Persistent Detection of Cosavirus and Saffold Cardiovirus in Riachuelo River, Argentina.

Cosaviruses (CoSV) and Saffold cardiovirus (SAFV) are novel members of the Picornaviridae family. The Matanza-Riachuelo river basin covers a total area of 2200 km2 with approximately 60 km long. Its last section is called Riachuelo River. The aim of this study was to describe the circulation of both picornaviruses and their relationship with the environmental situation of the Riachuelo River using 274 samples collected from 2005 to 2015. CoSV and SAFV were investigated in samples available by two periods: 2005-2006 and 2014-2015 (103 and 101, respectively). Physicochemical and bacteriological parameters confirmed very high levels of human fecal contamination during the 11 years evaluated. CoSV was detected in 85.7% (66/77) and 65.4% (17/26) of the samples collected in 2005-2006 and 2014-2015 periods, respectively. Species A and D were identified, the first one being widely predominant: 74.1% (20/27) and 75.0% (3/4) in both periods. SAFV virus was detected in 47.1% (32/68) and 52.6% (10/19) in periods 2005-2006 and 2014-2015, respectively. SAFV-6 was the most identified genotype in the entire study, while SAFV-3 was predominant in 2005-2006. The contribution of genotypes 1, 2, 4 and 8 was minor. The high prevalence of CoSV and SAFV suggests that both viruses have been circulating in Argentina at least since 2005. Our results show that a watercourse with high rates of human fecal contamination can become a persistent source of new viruses which capacity to produce human diseases is unknown.

Evidence of Saffold virus circulation in Italy provided through environmental surveillance.

Saffold virus (SAFV) is an emerging human cardiovirus associated with respiratory and gastrointestinal infection, and, more recently, to symptoms related to the endocrine, cardiovascular, and neurological systems. Information about SAFV circulation in Italy is scarce. In order to provide insights into the epidemiology of SAFV in Italy, 141 raw sewage samples collected throughout Italy were tested using broad-range nested RT-PCR primers targeting the 5'-NC region. Seven samples (5·0%) were confirmed as SAFV in samples collected in North, Centre and Southern Italy. Typing was attempted through amplification of the VP1 coding region, using both published and newly designed primers, and one sample was characterized as SAFV-2. SIGNIFICANCE AND IMPACT OF THE STUDY: Prevalence, genetic diversity and geographic distribution of SAFV in Italy is currently unknown. This study represents the first detection of SAFV in sewage samples in Italy, suggesting that it is circulating in the population despite lack of clinical reporting. Whether the virus is associated with asymptomatic cases or with undetected gastroenteritis or respiratory illness is unknown. Further studies are needed to investigate on the occurrence and persistence of SAFV in water environments and its waterborne transmission potential.

First Occurrence of Saffold Virus in Sewage and River Water Samples in Karaj, Iran.

Saffold virus as a newly discovered virus, which seems to be related to acute gastroenteritis as with other enteric viruses and to human airway diseases in children belongs to Cardiovirus genus in picornaviridae family with 11 genotypes. Saffold virus initially was detected in America from infant stool sample. Saffold virus has also been detected in environmental water samples. Until now, two reports have demonstrated that sewage water sources are contaminated with Saffold viruses. Molecular detection of Saffold virus mostly depended on reverse transcription PCR methods and RT-qPCR, which had targeted 5'UTR region of the viral genome. The present study aims to evaluate the molecular detection and quantity of Saffold virus in sewage water and river water specimens by RT-qPCR assay in Karaj, Iran. Fifty samples collected from environmental waters containing treated and untreated sewage water and river water samples were included in this study. After viral RNA extraction, the Real-time PCR was developed to amplify the 5'UTR sequence of Saffold virus genome and viral load was assessed. Out of the 50 samples tested (consisting 28 river water samples and 22 sewage water samples), the Saffold virus genomic RNA was identified in 10/28 (35.7%) of river water samples and in 4/12 (33.3%) of treated and 4/10 (40%) of untreated sewage samples. The maximum viral load was 6.8 × 106 copies/l in untreated sewage water sample in December, and the lower viral load was 1.2 × 106 copies/l related to treated sewage water taken in October. Our results for the first time indicate that Saffold virus has apparently been circulating among Iranian peoples. Also, the viral prevalence of Saffold virus in each of the three sets of tested samples was within moderate to high in range.

Frequent detection of Saffold cardiovirus in adenoids.

Saffold virus (SAFV) is classified into the Cardiovirus genus of the Picornaviridae family. Up to now, eleven genotypes have been identified however, their clinical significance remains unclear. Here, we investigated the presence of SAFV in asymptomatic patients admitted for adenoidectomy. A total of 70 adenoid tissue samples were collected from children with clinical symptoms caused by hypertrophy of adenoids but without symptoms of airway infection. Samples were investigated for SAFV by RT-nested PCR and sequence analysis. Eleven of 70 (15.7%) samples were positive for SAFV. Nasopharyngeal swabs were available from 45 children just before surgery. SAFV was rarely found and only in children with SAFV-positive adenoids 2/8. Our findings indicate that the presence of SAFV seems to be more frequent in adenoid tissue than expected. This could support the notion of a longer than previously anticipated persistence of SAFV nucleic acids in the respiratory tract and possibly a chronic infection. Further investigations are necessary to establish the role of SAFV infection in humans.

Viral Metagenomics Revealed a Novel Cardiovirus in Feces of Wild Rats.

BACKGROUND/AIMS: Cardiovirus is a genus of viruses belonging to the family Picornaviridae. Here, we used viral metagenomic techniques to detect the viral nucleic acid in the fecal samples from wild rats in Zhenjiang city in China. METHOD: Fecal samples were collected from 20 wild rats and pooled into four sample pools and then subjected to libraries construction which were then sequenced on Illumina MiSeq platform. The sequenced reads were analyzed using viral metagenomic analysis pipeline. RESULTS: A novel cardiovirus from feces of a wild rat was identified, named amzj-2018, of which the complete genome was acquired. Phylogenetic analysis based on the complete amino acid sequence of polyprotein revealed that amzj-2018 formed a separate branch located between clusters of Saffold virus and Rat Theilovirus 1 (RTV-1). Phylogenetic analysis based on different regions of the polyproteins, including P1, P2, P3, and P2+P3, respectively, showed discordant trees, where the tree based on P3 region indicated that amzj-2018 clustered separately between Theiler's murine encephalomyelitis virus and RTV-1. CONCLUSION: The complete genome of a cardiovirus was determined from the feces of wild rats which belonged to a novel type of cardiovirus based on phylogenetic analysis. Whether it is associated with disease needs further investigation.

Detection of Saffold viruses from children with acute respiratory infections in Yamagata, Japan, between 2008 and 2015.

Although Saffold virus (SAFV) was reported as a novel human cardiovirus in 2007, no causative association between SAFV and clinical disease has been proven and the longitudinal epidemiology of SAFVs is not available. To establish the relationship between SAFVs and acute respiratory infections (ARIs) and to clarify the longitudinal epidemiology of SAFVs, 7258 nasopharyngeal specimens were collected from children with ARIs in Yamagata, Japan between 2008 and 2015. The specimens were inoculated on a microplate including six cell lines as part of routine surveillance, and molecular screening was performed for SAFVs using a reverse transcription (RT)-PCR method. Throughout the study period, 95 (1.3%) SAFV genotype 2 (SAFV2), and 28 (0.4%) SAFV3 were detected, mainly between September and November. There were two outbreaks of SAFV2 in 2009 and 2013, and one outbreak of SAFV3 in 2012 and the positive rates during these outbreaks were 12.1% (53/439), 11% (35/319), and 4.4% (20/453), respectively. Sixty-three SAFV2 and 28 SAFV3 strains were detected as a single virus from children with ARIs such as pharyngitis, herpangina, and tonsillitis. These results suggested that SAFV2 and SAFV3 are possible causative agents of ARIs among children and their infections occur mainly in the autumn season in Japan.

Saffold Cardiovirus Infection in a 2-Year-Old Boy with Acute Pancreatitis.

Saffold cardiovirus (SAFV), first identified in a stool sample in 2007, is thought to be associated with respiratory disease and gastroenteritis. On the other hand, animal experiments suggested that the major viral load, following intraperitoneal inoculation of SAFV in mice, may be detected in the pancreas. However, until now, no cases of SAFV in patients with pancreatitis have been reported. This report presents a unique case in a patient who developed relapsing acute pancreatitis (AP) after hand, foot, and mouth disease, and was suspected to have SAFV-1 infection. A 2-year-old boy was admitted to the hospital because of severe abdominal pain. His serum amylase and lipase levels were elevated. Enhanced computed tomography showed pancreatic swelling and dilation of the main pancreatic duct, leading to a diagnosis of severe AP. The viral genome of SAFV-1 was detected by reverse transcription polymerase chain reaction from fecal samples. Furthermore, the serum neutralization titer for SAFV was elevated during AP, but decreased after 1 year. These findings strongly suggest the patient developed SAFV-1 infection concurrent with AP. Therefore, we propose that a cohort study is required to clarify the relationship between SAFV and AP.

Neuropathogenicity of Two Saffold Virus Type 3 Isolates in Mouse Models.

OBJECTIVE: Saffold virus (SAFV), a picornavirus, is occasionally detected in children with acute flaccid paralysis, meningitis, and cerebellitis; however, the neuropathogenicity of SAFV remains undetermined. METHODS: The virulence of two clinical isolates of SAFV type 3 (SAFV-3) obtained from a patient with aseptic meningitis (AM strain) and acute upper respiratory inflammation (UR strain) was analyzed in neonatal and young mice utilizing virological, pathological, and immunological methods. RESULTS: The polyproteins of the strains differed in eight amino acids. Both clinical isolates were infective, exhibited neurotropism, and were mildly neurovirulent in neonatal ddY mice. Both strains pathologically infected neural progenitor cells and glial cells, but not large neurons, with the UR strain also infecting epithelial cells. UR infection resulted in longer inflammation in the brain and spinal cord because of demyelination, while the AM strain showed more infectivity in the cerebellum in neonatal ddY mice. Additionally, young BALB/c mice seroconverted following mucosal inoculation with the UR, but not the AM, strain. CONCLUSIONS: Both SAFV-3 isolates had neurotropism and mild neurovirulence but showed different cell tropisms in both neonatal and young mouse models. This animal model has the potential to recapitulate the potential neuropathogenicity of SAFV-3.

Molecular epidemiological analysis of Saffold cardiovirus genotype 3 from upper respiratory infection patients in Taiwan.

BACKGROUND: Saffold cardiovirus (SAFV) belongs to the Cardiovirus genus of Picornaviridae family, and may be a relevant new human pathogen; Thus far, eleven genotypes have been identified. The SAFV type 3 (SAFV-3) is thought to be the major genotype and is detected relatively frequently in children with acute gastroenteritis and respiratory illness. The epidemiology and pathogenicity of SAFV-3 remain unclear. OBJECTIVES: To investigate the genomic and epidemiologic profiles of SAFV-3 infection in Taiwan. STUDY DESIGN: Virus was detected in respiratory samples from children suffering for URI. SAFV-3 isolates were detected by isolation on cell culture and IF assay. The molecular typing was performed by RT-PCR and was sequenced to compare with reference strains available in the NCBI GeneBank. Serum samples were collected from 2005 to 2013 in Taiwan for seroprevalence investigation. RESULTS: A total of 226 specimens collected from children with URIs, 22 (9.73%) were positive for SAFV-3. The majority of SAFV-3 infections were found in children less than 6 years of age (14 of 22, 63.6%). Genetic analysis of VP1 coding region of Taiwanese isolates shown an 83.2-97.7% difference from other available SAFV-3 sequences in NCBI GenBank. Phylogenetic analysis revealed there is three genetic groups of SAFV-3 co-circulated in Taiwan during the study period. In addition, seroprevalence investigation results indicated that SAFV-3 infection occurs early in life and 43.7-77.8% of children aged between 6 months to 9 years old, had neutralizing antibodies against SAFV-3. CONCLUSION: SAFV-3 may have circulated in Taiwan for some time and it appears to be one of the etiological agents responsible for URIs in children.

Saffold Virus, a Human Cardiovirus, and Risk of Persistent Islet Autoantibodies in the Longitudinal Birth Cohort Study MIDIA.

The aim of this study was to describe the frequency and distribution of Saffold virus in longitudinal stool samples from children, and test for association with development of persistent autoantibodies predictive of type 1 diabetes. A cohort of Norwegian children carrying the HLA genotype associated with highest risk of type 1 diabetes ("DR4-DQ8/DR3-DQ2") was followed with monthly stool samples from 3 to 35 months of age. Blood samples were tested for autoantibodies to insulin, glutamic acid decarboxylase65 and Islet Antigen-2. 2077 stool samples from 27 children with ≥ 2 repeatedly positive islet autoantibodies (cases), and 53 matched controls were analysed for Saffold virus genomic RNA by semi-quantitative real-time reverse transcriptase PCR. Saffold virus was found in 53 of 2077 (2.6%) samples, with similar proportions between cases (2.5%) and controls (2.6%). The probability of being infected by 3 years of age was 28% (95% CI 0.18-0.40). Viral quantities ranged from <1 to almost 105 copies/µl. Estimated odds ratio between islet autoimmunity and infection episodes prior to seroconversion was 1.98 (95% CI: 0.57-6.91, p = 0.29). Saffold virus had no statistically significant association with islet autoimmunity.

Prevalence and genetic characteristics of Saffold cardiovirus in China from 2009 to 2012.

The epidemiology and clinical features of the Saffold cardiovirus (SAFV) remain ambiguous. The present study was designed to systematically and intensively investigate the epidemiological features of SAFV in pediatric patients in China. Three cohorts of pediatric patients were recruited from 2009 to 2012. Cohort 1 comprised patients with acute respiratory tract infections. Cohort 2 comprised patients with diarrhea. Cohort 3 comprised hand, foot, and mouth disease (HFMD) patients. A total of 115 patients (1.6%) among 6052 (17/1647, 12/2013, and 86/2392 in cohorts 1, 2, and 3, respectively) were SAFV-positive. The samples from 82 SAFV-positive patients were successfully sequenced, and four genotypes were identified: 8 SAFV-1, 41 SAFV-2, 29 SAFV-3, and 4 SAFV-6. A significantly higher detection rate was found in the HFMD patients than in other two cohorts (both P <0.001). A higher frequency of severe clinical outcome and nervous system manifestation were also observed in the SAFV-positive HFMD patients. Additionally, 6 (3.5%) cerebrospinal fluid and 7 (2.2%) serum samples from the HFMD-associated encephalitis patients were SAFV-positive. Based on the VP1 sequences, all four genotypes displayed distinct geographical clustering. SAFV infection might be associated with a wide clinical spectrum and contribute to HFMD.

Serious invasive Saffold virus infections in children, 2009.

The first human virus in the genus Cardiovirus was described in 2007 and named Saffold virus (SAFV). Cardioviruses can cause severe infections of the myocardium and central nervous system in animals, but SAFV has not yet been convincingly associated with disease in humans. To study a possible association between SAFV and infections in the human central nervous system, we designed a real-time PCR for SAFV and tested cerebrospinal fluid (CSF) samples from children <4 years of age. SAFV was detected in 2 children: in the CSF and a fecal sample from 1 child with monosymptomatic ataxia caused by cerebellitis; and in the CSF, blood, and myocardium of another child who died suddenly with no history of illness. Virus from each child was sequenced and shown to be SAFV type 2. These findings demonstrate that SAFV can cause serious invasive infection in children.

Saffold virus, a novel human Cardiovirus with unknown pathogenicity.

Although cardioviruses have been thought to mainly infect rodents, a novel human cardiovirus, designated Saffold virus (SAFV), was identified in 2007. SAFV is grouped with Theiler-like rat virus and Theiler's murine encephalomyelitis virus (TMEV) in the species Theilovirus of the genus Cardiovirus of the family Picornaviridae. Eight genotypes of SAFV have now been identified. SAFV has been isolated from nasal and stool specimens from infants presenting with respiratory and gastrointestinal symptoms as well as from children with nonpolio acute flaccid paralysis; however, the relationship of SAFV to this symptomatology remains unclear. Of note, the virus has also been isolated from the cerebrospinal fluid specimens of patients with aseptic meningitis. This finding is of interest since TMEV is known to cause a multiple sclerosis-like syndrome in mice. The involvement of SAFV in various diseases (e.g., respiratory illness, gastrointestinal illness, neurological diseases, and type I diabetes) is presently under investigation. In order to clarify the pathogenicity of SAFV, additional epidemiological studies are required. Furthermore, identification of the SAFV cellular receptor will help establish an animal model for SAFV infection and help clarify the pathogenesis of SAFV-related diseases. In addition, investigation of the tissue-specific expression of the receptor may facilitate development of a novel picornavirus vector, which could be a useful tool in gene therapy for humans. The study of viral factors involved in viral pathogenicity using a reverse genetics technique will also be important.

Human cardioviruses, meningitis, and sudden infant death syndrome in children.

Cardioviruses cause myocarditis and encephalomyelitis in rodents; human cardioviruses have not been ascribed to any disease. We screened 6,854 cerebrospinal fluid and 10 myocardium specimens from children and adults. A genotype 2 cardiovirus was detected from a child who died of sudden infant death syndrome, and 2 untypeable cardioviruses were detected from 2 children with meningitis.

[The research of saffold virus in children with lower respiratory tract infection in Changsha].

OBJECTIVE: To investigate prevalence of Saffold virus (SAFV) in Changsha area of hospitalized children with respiratory tract infection, and to discuss whether this virus is related to respiratory tract infection of children. METHODS: 643 nasopharyngeal aspirates samples were collected from hospitalized children with respiratory tract infection of the first affiliated hospital of Hunan nomal university during Nov. 2007 to Oct. 2008. Real-time fluorescent quanti-tative PCR(FQ-PCR) performed to screen the 5'UTR gene. And then analyze clinical data. RESULTS: SAFV were detected in 67 patients (10.42%) out of the 643 children, it was not detected over 5 years of age. The virus were detected in 8 patients (25.81%) out of the 31 children with persistent pneumonia and chronic pneumonia, there was statistically significant. CONCLUSION: There existed SAFV infection in hospitalized children with lower respiratory infection in Changsha area; SAFV maybe related to disease onset with lower respiratory tract infection of children.

The preparation of an infectious full-length cDNA clone of Saffold virus.

The pathogenicity of Saffold virus (SAFV) among humans still remains unclear, although it was identified as a novel human cardiovirus in 2007. In order to encourage the molecular pathogenetic studies of SAFV, we generated an infectious cDNA clone of SAFV type 3 (SAFV-3). The present study demonstrated that the synthesis of the full-length infectious RNA by T7 RNA polymerase was terminated by a homologous sequence motif with the human preproparathyroid hormone (PTH) signal in the SAFV-3 genome. To obtain the infectious RNA using T7 promoter, a variant of T7 RNA polymerase, which fails to recognize the PTH signal, was useful. This study will provide a valuable technical insight into the reverse genetics of SAFV.

Saffold cardiovirus infection in children associated with respiratory disease and its similarity to coxsackievirus infection.

BACKGROUND: Saffold virus (SAFV) is a newly discovered virus belonging to the genus Cardiovirus of the family Picornaviridae. Using molecular techniques, SAFV has been detected, although infrequently, in the stools of both healthy and diarrheic children and in respiratory specimens collected from children with respiratory disease. The epidemiology and pathogenicity of SAFV remain unclear. METHODS: Between July 2009 and October 2010, nasopharyngeal specimens were collected from children with acute respiratory infections. The collected samples were used to isolate respiratory viruses, including coxsackievirus, by cell culture and were tested for SAFV by reverse transcription-polymerase chain reaction. RESULTS: SAFV genotype 2 (SAFV2) was detected in 54 (3.5%) of the 1525 children tested. SAFV2 detections showed an epidemic pattern for a 4-month period with a peak in October 2009. The median age of the SAFV2-positive children was 4 years (range: 7 months-16 years). Among the 35 SAFV2-positive children, excluding cases of viral coinfection, 13 (37.1%) had pharyngitis, 12 (34.3%) had tonsillitis, and 8 (22.8%) had herpangina. Bronchitis and gastroenteritis were detected in 1 case each. Fever (temperature, >38°C) was noted in 33 (94.3%) cases. The median duration of fever was 2 days (range: 1-3 days). Diarrhea was observed in 7 (20.0%) children, but watery and frequent diarrhea was not common. The age distribution and clinical diagnoses associated with SAFV2 infections were similar to those observed with coxsackievirus B4 infections, which detections showed an epidemic pattern during the study period. CONCLUSION: SAFV2 is a cause of upper respiratory tract illness that exhibits a pathogenicity similar to that of coxsackievirus B.