key: cord-285429-vmnj25b5
authors: Saikruang, Wilaiporn; Khamrin, Pattara; Suantai, Boonpa; Okitsu, Shoko; Hayakawa, Satoshi; Ushijima, Hiroshi; Maneekarn, Niwat
title: Detection of diarrheal viruses circulating in adult patients in Thailand
date: 2014-07-31
journal: Arch Virol
DOI: 10.1007/s00705-014-2191-3
sha: 
doc_id: 285429
cord_uid: vmnj25b5

A total of 332 fecal specimens collected during January-December 2008 from adult patients with diarrhea were screened for group A and C rotaviruses, noroviruses GI and GII, sapovirus, Aichi virus, human parechovirus, enterovirus, adenovirus and astrovirus by RT-multiplex PCR. The detection rate for diarrheal viruses was 4.2 %. Adenovirus and enterovirus were equally detected as the most predominant viruses, with prevalence of 1.2 %, followed by Aichi virus (0.9 %) and norovirus GII (0.6 %). Mixed infection with norovirus GII and human parechovirus was also detected (0.3 %). This study provides epidemiological data for a wide variety of diarrheal viruses circulating in adult patients with diarrhea in Chiang Mai, Thailand.

Acute gastroenteritis (AGE) is one of the most common diseases in children and adults and continues to be a significant cause of morbidity and mortality worldwide. The most common etiology is diarrheal viruses. Among various types of diarrheal viruses, norovirus (NoV) and rotavirus (RV) are considered to be the major cause of diarrhea [3] . Moreover, associations with other viruses such as adenovirus (AdV), sapovirus (SaV) and astrovirus (AstV) have also been reported in sporadic and outbreak cases of diarrhea [7, 19, 26, 27] . NoV is now recognized as the main cause of epidemic gastroenteritis in all age groups [20] . Among adults and elderly patients, NoV is responsible for 4.4 to 8.7 % of AGE cases [10] . RV is more common in children less than 5 years of age. Studies conducted in adults with gastroenteritis in several countries from Europe, America, Asia, and Australia have demonstrated that the prevalence of RV ranges from 2 to 40 % [2, 6, 9, 24] . Enteric AdV can also cause AGE in adults, but at a lower rate than those by RV or NoV infections, ranging from 1.5 to 5.4 % [11, 17] . AstV has also been shown to associate with AGE, with a frequency ranging between 2 and 26 % [19] . For SaV, although it is known to cause diseases primarily in children, it has also recently been reported to affect young adults to the elderly [12] . In addition, there are several reports of newly discovered enteric viruses that are associated with AGE in humans, including Aichi virus (AiV), human parechovirus (HPeV), enterovirus (EV), and human cosavirus (HCoSV) [1, 5, 15, 23, 25] .

In Thailand, there have been far fewer epidemiological studies of diarrheal viruses in adults than in children. Therefore, it is of interest to investigate the molecular epidemiology of diarrheal viruses in adults with diarrhea in Chiang Mai, Thailand.

A total of 332 fecal specimens were collected from adult patients with diarrhea, with the ages ranging from 15 to 90 years, who attended Chiang Mai University Hospital, Chiang Mai province, Thailand, during the period of January to December 2008. The specimens were stored at -20°C until used. The study was conducted with the approval of the Ethical Committee for Human Rights Related to Human Experimentation, Faculty of Medicine, Chiang Mai University (No. 181/2554).

The viral genome was extracted from a 10 % fecal suspension using a Geneaid Viral Nucleic Acid Extraction Kit II (Geneaid, Taipei, Taiwan). Then, the specimens were tested for the presence of SaV, AiV, group A rotavirus (RVA), group C rotavirus (RVC), HPeV, NoV GI and GII, EV, AdV, and AstV by RT-multiplex PCR using the protocol described previously by Khamrin et al. [14] . Positive and negative controls were also concurrently included along with the test samples. The oligonucleotide primers for the detection of each virus are shown in Table 1 .

The PCR products obtained from the specimens that were positive for diarrheal viruses were subjected to direct sequencing using a BigDye Terminator Cycle Sequencing Kit (Applied Biosystems, Foster City, CA, USA). The sequences obtained were compared with reference sequences by searching for closely related reference sequences in the NCBI GenBank database using the BLAST server (http://www.ncbi.nlm.nih.gov/blast). The nucleotide sequences of diarrheal viruses described in the present study have been deposited in the GenBank database. The accession numbers are as follows: KJ643239-KJ643242 for AdVs, KJ643243-KJ643246 for EVs, KJ643247 for HPeV, and KJ643248-KJ643250 for NoVs GII.

Screening by RT-multiplex PCR showed that 14 out of 332 (4.2 %) samples were positive for five types of diarrheal viruses. Among these, AdV, EV, AiV, NoV GII, and HPeV were detected, while RVA, RVC, SaV, NoV GI, and AstV were not found in this study. AdV and EV were detected as the most predominant viruses (1.2 %, 4 out of 332 for each virus), followed by AiV (0.9 %, 3 out of 332) and NoV GII (0.6 %, 2 out of 332). In addition, a mixed infection with NoV GII and HPeV was also detected in one fecal specimen (0.3 %), as shown in Table 2 .

Based on nucleotide sequence analysis, all three NoV GII specimens detected in the present study belonged to the GII.4 genotype. For AdV, three different genotypes were identified, including AdV24, AdV25, and AdV40. In addition, four strains of EV found in this study belonged to two different species, Enterovirus B and Enterovirus C. Interestingly, AiV of both genotypes A and B were also detected in this surveillance. Furthermore, one HPeV strain detected in this study belonged to genotype 1 ( Table 2) .

In this study, 4.2 % of fecal specimens collected from adults with diarrhea were positive for diarrheal viruses. Five types of viruses out of a total of 10 were detected in this study. Monoinfections with one type of virus were found for AdV, EV, AiV, and NoV GII. In addition, a mixed infection with NoV GII and HPeV was found in one case, but the impact of the mixed infection on clinical severity was not determined for this patient. It had been reported previously that no significant difference was found in the clinical symptoms of patients with multiple viral infections as compared to monoinfection [8] . The prevalence of diarrheal viruses detected in the present study is consistent with the findings reported previously in all age groups in Thailand, where the prevalence was reported at 5 % [17] . AdV infection occurs worldwide and may involve several systems and organs, including the upper and lower respiratory tract, the gastrointestinal (GI) tract, the urinary tract, and the eyes [28] . The AdV types that commonly infect the GI tract, the so-called enteric adenoviruses, are AdV40 and AdV41 in subgroup F. Sequence analysis showed that adenovirus detected in this study belonged to two distinct species (D and F) with three genotypes (Ad24, Ad25, and Ad40). When the AdV sequences detected in this study were compared to those from previous studies, the data clearly demonstrated that the AdV genotypes identified in children and adults are different. The AdV strains found in adults were AdV24 and AdV25 of subgroup D and AdV40 of subgroup F, while the strains identified previously in children were AdV1 of subgroup D, AdV3 of subgroup B, and AdV41 of subgroup F [7] . It is interesting to note that in the present study we detected AdV24 and AdV25, in addition to AdV40, in adult patients with diarrhea. The AdV types 24 and 25 commonly infect the eyes, causing conjunctivitis and epidemic keratoconjunctivitis [28] . To our knowledge, this is the first report of AdV24 and AdV25 in adult patients with diarrhea in this area. In this study, the EV detection rate in adult patients was 1.2 %, which is somewhat lower than that reported previously for children in Thailand in 2007 (2.5 %) [4] . Nucleotide sequence analysis of four EV strains detected in this study revealed that they belonged to species B and C. For AiV, the prevalence in adults is similar to that in children, where the detection rate is as low as 0.9 %. Molecular genetic analysis of the only AiV strain detected previously in a child with diarrhea in Chiang Mai, Thailand, revealed that it was genotype A [21] . It is interesting, however, to note that both genotype A and B of AiVs were detected in the present study. These data clearly demonstrate that the AiV strains circulating in this area are genetically diverse. Several epidemiological reports of NoV infections have shown that NoV GII, particularly GII.4, is the most predominant genotype in all parts of the world. Most recently, surveillance of NoV in Thailand revealed that the prevalence of NoV infection in all age groups is as high as 44.7 %. NoV GII was shown to be the most predominant genotype and accounted for 64.8 % of cases [18] . However, the NoV GII detection rate in adults with diarrhea in the present study was as low as 0.9 %. It is possible that NoV GII is not the major pathogen causing diarrhea in adults in this area. In addition, this study clearly demonstrates that HPeV is an unusual cause of acute gastroenteritis in adults compared to other viruses. The prevalence of HPeV infection in Thailand has only been reported in children with acute gastroenteritis at an infection rate of 14.6 % in 2005 [22] and 6.1 % in 2009-2011 [5] . The HPeV genotype found in adults in this study is genotype 1, which was the predominant genotype detected in diarrheal children. However, HPeV genotypes identified in children with diarrhea were highly diverse, including HPeV 1-6, 10, and 14 [5, 22] . It should be pointed out that rotavirus, which is the most important cause of diarrhea in pediatric patients, was not detected in adult diarrheic patients in the present study. The low prevalence and lack of detection of rotavirus infection in adult patients observed in this study might be due to immunity to rotavirus resulting from natural infection. The relatively low rate of diarrheal virus detection in adults with diarrhea in this study suggests that acute gastroenteritis in adults in this area may be caused by other pathogens. Further investigation for bacterial or parasitic infections may help to clarify this point. Nevertheless, several other diarrheal viruses that may cause diarrhea, including Saffold virus, pestivirus, coronavirus, picobirnavirus, and torovirus [16, 27] , were not included in the screening protocol in this study. In addition, the sensitivity limit of the multiplex PCR method or low amount of target viruses may also affect the detection rate.

In conclusion, this study demonstrates that a wide variety of viral pathogens that are associated with diarrhea are circulating in adult patients in Chiang Mai, Thailand. Since epidemiological information about gastroenteritis viruses in adults is limited, it is important to continue further surveillance, which may provide a better understanding of the whole picture of gastroenteritis virus epidemiology in the adult population.

Prevalence and genetic diversity of Aichi virus strains in stool samples from community and hospitalized patients

Rotavirus infection in adults

The etiology of severe acute gastroenteritis among adults visiting emergency departments in the United States

A wide variety of diarrhea viruses circulating in pediatric patients in Thailand

Molecular epidemiology, genome characterization, and recombination event of human parechovirus

Acute gastroenteritis associated with rotavirus in adults

Molecular epidemiology of adenovirus infection among infants and children with acute gastroenteritis in Dhaka City

Epidemiologic and molecular trends of ''Norwalk-like viruses'' associated with outbreaks of gastroenteritis in the United States

Diarrhoea in elderly people: aetiology, and clinical characteristics

Hospital admissions due to norovirus in adult and elderly patients in England

Etiology of acute gastroenteritis in three sentinel general practices

A nosocomial sapovirusassociated outbreak of gastroenteritis in adults

Diagnosis and epidemiology of echovirus 22 infections

A single-tube multiplex PCR for rapid detection in feces of 10 viruses causing diarrhea

Detection and molecular characterization of cosavirus in adults with diarrhea

Three clusters of Saffold viruses circulating in children with diarrhea in Japan

Molecular characterization of rotaviruses, noroviruses, sapovirus, and adenoviruses in patients with acute gastroenteritis in Thailand

Norovirus GII-4 2006b variant circulating in patients with acute gastroenteritis in Thailand during a 2006-2007 study

Outbreak of neonatal gastroenteritis associated with astrovirus serotype 1 at a hospital in Inner Mongolia

Noroviruses: a comprehensive review

Isolation and molecular characterization of Aichi viruses from fecal specimens collected in Japan

Diversity of human parechoviruses isolated from stool samples collected from Thai children with acute gastroenteritis

Identification of enteroviral infection among infants and children admitted to hospital with acute gastroentritis in Ho ChiMinh City. Vietnam

Serotype G9 rotavirus infections in adults in Sweden

Molecular detection and characterization of Aichivirus A in adult patients with diarrhea in Thailand

Genetic diversity of sapovirus in non-hospitalized adults with sporadic cases of acute gastroenteritis in Shanghai

Viruses causing gastroenteritis

Adenoviruses

Application of a reverse transcription-PCR for identification and differentiation of Aichi virus, a new member of the Picornavirus family associated with gastroenteritis in humans

Detection of norovirus (GI, GII), Sapovirus and astrovirus in fecal samples using reverse transcription single-round multiplex PCR

Development of RT-multiplex PCR assay for detection of adenovirus and group A and C rotaviruses in diarrheal fecal specimens from children in China

General primer-mediated polymerase chain reaction for detection of enteroviruses: application for diagnostic routine and persistent infections

The authors declare that they have no conflict of interest.