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Outbreak of febrile illness caused by coxsackievirus A4 in a nursery school in Beijing, China
Virology Journal volume 12, Article number: 92 (2015)
Coxsackievirus A4 (CV-A4) is classified as human enterovirus A according to its serotype. CV-A4, an etiological agent of hand, foot, and mouth disease, affects children worldwide and can circulate in closed environments such as schools and hospitals for long periods.
An outbreak of febrile illness at a nursery school in Beijing, China, was confirmed to be caused by CV-A4. Phylogenetic analysis of the complete genome of the isolated strain showed that the virus belongs to the same cluster as the predominant CV-A4 strain in China. This outbreak was controlled by effective measures.
The early identification of the pathogen and timely intervention may be the most critical factors in controlling an outbreak caused by CV-A4 in a preschool.
Human enteroviruses (HEVs) are a group of positive-sense single-stranded RNA viruses belonging to the genus Enterovirus, in the family Picornaviridae. HEVs are associated with hand, foot, and mouth disease (HFMD), herpangina and even death, and cause both sporadic infections and outbreaks, which often peak in summer and early autumn. Herpangina, predominantly caused by coxsackieviruses, often manifests as high fever, sore throat, and reduced appetite.
The genus Enterovirus includes 12 species. CV-A4 is classified as HEV-A based on its serotype, and is an etiological agent of HFMD [1–3]. The virus can be detected in throat swabs from herpangina patients , and can cause severe central nervous system symptoms . CV-A4 can circulate in closed environments for long periods, which may be attributable to its prolonged shedding in stools, poor hand hygiene, and/or close contact . CV-A4 has also been isolated from drinking water  and river water .
Here, we identified a febrile illness outbreak associated with CV-A4 in a preschool in China. The school, located in an urban district of Beijing, comprised six classes with 25–30 children in each class. One hundred sixty-five children, aged < 7 years, were in the care of 40 staff members. The class with the most cases of illness had 27 members, whereas another class with fewer cases had 26 children. “Case” is defined as any individual with symptoms that included a fever, cough, runny nose, and pharyngeal inflammation or a sore throat. “Intimate contact” is defined as any staff member or student with none of these symptoms. “Transmission rate” and “transmission period” are defined as reported previously . The demographic and clinical data for the study subjects were obtained from the school and informed consent was given by the parents/guardians of the subjects.
On 24 May 2011, a 4 year-old boy presenting with a mild fever (38.1 °C) and pharyngeal inflammation was diagnosed with an acute upper-respiratory infection. The number of cases then increased rapidly. By 10 June 2011, 23 children in the preschool showed similar symptoms: six were clinically confirmed as suffering an upper-respiratory tract infection and 17 had herpangina. Twenty cases were from Class One and the other three were from a nearby class. Their ages ranged from 3 to 5 years (mean age, 4.3 years) and the sex ratio (male:female) was 18:5 (3.6:1). Most of the children displayed a self-limiting illness, lasting for 2–4 days. All the patients had a good prognosis and there were no fatalities during this outbreak.
The most common symptoms in the affected children were fever (100 %; range, 37.9–41.0 °C) and pharyngeal inflammation or sore throat (21/23, 91.3 %). One boy had a cough and three had runny noses. No other symptoms were noted in any of the subjects. The mean duration of fever was 2.70 days (95 % confidence interval, 2.34–3.05). In seven cases, the peak body temperature was > 38.9 °C. Leukocytosis (white blood cell count > 15 × 109/L) was noted in four cases (Table 1). The peak incidence was between 27 May and 1 June, accounting for 78.3 % (18/23) of cases (Fig. 1).
Thirty-two oropharyngeal swabs were taken from 21 patients (no samples were available for two cases) and 11 intimate contacts from the two classes. All 32 swab specimens were stored in virus preservation solution at −70 °C until analysis. The nucleic acids were extracted with a QIAamp MinElute Virus Spin Kit (Qiagen, Valencia, CA, USA), according to the manufacturer’s instructions. All the samples were screened by PCR or RT–PCR for influenza A and B viruses, respiratory syncytial virus, human rhinovirus, human echovirus, parainfluenza viruses 1, 2, 3 and 4, human metapneumovirus, human coronavirus NL63, human adenovirus, and some HEVs, as reported previously [9–13]. The positive PCR products were purified and sequenced.
Of the 32 oropharyngeal swabs collected, 21 were positive for CV-A4. The detection rates in the patients and their intimate contacts were 81.0 % (17/21) and 36.4 % (4/11), respectively. Human adenovirus-3, human rhinovirus, and influenza B were also detected, but the samples were negative for the other viruses tested (Table 1). Outbreaks of human coxsackievirus infections in preschools are reported frequently worldwide and are typically associated with HFMD caused by the coxsackie A16 virus . However, febrile outbreaks caused by CV-A4 are rarely reported in preschools. In this study, 17 of the 21 tested cases were CV-A4 positive, strongly suggesting that this outbreak was caused by CV-A4.
Herpangina diseases are asymptomatic or self-limiting infections, often caused by EV71 or coxsackieviruses, including CV-A4. Chia-Jie Lee reported that herpangina caused by CV-A4 usually presented with high fever > 39.0 °C (75.5 %), oral ulcers (80.6 %), and leukocytosis (34.0 %), and that fever lasted longer than 3 days in 23.5 % of sufferers . In another outbreak in a preschool class, the transmission rate was 25.9 % (7/27) and the transmission period was 28 days . In our study, 42.9 % (9/21) of cases had high fever, and the fever persisted for more than 3 days in 14.3 % of patients (3/21) and for 3 days in 42.9 % of patients (9/21). The transmission rate was 74.1 % (20/27) in Class One, the transmission period was 18 days, and two CV-A4-positive patients had leukocytosis (leukocyte counts ≥ 15,000 /μL). We did not measure the white blood cell counts in all cases.
The virus was isolated from all CV-A4-positive throat samples in human rhabdomyosarcoma cells, using a previously reported protocol . Cytopathic effects were observed in 52.2 % (12/21) of the samples incubated with rhabdomyosarcoma cells. Twelve VP1 sequences and three complete genomes of CV-A4 (two from initial cases and one from intimate contact FT27) were amplified from the cell culture supernatants by RT–PCR and rapid amplification of cDNA ends–PCR, according to the manual supplied with the SMARTer™ RACE cDNA Amplification Kit (Japan, Tokyo) . The primer sequences and details of the reaction conditions are given in Table 2. The genome of CV-A4 is about 7460 bp and the VP1-encoding fragment is 915 bp. The genomes of three strains (FT27, FT7, and FT5) were 98.5–99.5 % homologous and the VP1 fragments of nucleic acids were 99.9–100 % homologous. These sequences shared 95.5–96.5 % identity with the clinical CV-A4 strain previously isolated in mainland China (GenBank: HQ728260). As expected, the polyproteins of FT7 and the CV-A4 mainland strain (GenBank: HQ728260) shared 96.5 % identity (VP4, 97.1 %; VP2, 96.7 %; VP3, 96.5 %; and VP1, 96.2 %) and the nonstructural proteins shared 95.8 % identity (2A, 95.1 %; 2B, 98.3 %; 2C, 95.3 %; 3A, 94.0 %; 3B, 98.5 %; 3C, 96.7 %; and 3D, 96.2 %).
In a phylogenetic analysis of the near-complete genome of the CV-A4 strain isolated in this outbreak, it clustered with the only two complete genomes of CV-A4 deposited in the GenBank database (Fig. 2). Analysis of a 3′ partial VP1 sequence, showed all CV-A4 isolates from this outbreak clustered on the same branch and were closely related to the predominant CV-A4 strains JL/CHN/2006 (GenBank: JQ715709) and SD/CHN/2008 (GenBank: GQ253374). All CV-A4 isolates from mainland China, Japan, India, and Taiwan, including CV-A4-mainland (GenBank: HQ728260), formed a subgenogroup, and isolates from the USA formed another subgenogroup within genotype III. Global CV-A4 strains show regional variations and were classed into three genotypes based on their 3′ partial VP1 sequences [3, 18]. Our results indicate that the CV-A4 strain isolated in this study probably also varies across its geographic distribution (Fig. 2). This CV-A4 strain is the predominant strain in China, resulting from the rapid lineage turnover of CV-A4 and the replacement of previously circulating strains by this new dominant variant .
CV-A4 is primarily transmitted via the fecal–oral route by contaminated hands, toys, and food. When the local Center for Disease Control received the report of this outbreak on June 1, normal control measures were taken, such as hand-washing, disinfection of the classroom, and body temperature screening. Health education was intensified and the public activities at all of the nursery schools were cancelled, as described previously [19, 20]. On June 1, the children in Classes One and Two celebrated Children’s Day with a party. On June 3, when the pathogens causing this outbreak were identified, the local Center for Disease Control suspended Class One for 10 days. During the outbreak, 20 children in Class One and three children in Class Two caught the disease. Although the transmission period of CV-A4 within a class is reported to be 28 days (6), this outbreak was controlled within 18 days. All the control measures used in this outbreak were similar to those used for HMFD caused by EV71.
This outbreak of febrile illness at a preschool in Beijing, China, was caused by CV-A4. Measures, such as surveillance in peak season, early identification of the pathogen and timely intervention, are key to controlling outbreaks of disease caused by CV-A4 or other HEVs.
Nucleotide sequence accession numbers
The three complete genomes have been submitted to the GenBank database under accession numbers KP676984, KP676985, and KP676986. Partial sequences of CV-A4 and other viral sequences have been deposited under accession numbers KP676948–KP676983.
Hand, foot, and mouth disease
Witso E, Palacios G, Cinek O, Stene LC, Grinde B, Janowitz D, et al. High prevalence of human enterovirus a infections in natural circulation of human enteroviruses. J Clin Microbiol. 2006;44:4095–100.
Yang F, Zhang T, Hu Y, Wang X, Du J, Li Y, et al. Survey of enterovirus infections from hand, foot and mouth disease outbreak in China, 2009. Virol J. 2011;8:508.
Hu YF, Yang F, Du J, Dong J, Zhang T, Wu ZQ, et al. Complete genome analysis of coxsackievirus A2, A4, A5, and A10 strains isolated from hand, foot, and mouth disease patients in China revealing frequent recombination of human enterovirus A. J Clin Microbiol. 2011;49:2426–34.
Zavate O, Avram G, Pavlov E, Burlea-Iriciuc A, Ivan A, Cotor F. Coxsackie A virus-associated herpetiform angina. Virologie. 1984;35:49–53.
Carey DE, Myers RM. Isolation of type A4 coxsackie virus from the blood serum of a child with rapidly fatal illness marked by severe central nervous system manifestations. Indian J Med Res. 1969;57:765–9.
Wu PC, Huang LM, Kao CL, Fan TY, Cheng AL, Chang LY. An outbreak of coxsackievirus A16 infection: comparison with other enteroviruses in a preschool in Taipei. J Microbiol Immunol Infect. 2010;43:271–7.
Nestor I, Costin L, Sovrea D, Ionescu N. Investigations on the presence of enteroviruses in drinking water. Virologie. 1978;29:203–7.
Simkova A, Wallnerova Z. Survival of small amounts of Coxsackie A4 virus in Danube river water under laboratory conditions. Acta Virol. 1973;17:505–6.
Lu X, Erdman DD. Molecular typing of human adenoviruses by PCR and sequencing of a partial region of the hexon gene. Arch Virol. 2006;151:1587–602.
Bellau-Pujol S, Vabret A, Legrand L, Dina J, Gouarin S, Petitjean-Lecherbonnier J, et al. Development of three multiplex RT-PCR assays for the detection of 12 respiratory RNA viruses. J Virol Methods. 2005;126:53–63.
Arthur JL, Higgins GD, Davidson GP, Givney RC, Ratcliff RM. A novel bocavirus associated with acute gastroenteritis in Australian children. PLoS Pathog. 2009;5:e1000391.
Donofrio JC, Coonrod JD, Davidson JN, Betts RF. Detection of influenza A and B in respiratory secretions with the polymerase chain reaction. PCR Methods Appl. 1992;1:263–8.
Savolainen C, Mulders MN, Hovi T. Phylogenetic analysis of rhinovirus isolates collected during successive epidemic seasons. Virus Res. 2002;85:41–6.
Ferson MJ, Bell SM. Outbreak of Coxsackievirus A16 hand, foot, and mouth disease in a child day-care center. Am J Public Health. 1991;81:1675–6.
Lee CJ, Huang YC, Yang S, Tsao KC, Chen CJ, Hsieh YC, et al. Clinical features of coxsackievirus A4, B3 and B4 infections in children. PLoS One. 2014;9:e87391.
Tao Z, Wang H, Li Y, Liu G, Xu A, Lin X, et al. Molecular epidemiology of human enterovirus associated with aseptic meningitis in Shandong Province, China, 2006–2012. PLoS One. 2014;9:e89766.
Freeman LA. Cloning full-length transcripts and transcript variants using 5' and 3' RACE. Methods Mol Biol. 2013;1027:3–17.
Chu PY, Lu PL, Tsai YL, Hsi E, Yao CY, Chen YH, et al. Spatiotemporal phylogenetic analysis and molecular characterization of coxsackievirus A4. Infect Genet Evol. 2011;11:1426–35.
Solomon T, Lewthwaite P, Perera D, Cardosa MJ, McMinn P, Ooi MH. Virology, epidemiology, pathogenesis, and control of enterovirus 71. Lancet Infect Dis. 2010;10:778–90.
McMinn PC. An overview of the evolution of enterovirus 71 and its clinical and public health significance. FEMS Microbiol Rev. 2002;26:91–107.
We thank all the staff members of the preschool who helped with this study.
The authors declare that they have no competing interests.
JSL identified the pathogens causing this outbreak, performed the genetic analysis, and drafted the manuscript; XGD collected the samples and undertook the epidemiological investigation; MQ collected the samples and undertook the epidemiological investigation; ZPX identified the pathogens causing the outbreak; GHC isolated the viruses and participated in the whole-genome sequencing; DDL participated in the whole-genome sequencing; JYY conducted the epidemiological investigation and outbreak control; XXY conducted the epidemiological investigation and outbreak control; JL participated in the design of the study; and ZJD participated in the design of the study and edited the manuscript. All authors have read and approved the final manuscript.
Jin-Song Li and Xiao-Gen Dong contributed equally to this work.
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Li, JS., Dong, XG., Qin, M. et al. Outbreak of febrile illness caused by coxsackievirus A4 in a nursery school in Beijing, China. Virol J 12, 92 (2015). https://0-doi-org.brum.beds.ac.uk/10.1186/s12985-015-0325-1
- Coxsackievirus A4