the prototype strain echovirus 9 Barty (Barty-INF), was constructed and sequenced. Genetic relationships of the sequenced echo 9 viruses to the other members of the human enterovirus type B species were studied by phylogenetic analyses. Comparison of capsid protein sequences showed that the isolate DM was closely related to both prototype strains: Hill and Barty-INF. The only exception was the inner capsid protein VP4 where serotype specificity was not evident and the isolate DM clustered with the strain Hill and the strain Barty-INF with echovirus 30 Bastianni. Likewise, the nonstructural protein coding region, P2P3, of isolate DM was more similar to strain Hill than to strain Barty-INF. However, like echovirus 9 Barty, the isolate DM contained the RGD-motif in the carboxy terminus of capsid protein VP1. By blocking experiments using an RGD-containing peptide and a polyclonal rabbit antiserum to the alpha(v)beta(3)-integrin, it was shown that this molecule works as a cellular receptor for isolate DM. By using primary human islets, it was shown that the isolate DM is capable of infecting insulin-producing beta-cells like the corresponding prototype strains did. However, only isolate DM was clearly cytolytic for beta-cells. The infectious clones that were made allow further investigations of the molecular features responsible for the diabetogenicity of the isolate DM.

Molecular evolution of human echovirus 9 isolated from patients with aseptic meningitis in northern Kyushu during the summer of 1997.

An epidemic of aseptic meningitis caused by human echovirus 9 (E-9) occurred in the summer of 1997 in northern Kyushu, Japan. Sequences of genome position 2504-3358, which encoded a part of VP1, of the nine isolated viruses were determined. An RGD motif and B-C loop were found in all. They were almost identical and closely related to the virulent strain Barty.

Acute onset of type I diabetes mellitus after severe echovirus 9 infection: putative pathogenic pathways.

Enterovirus infections have been implicated in the development of type I diabetes mellitus. They may cause beta cell destruction either by cytolytic infection in the pancreas or indirectly by contributing to autoimmune reactivity. We sought evidence for these 2 mechanisms in a case of acute-onset diabetes mellitus that occurred during severe echovirus 9 infection. The virus was isolated and administered to cultured human beta cells. No viral proliferation was observed, and no beta cell death was induced, while parallel exposure to Coxsackie B virus serotype 3 resulted in viral proliferation and massive beta cell death. Although the viral protein 2C exhibited a sequence similar to that of the beta cell autoantigen glutamic acid decarboxylase (GAD(65)), no cross-reactive T cell responses were detected. The patient did not develop antibodies to GAD(65) either. Absence of evidence for direct cytolytic action or an indirect effect through molecular mimicry with GAD(65) in the present case raises the possibility of another indirect pathway through which enteroviruses can cause diabetes mellitus.

Echovirus-9 protein 2C binds single-stranded RNA unspecifically.

Polypeptide 2C is essential for picornavirus replication. Although many data on multiple functions of this highly conserved protein are available, the mechanism of RNA binding is still obscure. In this work, protein 2C of echovirus-9 strain Barty was expressed as a histidine-tagged protein in E. coli followed by nondenaturing purification to homogeneity. After incubation of 2C protein with different kinds of RNA fragments, binding was shown in gel retardation assays. Competition experiments revealed that 2C targets linear RNA unspecifically; however, single-stranded linear DNA does not react with this protein. In contrast to poliovirus, protein 2C of echovirus-9 only recognizes RNA with a low content of secondary structures. This may be a first hint of a different binding specificity of 2C in echo- and polioviruses.

Outbreak of aseptic meningitis due to ECHO-9 in northern Kyushu island in the summer of 1997.

An outbreak of aseptic meningitis caused by echovirus type 9 (ECHO-9) occurred between June and August 1997 in the Chikugo area, Fukuoka, Japan. Clinical manifestations and laboratory data of 317 children with aseptic meningitis were analyzed. The age of the patients ranged from 1 month to 12 years with the highest incidence in 4 years old children. The male: female ratio was 2.0:1.0. Symptoms of the meningitis included fever (100%), headache (89.5%) and nausea and/or vomiting (85.6%). Skin rash was not frequent (2.2%) in contrast to previous reports of ECHO 9 infections. The number of white blood cells (WBC) in cerebrospinal fluid (CSF) ranged from 10 to 3,493 cells/microliter (median; 412 cells/microliter). The neutrophils were more than 50% of the WBC in CSF in one-fourth of the patients at diagnosis. Enteroviruses were identified from CSF utilizing virus culture and enterovirus-specific RT-PCR, and ECHO-9 infection was determined by antibody titer of paired sera. Finally 44 patients were diagnosed virologically or serologically as aseptic meningitis caused by ECHO-9. Sequence analysis revealed that two strains of ECHO-9 isolated from CSF in this epidemic were closely related to ECHO-9 virulent strain Barty.

Molecular biological characterization of enterovirus variant isolated from patients with aseptic meningitis.

In Korea, there was a big outbreak of aseptic meningitis in 1993. Six clinical isolates of enterovirus were obtained from patients with aseptic meningitis and were identified as echovirus type 9 by serotyping with a pool of neutralizing antisera. For molecular characterization of the isolates, the nucleotide sequences of 5'-noncoding region (NCR), VP4, VP2, VP1, 2A and 2C regions of the isolates were compared with the corresponding regions of echovirus type 9 Hill and Barty strains. Unlike Hill strain, Barty strain contained a C-terminal extension to the capsid protein VP1 with an RGD (argnine-glycine-aspartic acid) motif. To determine whether similar structural features were present in our isolates, their nucleotide sequences including the VP1 region were analyzed. All isolates exhibited the VP1 extension with the RGD motif. We concluded the Korean isolates in the year of 1993 as the echovirus type 9 Barty strain although the isolates showed 15-20% nucleotide sequence differences in the several genomic regions.

Cell attachment and mouse virulence of echovirus 9 correlate with an RGD motif in the capsid protein VP1.

The recently analyzed sequences of the nonpathogenic prototype strain Hill and the mouse-virulent strain Barty of the human echovirus 9 differ particularly in an insertion coding for an RGD motif at the C-terminus of the capsid protein VP1 in the genome of strain Barty. To investigate molecular determinants of virulence, we generated a panel of recombinant viruses derived from cDNA clones of strains Hill and Barty. In this communication, we show that the mouse-pathogenic character of strain Barty correlates with a 310-aa segment including the RGD motif. By mutating the RGD to an RGE tripeptide, the infectivity of the resulting echovirus 9 clones for GMK cells is lost. Furthermore, we could show that synthetic peptides containing the RGD sequence influence binding of mouse-virulent echovirus 9 strains to GMK cells, whereas binding of apathogenic strains is not affected. These results suggest that the RGD motif is a significant factor affecting pathogenicity of echovirus 9 strains.

Nucleotide sequencing of a part of the 5'-noncoding region of echovirus type 9 and rapid virus detection during the acute phase of aseptic meningitis.

A part of the 5'-noncoding region of echovirus type 9 isolates was sequenced, and an attempt was made for rapid virus detection in clinical samples obtained from 22 subjects hospitalized with aseptic meningitis. The sequence identity of 440-bp products amplified from the region by RT-PCR was 87.7% between the standard echovirus type 9(Hill strain) and the isolates. Specific IgM antibodies to Hill strain were positive in 45.5% by immunofluorescent antibody staining of virus-infected cells. A high detection rate of PCR products was observed in cerebrospinal fluids (CSFs; 54.5%) at admission, and in peripheral mononuclear cells (PMCs; 72.7%) at the end of hospitalization. Viral genomes were detectable for 2 days in serum samples, and for 6 days in PMC samples after onset of disease. When specific IgM antibody titers were less than 1:40, the amplification rate of viral genome from serum samples was 50.0%. These results indicate that the combination of specific IgM determination and viral genome amplification from CSFs will be a rapid and reliable method for early diagnosis.

Molecular cloning and sequence determination of the complete genome of the virulent echovirus 9 strain barty.

As part of a study of the molecular basis of pathogenicity of echovirus 9, the complete nucleotide sequence of the mouse-virulent echovirus 9 strain Barty was determined. Excluding the poly(A) tail, the complete RNA genome is composed of 7451 bases. The postulated open reading frame extends from nucleotide (nt) 741 to 7349 and predicts a polyprotein of 2203 amino acids (aa). As compared with the sequence of the echovirus 9 prototype strain Hill, which is apathogenic for newborn mice, 1492 nt are exchanged, leading to 9% divergence of the deduced amino acid sequence. The foremost difference between both strains is located at the C-terminus of the capsid protein VP1. In the case of strain Barty, an additional 10 aa fragment, including an RGD motif, is inserted.

Complete nucleotide sequence and biological properties of an infectious clone of prototype echovirus 9.

The prototype Hill of echovirus 9, a human enterovirus, exhibits no pathogenicity for newborn mice in contrast to some other echovirus 9 strains isolated subsequently during epidemics. In this communication we report the first complete nucleotide sequence and construction of an infectious clone of echovirus 9. Aside from the 3' poly(A)-tract, the RNA genome is 7420 nucleotides (nt) in length and encodes a single polyprotein of 2193 amino acids (aa). The open reading frame extends from position 740 to position 7318 of the genome. Sequence comparisons to other enteroviruses reveal a strong overall amino acid identity to echovirus types 11 and 12 (in each case 76%). The proteolytic cleavage sites of the three major capsid proteins were determined after purification by HPLC and protein sequencing. A full-length clone coding for an infectious RNA transcript was constructed, and recombinant echovirus 9 particles could be isolated from the supernatant of transfected cell culture. It is shown that the recombinant virus, like the original prototype, is non-pathogenic for newborn mice and does not multiply in skeletal muscles.