Human bocavirus infection, People's Republic of China.A newly identified parvovirus, human bocavirus (HBoV), was found in 21 (8.3%) of 252 nasopharyngeal aspirates from hospitalized children with lower respiratory tract infection in Hunan Province, People's Republic of China. Viral loads were [10.sup.4] to [10.sup.10] copies/mL. Phylogenetic analysis of the VP1 gene showed a single genetic lineage of HBoV worldwide. ********** Acute respiratory tract infections (ARTIs) are a leading cause of hospitalization, illness, and death in infants and young children (1-4). Respiratory syncytial virus (RSV), human metapneumovirus (HMPV), influenza viruses, human coronaviruses, rhinoviruses, and adenoviruses are some of the most important viral agents for this group of patients. However, in a substantial proportion of children with respiratory tract diseases, no pathogen can be identified (1). Until recently, the only parvovirus known to be pathogenic for humans is B19 (5). In 2005, a new human virus of the genus Bocavirus considered to be pathogenic for humans, provisionally named human bocavirus (HBoV), was described in Sweden (1). Subsequently, HBoV infection was reported in children with ARTIs in Australia (6), Japan (7), Canada (8), France (9), and the United States (10). In our study, 252 nasopharyngeal aspirates (NPA) obtained from November 3, 2005, to April 3, 2006, from hospitalized children with lower respiratory tract infections were analyzed for the presence of HBoV because of associated clinical manifestations. The Study Participants in the study were children [less than or equal to] 10 years of age who were hospitalized from November 3, 2005, to April 3, 2006, in Hunan Province, People's Republic of China. They were admitted mostly for bronchitis, pneumonia, and bronchopneumonia bronchopneumonia /bron·cho·pneu·mo·nia/ (-ndbobr-mo´ne-ah) bronchial pneumonia; inflammation of the lungs beginning in the terminal bronchioles. bron·cho·pneu·mon·ia (br  ng; their
NPA were collected for investigation of the cause. All children were
admitted 2-6 days after the onset of ARTI. All specimens were collected
after the parents of the enrolled children had given informed consent.DNA was extracted from NPA specimens by using the QIAamp Viral DNA Mini Kit (QIAGEN, Beijing, China). HBoV in extracted DNA was detected by PCR amplification of a 291-bp fragment of the NS1 gene as described previously (6). To acquire the complete sequence of the VP1 gene, we used primers 5'-GATAACTGACGAGGAAATG-3' and 5'-GAGACGGTAACACCACTA-3' based on the published genomic sequence of HBoV (GenBank accession no. NC_007455). The PCR cycle included an initial heating at 95[degrees]C for 15 min; 40 cycles of 94[degrees]C for 45 s, 50[degrees]C for 45 s, and 72[degrees]C for 2 min; and a final extension at 72[degrees]C for 10 min. Both short and long PCR products were sequenced. Sequencing was performed on an Applied Biosystems 3730 XL DNA Analyzer (Applied Biosystems, Foster City, CA, USA) by using both the forward and reverse primers. The complete sequences of the VP1 gene obtained were aligned with sequences available in GenBank by using Clustal X (ftp://ftp-igbmc.u-strasbg.fr/pub/ClustalX/). A neighbor-joining tree was constructed by the neighbor-joining method using the MEGA 3.1 program (www.megasoftware.net) and sequences of canine minute virus (MVC) and bovine parvovirus (BPV BPV - Back Pressure Valve (oil and gas industry) BPV - Banca Popolare di Verona (Italian Bank) BPV - Battle Planning and Visualization BPV - Benign Positional Vertigo BPV - Bipolar Violation BPV - Bipropellant Valve BPV - Bovine Papilloma Virus BPV - Bullet Piercing Valve (ice maker installation) BPV - Bullet Proof Vest BPV - Bundesamt für Privat Versicherungen (Bern, Switzerland) BPV - Bupivacaine). Human parvovirus B19 (B19) was used as the outgroup. A TaqMan real-time PCR targeting the NS1 region of HBoV was conducted to quantify the viral load. In brief, 2 [micro]L genomic DNA was amplified in a 25-[micro]L PCR mixture containing 5 [micro]L ABI TaqMan 2x PCR Master mix, 20 [micro]M of each primer, and 20 [micro]M of the probe. The primer sequences used were 5'-TAATGACTGCAGACAACGCCTAG-3' and 5'-TGTCCCGCCCAAGATACACT-3', and the probe was 5'-FAM-TTCCACCCAATCCTGGT-MGB MGB - Machine Gun Blow (gaming) MGB - Magandang Gabi Bayan (Good Evening Nation, Philippine TV newsmagazine) MGB - Main Gear Box MGB - Main Ground Bus MGB - Manual Gearbox MGB - Mardergraphics Berlin MGB - Mass Group Buff (gaming) MGB - Master Ground Bar MGB - Matthew Good Band MGB - May God Bless MGB - Medial Geniculate Body MGB - Medium Girder Bridge MGB - Metal Graphite Brush MGB - Microsoft Global Briefing MGB - Mini-Gastric Bypass-3'. The cycling conditions included initial incubations at 50[degrees]C for 2 min and 95[degrees]C for 10 min, followed by 40 cycles of 95[degrees]C for 15 s and 60[degrees]C for 30 s. Plasmid pGEM-T-NS1 containing the target sequences was constructed and used as a positive control for copy number calculation. Sensitivity of the PCR assay was 100 copies per reaction, as determined by dilutions of the plasmid. RNA was also extracted from each NPA specimen by using the QIAamp Viral RNA Mini Kit (QIAGEN) to screen for HMPV (11), RSV (12), infuenza (A, B, and C) (13), parainfluenza (types 1-4) (13), and human coronaviruses (229E, OC43, NL63, and HKU1) by standard reverse transcription--PCR technique (13-15). HBoV was detected by the diagnostic PCR in 21 (8.3%) of NPA specimens collected from 252 hospitalized children with ARTI. Serum samples available from 2 of the HBoV-positive patients were also positive. Two HBoV-positive patients (patient 7 and patient 10) had coinfection coinfection /co·in·fec·tion/ (ko´in-fek?shun) simultaneous infection by separate pathogens, as by hepatitis B and hepatitis D viruses. with human coronavirus 229E. Among the HBoV-positive patients, 17 (81%) were male, and 4 (19%) were female (Table). The ages of the infected patients were 2 months to 3 years (median age 10.5 months), with the exception of a 10-year-old boy (patient 8). The most common clinical signs and symptoms were cough (86%), fever (33%), wheezing (33%), and diarrhea (29%) (Table). The 3 main admission diagnoses were pneumonia (6 patients), bronchitis (6 patients), and bronchopneumonia (7 patients). These patients had been admitted to hospital for 2 to 28 days. Chest radiographs were obtained from 12 patients; all showed abnormal findings (6 had airspace shadows, and 6 displayed coarse lung markings). Most HBoV-positive patients had no other underlying illness, with the exception of 1 (patient 3) who had intracranial infection. Although cough and diarrhea were more frequently found in HBoV-infected children (86% and 29%, respectively) than in HBoV-uninfected children (60% and 7.8%, respectively), confirmation of the disease association of HBoV infection requires the analysis of HBoV in a negative control group of healthy children. HBoV viral loads in NPA specimens ranged from 2.4 x [10.sup.4] to 2.5 x [10.sup.10] copies/mL (Table). The 2 positive serum specimens (from patients 7 and 10) had 1.2 x [10.sup.5] and 4.1 x [10.sup.4] copies/mL, respectively, which were almost equal to those found in their corresponding NPA specimens. Most specimens had HBoV viral loads close to [l0.sup.4] copies/mL. However, 5 (24%) NPA specimens had viral loads >[10.sup.9] copies/mL. The entire VP1 gene of HBoV was sequenced for 5 specimens that had adequate amounts of genomic DNA. An alignment of VP1 sequences obtained from children in China with those previously reported for the prototype strains (ST1 and ST2 strains, GenBank accession nos.DQ000495--DQ000496) showed only minor sequence differences, with a nucleotide identity of 97.7% and an amino acid identity of 98.1%. Thus, HBoV is a highly conserved virus. Phylogenetic analysis of these sequences and those from BPV, MVC, and B19 indicated that HBoV was more related to BPV and MVC (Figure). [FIGURE OMITTED] Conclusions The prevalence of HBoV in children and the associated illness have not been well characterized. In this study, we found that HBoV was prevalent in infants and young children in China. The 8.3% prevalence rate is higher than rates (3.1%-5.7%) previously reported for children in Sweden, Australia, Japan, Canada, France, and the United States (1,6-10). This difference could be due to the fact that we screened specimens collected during the peak ARTI season. Because this is the first finding of HBoV in children in developing countries, whether the difference also reflects a higher prevalence of the infection in developing countries is unclear. The symptoms associated with HBoV infection in Chinese children are similar to those reported for children from other countries (6-10) and are comparable to those observed in children infected with other respiratory viruses, with a predominance of bronchitis or pneumonia (11,13,15). Our results indicate several risk factors for HBoV infection. Consistent with cases reported in the United States (10), 57% of our HBoV-positive patients were [less than or equal to] 12 months of age. Chest radiographs obtained from all 12 patients had abnormal findings. Major diagnoses were pneumonia, bronchitis, and bronchopneumonia. Collectively, these findings support the notion that HBoV infection may be associated with lower respiratory diseases, as suggested by Allander et al. (1). We did not find any association between the viral loads and disease severity and could not explain the difference in viral loads among specimens. Nevertheless, the viral loads in serum specimens were similar to those from NPA specimens in the 2 HBoV-positive patients who had both serum and NPA specimens. In our study, 29% of patients had diarrhea, which was also reported in 16% of HBoV--positive patients in the United States (10). Unfortunately, we did not collect stool specimens from HBoV-positive patients for viral detection. Detection of HBoV in serum specimens from 2 patients suggests that HBoV may cause viremia, which was supported by the occurrence of intracranial infection in 1 patient. However, further studies are required to confirm whether HBoV indeed causes viremia. In addition, coinfection with human coronavirus 229E was identified in 2 of the 21 HBoV-positive children in our study. Although RSV, HMPV, and human coronavirus 229E were detected in 13.5%, 7.9%, and 6.0%, respectively, of the patients, no other children were found to be coinfected with HBoV and another virus. This rate of coinfection is lower than that reported for other countries (1,6,7,10). Whether seasonal or other factors might account for this difference remains to be determined. In agreement with previous findings in other countries (1,6,7,10), results of our study indicate that HBoV is a conserved virus. Additional epidemiologic studies in different regions and sequence analysis of other genes are required to investigate the overall distribution, seasonality, and genetic variations of HBoV and to examine the origin of current HBoV endemics. Acknowledgments We thank Bing Zhang, Li-Li Zhong, Jin-Yan Zhou, Jing-Song Liu, and Qiao-Tu Liu for their assistance in this study and Dong-Yan Jin for critical reading of our manuscript. References (1.) Allander T, Tammi MT, Eriksson M, Bjerkner A, Tiveljung-Lindell A, Andersson B. Cloning of a human parvovirus by molecular screening of respiratory tract samples. Proc Natl Acad Sci U S A. 2005;102:12891-6. (2.) Iwane MK, Edwards KM, Szilagyi PG, Walker FJ, Griffin MR, Weinberg GA, et al. Population-based surveillance for hospitalizations associated with respiratory syncytial virus, influenza virus, and parainfluenza viruses among young children. Pediatrics. 2004;113:1758-64. (3.) Juven T, Mertsola J, Waris M, Leinonen M, Meurman O, Roivainen M, et al. Etiology of community-acquired pneumonia in 254 hospitalized children. Pediatr Infect Dis J. 2000;19:293-8. (4.) Jartti T, Lehtinen P, Vuorinen T, Osterback R, van den Hoogen B, Osterhaus AD, et al. Respiratory picoruaviruses and respiratory syncytial virus as causative agents of acute expiratory wheezing in children. Emerg Infect Dis. 2004; 10:1095-101. (5.) Young NS, Brown KE. Parvovirus B19. N Engl J Med. 2004;350:586-97. (6.) Sloots TP, McErlean P, Speicher DJ, Arden K, Nissen MD, Mackay IA. Evidence of human coronavirus HKU1 and human bocavirus in Australian children. J Clin Virol. 2006;35:99-102. (7.) Ma X, Endo R, Ishiguro N, Ebihara T, Ishiko H, Ariga T, et al. Detection of human bocavirus in Japanese children with lower respiratory tract infections. J Clin Microbiol. 2006;44:113-4. (8.) Bastien N, Brandt K, Dust K, Ward D, Li Y. Human bocavirus infection, Canada. Emerg Infect Dis. 2006;12:848-50. (9.) FouLongne V, Rodiere M, Segondy M. Human bocavirus in children. Emerg Infect Dis. 2006;12:862-3. (10.) Arnold JC, Singh KK, Spector SA, Sawyer MH. Human bocavirus: prevalence and clinical spectrum at a children's hospital. Clin Infect Dis. 2006;43:283-8. (11.) Williams JV, Harris PA, Tollefson SJ, Halburnt-Rush LL, Pingsterhaus JM, Edwards KM, et al. Human metapneumovirus and lower respiratory tract disease in otherwise healthy infants and children. N Engl J Med. 2004;350:443-50. (12.) Sampalis JS. Morbidity and mortality after RSV-associated hospitalizations among premature Canadian infants. J Pediatr. 2003; 143:S150-6. (13.) Chiu SS, Chan KH, Chu KW, Kwan SW, Guan Y, Poon LL, et al. Human coronavirus NL63 infection and other coronavirus infections in children hospitalized with acute respiratory disease in Hong Kong, China. Clin Infect Dis. 2005;40:1721-9. (14.) 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. (15.) Woo PC, Lau SK, Tsoi HW, Huang Y, Poon RW, Chu CM, et al. Clinical and molecular epidemiological features of coronavirus HKU1-associated community-acquired pneumonia. J Infect Dis. 2005;192:1898-907. (1) These authors contributed equally to this work. Xiao-Wang Qu, * (1) Zhao-Jun Duan, * (1) Zheng-Yu Qi, * Zhi-Ping Xie, * Han-Chun Gao, * Wen-Pei Liu, * Can-Ping Huang, * Fu-Wang Peng, * Li-Shu Zheng, * and Yun-De Hou * * Chinese Center for Disease Control and Prevention, Beijing, People's Republic of China Xiao-Wang Qu is a PhD student at the Institute for Viral Disease Control and Prevention, Chinese Center for Disease Control and Prevention. His research interests are in the epidemiology and molecular biology of respiratory viruses. Address for correspondence: Zhao-Jun Duan, Institute for Viral Disease Control and Prevention, 100 Ying-Xin St, Xuan Wu District, Beijing, 100052, People's Republic of China; email: zhaojund@126.com
Table Clinical data for children with human bocavirus DNA detected in
nasopharyngeal aspirate (NPA) specimens *
Patient Age, Days in
no. (sex) mo hospital Diagnosis Signs/symptoms
1 (F) 12 5 P Fever, vomiting, diarrhea
2 (M) 18 15 P Cough, rash
3 (M) 12 28 II Cough, hypodynamia
4 (M) 8 3 B Fever, clonism
5 (M) 10 15 BP Cough
6 (F) 2 2 BP Dyspnea, cyanosis
7 (M) 4 11 BP Cough, diarrhea
8 (M) 120 10 P Fever, cough
9 (M) 9 19 B Cough, wheeze
10 (M) 2 16 SP Cough, foaming, ALTE
11 (M) 24 7 P Cough, wheeze
12 (M) 14 6 B Cough, wheeze, polypnea
13 (M) 36 14 B Fever, cough, wheeze
14 (F) 8 17 B Fever, cough, wheeze
15 (M) 6 8 BP Cough, polypnea, diarrhea
16 (F) 6 8 FOU Fever, cough, wheeze
17 (M) 6 5 BP Cough, diarrhea
18 (M) 15 9 B Cough, wheeze, diarrhea
19 (M) 7 9 BP Cough, polypnea
20 (M) 2 15 BP Cough, polypnea
21 (M) 9 6 P Fever, cough, diarrhea
Patient
no. (sex) Chest radiograph Copies/mL specimen(NPA)
1 (F) NR 1.2 x [10.sup.10]
2 (M) BA-ILM 3.1 x [10.sup.4]
3 (M) RLZ-AS 5.1 x [10.sup.9]
4 (M) NR 4.3 x [10.sup.4]
5 (M) BA-ILM 2.5 x [10.sup.10]
6 (F) RLZ-AS 4.7 x [10.sup.4]
7 (M) BA-ILM 1.6 x [10.sup.5] (1.2 x [10.sup.5])
([dagger])
8 (M) BA-ILM 4.4 x [10.sup.4]
9 (M) NR 1.8 x [10.sup.9]
10 (M) BAS 6.7 x [10.sup.4] (4.4 x [10.sup.4])
([dagger])
11 (M) RUZ-AS 1.8 x [10.sup.9]
12 (M) NR 4.2 x [10.sup.4]
13 (M) NR 4.8 x [10.sup.4]
14 (F) NR 5.5 x [10.sup.4]
15 (M) BA-ILM 2.4 x [10.sup.4]
16 (F) BA-ILM 7.3 x [10.sup.4]
17 (M) BAS 4.5 x [10.sup.4]
18 (M) NR 6.1 x [10.sup.4]
19 (M) NR 3.8 x [10.sup.5]
20 (M) BAS 7.6 x [10.sup.4]
21 (M) NR 8.3 x [10.sup.4]
* M, male; F, female; P, pneumonia; NR, none reported; BA, bilateral
airspace; ILM, increased lung marking; II, intracranial infection; RLZ,
right lower zone; B, bronchitis; BP, bronchopneumonia; SP, severe
pneumonia; ALTE, apparent life-threatening event; RUZ, right upper
zone; AS, airspace shadows; FOU, fever of unknown origin; BAS,
bilateral airspace shadows.
([dagger]) Parentheses show virus titer in serum sample.
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