Skip directly to site content Skip directly to page options Skip directly to A-Z link Skip directly to A-Z link Skip directly to A-Z link
Volume 29, Number 9—September 2023
Dispatch

Emergence of GII.4 Sydney[P16]-like Norovirus-Associated Gastroenteritis, China, 2020–2022

On This Page
The Study
Conclusions
Cite This Article
Figures
Figure 1
Figure 2
Tables
Table
Downloads
Article
Appendix
RIS [TXT - 2 KB]
Article Metrics
Metric Details
Author affiliations: Children's Hospital of Fudan University, Shanghai, China (Y. Ao, L. Lu, J. Xu); Shanghai Institute of Infectious Disease and Biosecurity of Fudan University, Shanghai, China (J. Xu).

Cite This Article

Abstract

Newly evolved GII.4 Sydney[P16] norovirus with multiple residue mutations, already circulating in parts of China, became predominant and caused an abrupt increase in diagnosed norovirus cases among children with gastroenteritis in Shanghai during 2021–2022. Findings highlight the need for continuous long-term monitoring for GII.4 Sydney[P16] and emergent GII.4 norovirus variants.

Norovirus, the main cause of nonbacterial acute gastroenteritis (AGE) outbreaks worldwide (1), is a positive-sense, single-stranded RNA virus within the family Caliciviridae. Its genome contains 3 open reading frames (ORFs): ORF1 encodes a polyprotein cleaved into 6 nonstructural proteins, including RNA-dependent RNA polymerase (RdRp); ORF2 encodes major (VP1) and ORF3 minor (VP2) capsid proteins (2). On the basis of VP1 amino acid sequences, noroviruses can be grouped into 10 genogroups (GI–GX) and 49 genotypes (3); GI and GII genogroups are the most common in human infections.

Since 2002, GII.4 has been the predominant norovirus genotype worldwide (4,5). GII.4 Sydney norovirus recombinant with a GII.P31 polymerase, GII.4 Sydney[P31], emerged in 2012 and caused pandemic illness during 2012–2013 (6). However, in 2015, a recombinant GII.4 Sydney[P16] norovirus emerged and recently became predominant in some Western countries (710). GII.4 Sydney[P16] norovirus has advantageous epidemic potential because of viral fitness from its recombinant components: emerging GII.P16 polymerase and persistently mutating GII.4 VP1 (11,12). Although GII.4 Sydney[P16] norovirus prevalence has rarely been reported in China (13), its advantageous qualities raise concerns about the virus possibly causing an epidemic. To monitor epidemiologic and genetic data from GII.4 Sydney[P16] norovirus in China, we performed laboratory-based surveillance of noroviruses among children with AGE in Shanghai.

The Study

Beginning in 2016, fecal specimens were collected from children ≤5 years of age with AGE seen as outpatients at Children’s Hospital of Fudan University in Shanghai; case-patients from local outbreaks were excluded. AGE is defined as 3 episodes of loose feces or 2 episodes of vomiting within 24 hours. We tested fecal samples for GI and GII norovirus by dual-genotyped reverse transcription PCR (RT-PCR), as described elsewhere (14). We genotyped sequences using the norovirus typing tool of the Dutch National Institute for Public Health and the Environment (https://www.rivm.nl/mpf/norovirus/typingtool). We measured concentrations of viral RNA in norovirus-positive samples using real-time RT-PCR with primers/probe targeting the conserved ORF1–ORF2 junction, as described elsewhere (15).

Figure 1

Emergence of recombinant GII.4 Sydney[P16] norovirus associated with acute gastroenteritis among children treated as outpatients in Shanghai, before and during COVID-19 pandemic, Shanghai, China, during January 2016–March 2022. A) Numbers of cases of norovirus-associated acute gastroenteritis. Red arrow indicates an abrupt increase in norovirus activity. B) Genotype (polymerase-capsid) distribution of norovirus. Different norovirus genotypes are indicated by color (key). Start date of COVID-19 pandemic declared by World Health Organization was March 11, 2020; absent labels indicate period (September–December 2019) during which fecal sample collection was paused.

Figure 1. Emergence of recombinant GII.4 Sydney[P16] norovirus associated with acute gastroenteritis among children treated as outpatients in Shanghai, before and during COVID-19 pandemic, Shanghai, China, during January 2016–March 2022. A) Numbers...

We determined that, during January 2016–March 2022, a total of 301/2,419 (12.4%) fecal samples from cases in children were norovirus-positive (Figure 1, panel A). Annually, the peak number of norovirus cases has been detected in samples taken during winter, exhibiting a seasonal characteristic. Each year during 2016–2019, there were <60 norovirus cases; during 2020, the first year of the COVID-19 pandemic, norovirus activity abruptly decreased to 13 cases, but rates then unexpectedly increased to 110 cases in 2021, a trend similar to the proportion of norovirus cases among all gastroenteritis cases (data not shown). Of note, 40 (36.4%) cases were identified in samples taken during November–December 2021; a total of 11 cases were detected in samples taken during January–March 2022.

We observed a dynamic profile of norovirus genotypes in cases among children during 2016–2022 (Figure 1, panel B). Before the COVID-19 pandemic, the predominant genotypes were GII.4 Sydney[P31] during 2016–2017 and GII.4 Sydney[P31] and GII.3[P12] during 2018–2019; however, GII.4 Sydney[P16] suddenly emerged in November 2020 and predominated in 2021. Of 110 norovirus samples in 2021, we successfully genotyped 100. GII.4 Sydney[P16], the predominant genotype, was identified in 60 (60%) samples, followed by GII.4 Sydney[P31] in 14 (14%), GII.2[P16] in 9 (9%), GII.3[P12] in 7 (7%), GII.17[P17] in 3 (3%), GII.6[P7] in 3 (3%), and other genotypes in 2 (2%). Of note, the proportion of GII.4 Sydney[P16] cases rose sharply to 42/55 (76.4%) during October–December 2021 and 7/11 (70%) cases during January–March 2022.

Figure 2

Phylogenetic analysis of newly identified GII.4 Sydney[P16] noroviruses in Shanghai, China, 2020–2022. Maximum-likelihood phylogenetic trees show complete genome (A) RNA-dependent RNA polymerase (RdRp) (B) and VP1 (C) gene sequences for newly identified GII.4 Sydney[P16] strains (n = 23) in Shanghai. Pink shading indicates new sublineage (tentatively named SHGII.4-2020) in GII.4 Sydney[P16] cluster. Branches of each strain in SHGII.4-2020 are indicated by color according to identified positions; red indicates GII.4 Sydney[P16] strains identified in this study, except SH18-36. Numbers on ancestral nodes represent node support values.

Figure 2. Phylogenetic analysis of newly identified GII.4 Sydney[P16] noroviruses in Shanghai, China, 2020–2022. Maximum-likelihood phylogenetic trees show complete genome (A) RNA-dependent RNA polymerase (RdRp) (B) and VP1 (C) gene sequences for...

Using high-throughput sequencing, we identified 23 complete genomes of GII.4 Sydney[P16] (GenBank accession nos. OP037976–83 and OQ940068–82) from 23 case-patients. Maximum-likelihood phylogenetic trees of GII.4 Sydney[P16] full-length RdRp and VP1 genes all showed that 22 strains from November 2020–December 2021 clustered together with strains recently identified in Beijing (GenBank accession nos. OL336332.1, OL336335.1–41.1, and OL336352.1–89.1), Taiwan (ON329737.1), and Thailand (MW521126.1–7.1 and MW521129.1–30.1) (Appendix Table), which evolved into a genetically distinct sublineage (tentatively named SHGII.4-2020) in the GII.4 Sydney[P16] cluster (Figure 2). All trees showed SHGII.4-2020 most closely related to SH18-36, the first identified GII.4 Sydney[P16] strain in our study, implying that SH18-36 might constitute an evolutionary ancestor of SHGII.4-2020.

Compared with sequences of GII.4 Sydney[P16] strains from GenBank, SHGII.4-2020 had 19 aa mutations: 10 in nonstructural proteins (T169S and L305F in p48; K84R, V88I and I168V in p22; K103R in VPg; K54R, V125A, A311T and N427T in RdRp), 2 in VP1 (R297H and D372N), and 7 in VP2 (K80R, A108V, A128S, N157T, T164A, I174T and N207S) (Appendix Figure 1). In VP1, R297H and D372N substitutions were mapped to the main antigenic epitope A, and D372N was also present around the HBGA binding site II (Appendix Figure 2). Those 2 residues, 297H and 372N, were only identified in certain previous GII.4 Sydney[P16] strains (MG002631.1, MH922876, and MK754444). Three substitutions, K54R, V125A, and N427T, were located on the surface of RdRp (Appendix Figure 2); A312T resided adjacent to motif B. In addition, we found 7 unique mutations in Shanghai strains. Further studies of these SHGII.4-2020 mutations are needed to better understand their role in its emergence.

We performed comparative clinical analysis of SHGII.4-2020, GII.4 Sydney[P31] and GII.3[P12] cases. The median age of SHGII.4-2020 case-patients (21.5 months, interquartile range [IQR] 15–50.3 months) was older than those for GII.4 Sydney[P12] (12 months, IQR 9–19.3 months) and GII.3[P12] (12 months, IQR 8–26.75 months; p<0.005) case-patients (Table). We observed SHGII.4-2020 more commonly than GII.4 Sydney[P31] among children >36 months of age, whereas the converse was true among children <12 months of age (p<0.005) (Table). Vomiting was a more common clinical sign among SHGII.4-2020 case-patients than among GII.4 Sydney[P31] and GII.3[P12] case-patients (p<0.05) (Table). The median viral RNA load (cycle threshold value) for SHGII.4-2020 (15.86, IQR 13.95–18.74) was higher than those for GII.4 Sydney[P31] (17.00, IQR 15.11–20.32; p = 0.0372) and GII.3[P12] (17.98, IQR 15.76–21.75; p = 0.0093) (Appendix Figure 3). Five samples with high cycle threshold values (>25.0) for each genotype were randomly selected for primer/probe sequence mismatch analysis; no mismatch was found.

Conclusions

We provide evidence that GII.4 Sydney[P16] norovirus has evolved into a new sublineage, SHGII.4-2020, that carries multiple mutations and is circulating in different regions of China. We found that SHGII.4-2020 became the predominant norovirus genotype and resulted in an abrupt increase in diagnosed cases among children treated as outpatients at a hospital in Shanghai during 2021–2022. Based on data from CaliciNet China, GII.2[P16] was identified as the dominant genotype in 2016–2020 norovirus outbreaks in China (13), but more recent data have not been reported. The viral load in feces for SHGII.4-2020 was higher than for GII.4 Sydney[P31] and GII.3[P12] noroviruses, suggesting the higher viral replication efficiency and transmissibility of SHGII.4-2020. However, further multivariate analyses are needed to exclude potential confounding factors, such as time interval from sign and symptom onset to sample collection, which may have biased those results. The higher proportion of case-patients experiencing vomiting during infection with SHGII.4-2020 is of particular clinical and epidemiologic interest because this symptom profile may affect how that norovirus strain spreads and cause a changes in epidemiology. Although our study was limited by a small number of cases and its single-center setting, our findings highlight the need for continuous long-term monitoring for global spread of SHGII.4-2020 and emergence of newly evolving GII.4 norovirus variants.

Dr. Ao is a virologist in the Department of Clinical Laboratory, Children's Hospital of Fudan University, National Children’s Medical Center. His research interests include evolutionary analysis and epidemic mechanisms of emerging enteric viruses.

Top

Acknowledgment

This work was supported by grants from the National Natural Science Foundation of China (no. 82202495), General Project of Natural Science Foundation of Shanghai (no. 22ZR1408200), and the Key Development Program of the Children's Hospital of Fudan University (no. EK2022ZX05).

Top

References

  1. Ahmed  SM, Hall  AJ, Robinson  AE, Verhoef  L, Premkumar  P, Parashar  UD, et al. Global prevalence of norovirus in cases of gastroenteritis: a systematic review and meta-analysis. Lancet Infect Dis. 2014;14:72530. DOIPubMedGoogle Scholar
  2. Robilotti  E, Deresinski  S, Pinsky  BA. Norovirus. Clin Microbiol Rev. 2015;28:13464. DOIPubMedGoogle Scholar
  3. Chhabra  P, de Graaf  M, Parra  GI, Chan  MC, Green  K, Martella  V, et al. Updated classification of norovirus genogroups and genotypes. J Gen Virol. 2019;100:1393406. DOIPubMedGoogle Scholar
  4. Siebenga  JJ, Vennema  H, Zheng  DP, Vinjé  J, Lee  BE, Pang  XL, et al. Norovirus illness is a global problem: emergence and spread of norovirus GII.4 variants, 2001-2007. J Infect Dis. 2009;200:80212. DOIPubMedGoogle Scholar
  5. Vinjé  J, Altena  SA, Koopmans  MP. The incidence and genetic variability of small round-structured viruses in outbreaks of gastroenteritis in The Netherlands. J Infect Dis. 1997;176:13748. DOIPubMedGoogle Scholar
  6. van Beek  J, Ambert-Balay  K, Botteldoorn  N, Eden  JS, Fonager  J, Hewitt  J, et al.; NoroNet. Indications for worldwide increased norovirus activity associated with emergence of a new variant of genotype II.4, late 2012. Euro Surveill. 2013;18:89. DOIPubMedGoogle Scholar
  7. Barclay  L, Cannon  JL, Wikswo  ME, Phillips  AR, Browne  H, Montmayeur  AM, et al. Emerging novel GII.P16 noroviruses associated with multiple capsid genotypes. Viruses. 2019;11:11. DOIPubMedGoogle Scholar
  8. Cannon  JL, Barclay  L, Collins  NR, Wikswo  ME, Castro  CJ, Magaña  LC, et al. Genetic and epidemiologic trends of norovirus outbreaks in the United States from 2013 to 2016 demonstrated emergence of novel GII.4 recombinant viruses. J Clin Microbiol. 2017;55:220821. DOIPubMedGoogle Scholar
  9. Bidalot  M, Théry  L, Kaplon  J, De Rougemont  A, Ambert-Balay  K. Emergence of new recombinant noroviruses GII.p16-GII.4 and GII.p16-GII.2, France, winter 2016 to 2017. Euro Surveill. 2017;22:30508. DOIPubMedGoogle Scholar
  10. Lun  JH, Hewitt  J, Yan  GJH, Enosi Tuipulotu  D, Rawlinson  WD, White  PA. Recombinant GII.P16/GII.4 Sydney 2012 was the dominant norovirus identified in Australia and New Zealand in 2017. Viruses. 2018;10:548. DOIPubMedGoogle Scholar
  11. Tohma  K, Lepore  CJ, Ford-Siltz  LA, Parra  GI. Phylogenetic analyses suggest that factors other than the capsid protein play a role in the epidemic potential of GII.2 norovirus. MSphere. 2017;2:e0018717. DOIPubMedGoogle Scholar
  12. Parra  GI, Tohma  K, Ford-Siltz  LA, Eguino  P, Kendra  JA, Pilewski  KA, et al. Minimal antigenic evolution after a decade of norovirus GII.4 Sydney_2012 circulation in humans. J Virol. 2023;97:e0171622. DOIPubMedGoogle Scholar
  13. Zhu  X, He  Y, Wei  X, Kong  X, Zhang  Q, Li  J, et al. Molecular epidemiological characteristics of gastroenteritis outbreaks caused by norovirus GII.4 Sydney [P31] strains—China, October 2016–December 2020. China CDC Wkly. 2021;3:112732. DOIPubMedGoogle Scholar
  14. Ao  Y, Wang  J, Ling  H, He  Y, Dong  X, Wang  X, et al. Norovirus GII.P16/GII.2-associated gastroenteritis, China, 2016. Emerg Infect Dis. 2017;23:11725. DOIPubMedGoogle Scholar
  15. Kageyama  T, Kojima  S, Shinohara  M, Uchida  K, Fukushi  S, Hoshino  FB, et al. Broadly reactive and highly sensitive assay for Norwalk-like viruses based on real-time quantitative reverse transcription-PCR. J Clin Microbiol. 2003;41:154857. DOIPubMedGoogle Scholar

Top

Figures
Table

Top

Cite This Article

DOI: 10.3201/eid2909.230383

Original Publication Date: July 24, 2023

1These authors contributed equally to this article.

Table of Contents – Volume 29, Number 9—September 2023

EID Search Options
presentation_01 Advanced Article Search – Search articles by author and/or keyword.
presentation_01 Articles by Country Search – Search articles by the topic country.
presentation_01 Article Type Search – Search articles by article type and issue.

Top

Comments

Please use the form below to submit correspondence to the authors or contact them at the following address:

Addresses for correspondence: Jin Xu or Yuanyun Ao, Children’s Hospital of Fudan University, National Children’s Medical Center, 399 Wanyuan Rd, Min-hang District, Shanghai 201102, China

Send To

10000 character(s) remaining.

Top

Page created: June 29, 2023
Page updated: August 20, 2023
Page reviewed: August 20, 2023
The conclusions, findings, and opinions expressed by authors contributing to this journal do not necessarily reflect the official position of the U.S. Department of Health and Human Services, the Public Health Service, the Centers for Disease Control and Prevention, or the authors' affiliated institutions. Use of trade names is for identification only and does not imply endorsement by any of the groups named above.
file_external