key: cord-1032122-vlsk8rw1 authors: Woolhouse, Mark; Ashworth, Jordan; Bogaardt, Carlijn; Tue, Ngo Tri; Baker, Steve; Thwaites, Guy; Phuc, Tran My title: Sample descriptors linked to metagenomic sequencing data from human and animal enteric samples from Vietnam date: 2019-10-15 journal: Sci Data DOI: 10.1038/s41597-019-0215-2 sha: 78cc0a828b438df4987059241b39f933a1dfdfd0 doc_id: 1032122 cord_uid: vlsk8rw1 There is still limited information on the diversity of viruses co-circulating in humans and animals. Here, we report data obtained from a large field collection of enteric samples taken from humans, pigs, rodents and other mammal hosts in Vietnam between 2012 and 2016. Each of 2100 stool or rectal swab samples was subjected to virally-enriched agnostic metagenomic sequencing; the short read sequence data are accessible from the European Nucleotide Archive (ENA). We link the sequence data to metadata on host type and demography and geographic location, distinguishing hospital patients, members of a cohort identified as a high risk of zoonotic infections (e.g. abattoir workers, rat traders) and animals. These data are suitable for further studies of virus diversity and virus discovery in humans and animals from Vietnam and to identify viruses found in multiple hosts that are potentially zoonotic. Viruses of zoonotic origin are a significant public health concern worldwide having given rise to a number of high profile health emergencies in recent years, including SARS and MERS coronaviruses, H5N1 influenza A and ebolavirus 1 . However, detailed information on the epidemiology and evolution of viruses co-circulating in human and animal populations in the absence of significant outbreaks or epidemics is generally lacking. To help overcome this deficiency, the Vietnam Initiative on Zoonotic InfectIONS (VIZIONS) project ran between 2011 and 2016 with the overall aim of improving understanding of the epidemiology and evolution of zoonotic virus infections (particularly emerging infections) in Vietnam in south-east Asia. VIZIONS was a Wellcome Trust-funded collaboration between the Oxford University Clinical Research Unit (OUCRU) in Ho Chi Minh City, Vietnam, the Sanger Institute and the University of Edinburgh in the UK, and Metabiota Inc. in the US, working closely with seven Vietnam hospitals, Hanoi Medical University, and Vietnam regional medical centres and sub-departments for animal health 1 . VIZIONS supported studies in hospitals, communities and animal populations throughout Vietnam covering mainly enteric, respiratory, CNS infections and jaundice and generating data on clinical symptoms and outcomes, diagnostics, epidemiology and risk factors, virus identification, and virus genome sequences 2, 3 . The data reported here comprise metagenomic sequence data and linked metadata for 2100 enteric samples from humans and animals and come from two major components of the VIZIONS project, one hospital-based and one community-based. The first component was a large hospital-based surveillance study: a retrospective case series of hospitalised patients presenting with enteric disease believed to result from an infection 3 . The main aims of the study were to obtain high resolution data on all viruses present in these patients; to identify viruses of possible zoonotic origin causing severe disease (resulting in hospitalisation); and to estimate the disease burden due to viruses of zoonotic origin. This component contributed two additional sub-studies: a small study of only patients who tested positive for rotavirus A infection using a PCR test; and another small study of patients with undiagnosed enteric disease at four hospital sites. The second component was a high-risk sentinel cohort: a prospective longitudinal cohort of people who have frequent occupational contact with animals and are thus perceived to be at high risk of developing zoonotic infections 2 . This component contributed two sub-studies: the high-risk sentinel cohort itself; and a parallel study of non-human mammals with which the human subjects were in close contact. The main aims of the study were to characterise the diversity of viruses circulating in high-risk human populations and in the animals with which they were in contact (including those that were asymptomatic or caused only mild illness that would not be picked up in a hospital-based study), estimate the incidence of virus infections in the human cohort, and identify possible instances of cross-species transmission. Subjects were selected based on high levels of exposure to animals (mainly on farms, in wet markets or slaughterhouses) and were sampled routinely at regular intervals over a three-year period and during episodes of diarrhoea. A metagenomic sequencing protocol using random primers and a reverse transcription step was used to identify viruses in faecal samples and rectal swabs from these studies. This method was considered to be less biased towards common pathogens and to yield more information than a battery of diagnostic PCRs targeting specific, known pathogens. Metagenomic sequence data would allow in-depth characterisation of virus diversity in the study populations. Subsequent phylogenetic analysis would provide insights into the evolutionary and epidemiological dynamics of the identified viruses, including their spatial and temporal spread through human and animal populations and the inference of any zoonotic transmission events. The great majority of the data reported here were obtained from Dong Thap, a province in the south of Vietnam that is regarded as a potential hot-spot for the emergence of novel zoonotic viruses. Dong Thap province is in the Mekong Delta region (Fig. 1 ). Due to its mostly flat terrain, the Mekong Delta is one of the most important agricultural centres in Vietnam, and it has high human and livestock population densities. Dong Thap has an area of 3,379 km 2 and is inhabited by just under 1.7 million people, approximately 4.7 million ducks, chickens and other poultry, 233,000 pigs, and 26,000 cattle and buffalo 3 . Additionally, there is a vibrant rat trade, with many tonnes of live rats sold for human consumption each year 2 . In addition, a small number of samples are included from other sites in Vietnam (see below). Overall, sequence data and metadata are available for 2100 samples collected in Vietnam between November 2012 and May 2016. The numbers of samples from each of the five sub-studies are shown in Table 1. 1258 samples were obtained from human subjects (Fig. 2) . 707 samples were collected from patients admitted to hospital with symptoms of enteric disease. The great majority of these (95%) were from Dong Thap General Hospital (Table 1) . 551 samples were obtained from a high-risk sentinel cohort in Dong Thap province, most of whom were sampled on multiple occasions. These subjects are divided into four risk categories (Table 2) . 842 samples were obtained from a variety of non-human animals in Dong Thap province in parallel with sampling the high-risk cohort (Table 3 ). Information on host species, sampling date, location and other attributes (see below) is available for all samples. Metagenomic sequencing yielded from 3670 to 59.5 M read pairs (Illlumina 2 × 250 nt reads) per sample, with a mean of 3.38 M, a median of 2.66 M and a mode of 3.1 M. 67.7% of samples were from stool and 32.3% were from rectal swabs. Stool samples had higher modal read counts (Fig. 3) . The sequence data and linked metadata have been used in a series of published research papers on viruses in Vietnam: www.nature.com/scientificdata www.nature.com/scientificdata/ • Complete genome characterization of two wild-type measles viruses from Vietnamese infants 4 ; • Genome sequences of a novel Vietnamese bat bunyavirus 5 ; • Whole-genome deep sequencing of rotaviruses from human and porcine stool samples with evidence of a putative zoonotic infection 6 ; • Characterization of Posa and Posa-like virus genomes in faecal samples from humans, pigs, rats, and bats collected 7 ; • Genetic diversity and cross-species transmission of kobuviruses in Vietnam 8 ; • Virus diversity in enteric bat samples from Vietnam 9 ; • Identification of coronavirus genomes from bats and rodents 10 . We anticipate that the data may be used for further studies of virus diversity and virus discovery in humans and animals from Vietnam and to identify viruses found in both kinds of host that are potentially zoonotic. Age and gender distribution of participants in the high-risk and hospital based study. Age (years) and genders (male (blue), female (green)) were recorded for each participant in the hospital based study on the day of sampling. The age of participants in the high-risk cohort was recoded on the day of sampling. The genders of participants in the high-risk cohort were not disclosed. Baseline ( www.nature.com/scientificdata www.nature.com/scientificdata/ Methodological summaries are provided below for each of the 5 sub-studies listed in Table 1 . These are followed by a summary of the metagenomic sequencing methodology -this was common to all 5 sub-studies. Hospital patients -enteric disease study. Study design and recruitment. This study took place in Dong Thap General Hospital between November 2012 and May 2015. The study method are described in full elsewhere 1 . All hospital admissions during the study period with suspected enteric disease were considered for recruitment and up to six patients per day were enrolled into the study. Patients were included in the study if they satisfied the following criteria: a clinical diagnosis of acute diarrhoeal disease (defined as a minimum of three loose stools within 24 hours, or one bloody loose stool) believed to be caused by an infection; provision of written informed consent; and requiring admission to the hospital as decided by the attending physician. Patients were excluded from the study if they had been hospitalised with enteric disease within the previous six months, if they had previously been enrolled to the www.nature.com/scientificdata www.nature.com/scientificdata/ study, if the diarrhoea was deemed likely to be due to prior antibiotic treatment, or if they had unrelated medical complications. Data collection. Upon enrolment, study staff collected a stool sample (on the day of admission, before any antimicrobial treatment) and a variety of demographic and other epidemiologically relevant information. The patient's residential address was recorded and mapped with GPS software. Stool samples were subjected to a range of diagnostic tests at the microbiology departments of the participating hospitals and at the central study laboratory at OUCRU: these data are incomplete and are not reported here. All 602 samples collected during this study were sent for metagenomic sequencing (see below). Thap General Hospital with enteric disease tested positive by PCR test for the presence of rotavirus A (full details are provided elsewhere 6 ). Between March 2014 and May 2016, 49 such patients were purposefully sampled in order to provide rotavirus positive samples as a partial validation of the metagenomic sequencing. These patients were additional to the routine sample collection from enteric disease patients described above. In all other respects these samples were treated in an identical manner to those from the enteric disease study. (19) . Inclusion and exclusion criteria were as for the main enteric disease study, with the additional criterion that no pathogen was identified by diagnostic screening at the hospital. In all other respects these samples were treated in an identical manner to those from the enteric disease study at Dong Thap General Hospital. Province between March 2013 and May 2016. The study design, methods and baseline characteristics of the cohort are described in detail elsewhere 11, 12 . Four categories of subjects with residential or occupational exposure to animals were recruited into the cohort: • Animal farmers and their relatives, representing people with typical residential exposures to a variety of livestock species. This included keepers of both domestic and exotic animals, but excluded keepers of cold blooded animals. Poultry, pig and cattle farmers were originally selected at random from the animal farm census. Exotic animal farmers were actively sought as a group of special interest with the aim of maximising diversity of animals sampled. Up to four family members, including children, were enrolled from 61 farms. • Pig and poultry slaughterers, representing people with more intense occupational exposures (particularly to blood). These were recruited from the three major abattoirs and slaughter points in Dong Thap Province. • Animal health workers, representing people with intense occupational exposures to sick animals. These were recruited through the Dong Thap Sub-Department of Animal Health and District Veterinary Stations. • Rat traders and sellers from three marketplaces. These were actively sought as a group of special interest. Inclusion and exclusion criteria. Potential participants were included in the cohort study if they were long-term members of one of the above four risk groups; gave informed consent to sampling at regular intervals for three years; and resided within 40 km of Dong Thap General Hospital for clinical presentation in the event of illness. Data collection. Included individuals were followed up for three years. Cohort members were requested to provide a rectal swab at enrolment, yearly thereafter, and when they reported an episode of enteric illness. In the third year of the study, stool samples were collected instead of rectal swabs, as it had become apparent that human rectal swabs generally did not have sufficient concentrations of viral nucleic acid for reliable metagenomic sequencing. Detailed demographic, socio-economic and behavioural data relating to food preparation and consumption were collected from each participant; these data are not reported here. A total of 551 samples were sent for metagenomic sequencing. These comprised: Non-human animal study. The high-risk cohort study also included the sampling of associated mammals and birds. This part of the study is described in detail elsewhere 10 . A subset of 842 these samples was selected for metagenomic sequencing. This subset comprised all available rodent and bat samples, and a representative selection from other mammals (Table 3 ). Bat and monkey species were not recorded during sampling, therefore this was predicted by querying the raw reads from bat and monkey samples against mitochondrial DNA databases containing Chiroptera (NCBI:txid9397, February 2017) and Simiiformes (excluding Homo sapiens) (NCBI:txid314293, June 2018) sequences respectively. This was performed using Blastn (e value < 1e-50) and selecting the species with the highest frequency of hits. www.nature.com/scientificdata www.nature.com/scientificdata/ Viral metagenomic sequencing. A total of 2100 samples obtained from the 5 sub-studies were sent for metagenomic sequencing at the Sanger Institute, UK. Samples were stored at −80 °C after collection and maintained at this temperature until sample processing (up to a maximum of 12 months). Samples were processed according to a modified Virus Discovery by cDNA Amplified Fragment Length Polymorphism (VIDISCA) method [13] [14] [15] . This method enriches samples for viral genetic material, which is otherwise difficult to sequence as it is naturally present at much lower concentrations than host and bacterial nucleic acid. It then converts genetic material from both DNA and RNA viruses to dsDNA to allow for metagenomic library preparation, using a process that is sequence-independent and reduces contamination by host ribosomal RNA. Detailed procedures were as follows. Samples were suspended in an equal volume of phosphate-buffered saline, and 110 µl were used for nucleic acid extractions. First, viral nucleic acid was enriched for by the removal of cellular debris, mitochondria and bacteria with a centrifugation step (10 minutes at 10,000 × g), and subsequent digestion of any residual DNA with DNase (20 units TURBO DNase, Ambion) -viral nucleic acid was presumed to be protected from this treatment by encapsidation within virions. Protected viral nucleic acid was then extracted using the Boom extraction method 16 . Viral RNA was converted to a cDNA intermediate using reverse transcriptase (Superscript II, Invitrogen) and a mixture of hexamer primers, designed to avoid binding to ribosomal RNA 17 . Subsequently, cDNA and viral ssDNA were subjected to second strand synthesis with 5 units Klenow fragment (3′-5′ exonuclease defective, New England Biolabs), and the resulting dsDNA was purified by phenol/chloroform extraction and ethanol precipitation. Library preparation and sequencing. Isolated viral dsDNA was used to prepare metagenomic sequence libraries for deep sequencing, as previously described 6 . Library preparation followed standard Illumina protocols, with up to 96 samples being prepared at a time for multiplex sequencing. Nucleic acids were sheared to 400-500 nucleotides (nt) in length. Distinct 8 nt indexing barcodes were added to each sample's nucleic acid before pooling. Each pool was sequenced divided over two lanes. Sequencing was done on Illumina HiSeq. 2500 machines, yielding up to several million 250 nt paired-end reads per sample. Adapters were trimmed off with Biobambam2 18 . For ethical reasons, human-derived sequences were identified by aligning reads to the GRCh38 reference genome (without Epstein-Barr virus) with BWA-backtrack 19 , and then removed. The resulting sequence data were deposited in the European Nucleotide Archive (ENA) in two batches, the first by Wellcome Sanger Institute as study PRJEB6505 20 and the second by the University of Edinburgh as study PRJEB26687 21 . These sequencing studies are linked by umbrella study PRJEB27881 22 , where sequence data for each sample is available for download in fastq or cram format. Ethics. Informed consent was obtained from all human subjects. All sampling and testing procedures were carried out in accordance with guidelines that had previously been reviewed and approved by the relevant institutional ethics committees for human and veterinary medicine. This includes the Ethics Board of Dong Thap Hospital and the review board of sub-Department of Animal Health (for work carried out in Dong Thap); the Ethics Board Hospital of Tropical Diseases and the review board of the sub-Department of Animal Health (for work carried out in Dong Thap province) and the Hanoi Medical University and the review board of the sub-Department of Animal Health in Ha Noi (for work carried out in Ha Noi). In addition, all methods were approved by the Oxford Tropical Research Ethics Committee (OxTREC) (No. 157-12) in the United Kingdom. The metadata associated with the sequence data is located on Edinburgh DataVault 23 . As the VIZIONS metadata include anonymised information on human subjects it cannot be made openly available. Researchers are required formally to request access to the database by contacting the Corresponding Author. Researchers will be required to complete a Data Release Request form that covers the purpose of the study, funding, ethical approvals, publication and intellectual property (Supplementary File 1). Average read quality grouped by sample collection method and host type. The average read quality for each read was calculated using FastQC. Reads were split into four categories based on collection method (faecal sample or rectal swab) and host type (human or non-human animal) of the sample they belong to. Giam Thong Ke (Statistical Yearbook of Vietnam Complete Genome Characterization of Two Wild-Type Measles Viruses from Vietnamese Infants during the 2014 Outbreak Genome Sequences of a Novel Vietnamese Bat Bunyavirus Unbiased whole-genome deep sequencing of human and porcine stool samples reveals circulation of multiple groups of rotaviruses and a putative zoonotic infection Characterization of Posa and Posa-like virus genomes in fecal samples from humans, pigs, rats, and bats collected from a single location in Vietnam Genetic diversity and cross-species transmission of kobuviruses in Vietnam A68 Bats as a source of zoonotic spillover: Investigating viruses in enteric bat samples from Viet Nam The baseline characteristics and interim analyses of the high-risk sentinel cohort of the Vietnam Initiative on Zoonotic InfectiONS (VIZIONS) Identification and characterization of Coronaviridae genomes from Vietnamese bats and rats based on conserved protein domains Mobilising community-based research on zoonotic infections: A case study of longitudinal cohorts in Vietnam Performance of VIDISCA-454 in feces-suspensions and serum A sensitive assay for virus discovery in respiratory clinical samples Full genome virus detection in fecal samples using sensitive nucleic acid preparation, deep sequencing, and a novel iterative sequence classification algorithm Rapid and simple method for purification of nucleic acids Species-independent detection of RNA virus by representational difference analysis using non-ribosomal hexanucleotides for reverse transcription biobambam: tools for read pair collation based algorithms on BAM files Fast and accurate short read alignment with Burrows-Wheeler transform Sample descriptors linked to metagenomic sequencing data from human and animal enteric samples from Vietnam Base-calling of automated sequencer traces using phred. I. Accuracy assessment Base-calling of automated sequencer traces using phred. II. Error probabilities We acknowledge the roles played by the entire VIZIONS consortium in obtaining these data Supplementary Information is available for this paper at https://doi.org/10.1038/s41597-019-0215-2.Competing Interests: The authors declare no competing interests.Publisher's note Springer Nature remains neutral with regard to jurisdictional claims in published maps and institutional affiliations.Open Access This article is licensed under a Creative Commons Attribution 4.0 International License, which permits use, sharing, adaptation, distribution and reproduction in any medium or format, as long as you give appropriate credit to the original author(s) and the source, provide a link to the Creative Commons license, and indicate if changes were made. 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