Detection of human noroviruses in sewage by next generation sequencing in Shandong Province, 2019–2021
Human noroviruses are the major cause of acute gastroenteritis and exhibit considerable genetic diversity. Next generation sequencing (NGS) analysis based on environmental surveillance has been proved to be an effective method in norovirus surveillance. Between January 2019 and December 2021, 36 sew...
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| Published in | Virology journal Vol. 22; no. 1; p. 18 |
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27.01.2025
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| Abstract | Human noroviruses are the major cause of acute gastroenteritis and exhibit considerable genetic diversity. Next generation sequencing (NGS) analysis based on environmental surveillance has been proved to be an effective method in norovirus surveillance.
Between January 2019 and December 2021, 36 sewage samples were collected and analyzed using real-time quantitative PCR to detect noroviruses. Partial VP1 region was amplified and subjected to NGS analysis to assess the abundance and genetic characterization of various norovirus genotypes across different samples.
A total of 23 norovirus genotypes were identified, including 9 genotypes of GI, 13 genotypes of GII and 1 genotype of GIX. The most frequently detected genotypes were GI.5 (86.11%), GII.2 (86.11%), GII.4 (63.89%), GII.17 (58.33%), and GII.13 (55.56%). Additionally, some rare genotypes, such as GI.7, GII.5, GII.9, and GII.16, which had not been previously reported in Shandong, were identified. No significant differences were observed in genotypic diversity or viral copy numbers in sewage samples when comparing pre- and post-COVID-19 periods. A total of 379 partial VP1 sequences were obtained, with the means sequence identity within a genotype of Shandong sequences ranging from 92.69 to 98.37% and a coefficient of variation ranging from 1.46 to 6.73%. Phylogenetic analysis indicated that local noroviruses within each genotype comprised multiple co-circulating lineages.
Our data demonstrate that sewage contains noroviruses with considerable high diversities. NGS based environmental surveillance greatly improves the understanding of norovirus circulation and should be encouraged. |
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| AbstractList | Abstract Background Human noroviruses are the major cause of acute gastroenteritis and exhibit considerable genetic diversity. Next generation sequencing (NGS) analysis based on environmental surveillance has been proved to be an effective method in norovirus surveillance. Methods Between January 2019 and December 2021, 36 sewage samples were collected and analyzed using real-time quantitative PCR to detect noroviruses. Partial VP1 region was amplified and subjected to NGS analysis to assess the abundance and genetic characterization of various norovirus genotypes across different samples. Results A total of 23 norovirus genotypes were identified, including 9 genotypes of GI, 13 genotypes of GII and 1 genotype of GIX. The most frequently detected genotypes were GI.5 (86.11%), GII.2 (86.11%), GII.4 (63.89%), GII.17 (58.33%), and GII.13 (55.56%). Additionally, some rare genotypes, such as GI.7, GII.5, GII.9, and GII.16, which had not been previously reported in Shandong, were identified. No significant differences were observed in genotypic diversity or viral copy numbers in sewage samples when comparing pre- and post-COVID-19 periods. A total of 379 partial VP1 sequences were obtained, with the means sequence identity within a genotype of Shandong sequences ranging from 92.69 to 98.37% and a coefficient of variation ranging from 1.46 to 6.73%. Phylogenetic analysis indicated that local noroviruses within each genotype comprised multiple co-circulating lineages. Conclusions Our data demonstrate that sewage contains noroviruses with considerable high diversities. NGS based environmental surveillance greatly improves the understanding of norovirus circulation and should be encouraged. Human noroviruses are the major cause of acute gastroenteritis and exhibit considerable genetic diversity. Next generation sequencing (NGS) analysis based on environmental surveillance has been proved to be an effective method in norovirus surveillance.BACKGROUNDHuman noroviruses are the major cause of acute gastroenteritis and exhibit considerable genetic diversity. Next generation sequencing (NGS) analysis based on environmental surveillance has been proved to be an effective method in norovirus surveillance.Between January 2019 and December 2021, 36 sewage samples were collected and analyzed using real-time quantitative PCR to detect noroviruses. Partial VP1 region was amplified and subjected to NGS analysis to assess the abundance and genetic characterization of various norovirus genotypes across different samples.METHODSBetween January 2019 and December 2021, 36 sewage samples were collected and analyzed using real-time quantitative PCR to detect noroviruses. Partial VP1 region was amplified and subjected to NGS analysis to assess the abundance and genetic characterization of various norovirus genotypes across different samples.A total of 23 norovirus genotypes were identified, including 9 genotypes of GI, 13 genotypes of GII and 1 genotype of GIX. The most frequently detected genotypes were GI.5 (86.11%), GII.2 (86.11%), GII.4 (63.89%), GII.17 (58.33%), and GII.13 (55.56%). Additionally, some rare genotypes, such as GI.7, GII.5, GII.9, and GII.16, which had not been previously reported in Shandong, were identified. No significant differences were observed in genotypic diversity or viral copy numbers in sewage samples when comparing pre- and post-COVID-19 periods. A total of 379 partial VP1 sequences were obtained, with the means sequence identity within a genotype of Shandong sequences ranging from 92.69 to 98.37% and a coefficient of variation ranging from 1.46 to 6.73%. Phylogenetic analysis indicated that local noroviruses within each genotype comprised multiple co-circulating lineages.RESULTSA total of 23 norovirus genotypes were identified, including 9 genotypes of GI, 13 genotypes of GII and 1 genotype of GIX. The most frequently detected genotypes were GI.5 (86.11%), GII.2 (86.11%), GII.4 (63.89%), GII.17 (58.33%), and GII.13 (55.56%). Additionally, some rare genotypes, such as GI.7, GII.5, GII.9, and GII.16, which had not been previously reported in Shandong, were identified. No significant differences were observed in genotypic diversity or viral copy numbers in sewage samples when comparing pre- and post-COVID-19 periods. A total of 379 partial VP1 sequences were obtained, with the means sequence identity within a genotype of Shandong sequences ranging from 92.69 to 98.37% and a coefficient of variation ranging from 1.46 to 6.73%. Phylogenetic analysis indicated that local noroviruses within each genotype comprised multiple co-circulating lineages.Our data demonstrate that sewage contains noroviruses with considerable high diversities. NGS based environmental surveillance greatly improves the understanding of norovirus circulation and should be encouraged.CONCLUSIONSOur data demonstrate that sewage contains noroviruses with considerable high diversities. NGS based environmental surveillance greatly improves the understanding of norovirus circulation and should be encouraged. BACKGROUND: Human noroviruses are the major cause of acute gastroenteritis and exhibit considerable genetic diversity. Next generation sequencing (NGS) analysis based on environmental surveillance has been proved to be an effective method in norovirus surveillance. METHODS: Between January 2019 and December 2021, 36 sewage samples were collected and analyzed using real-time quantitative PCR to detect noroviruses. Partial VP1 region was amplified and subjected to NGS analysis to assess the abundance and genetic characterization of various norovirus genotypes across different samples. RESULTS: A total of 23 norovirus genotypes were identified, including 9 genotypes of GI, 13 genotypes of GII and 1 genotype of GIX. The most frequently detected genotypes were GI.5 (86.11%), GII.2 (86.11%), GII.4 (63.89%), GII.17 (58.33%), and GII.13 (55.56%). Additionally, some rare genotypes, such as GI.7, GII.5, GII.9, and GII.16, which had not been previously reported in Shandong, were identified. No significant differences were observed in genotypic diversity or viral copy numbers in sewage samples when comparing pre- and post-COVID-19 periods. A total of 379 partial VP1 sequences were obtained, with the means sequence identity within a genotype of Shandong sequences ranging from 92.69 to 98.37% and a coefficient of variation ranging from 1.46 to 6.73%. Phylogenetic analysis indicated that local noroviruses within each genotype comprised multiple co-circulating lineages. CONCLUSIONS: Our data demonstrate that sewage contains noroviruses with considerable high diversities. NGS based environmental surveillance greatly improves the understanding of norovirus circulation and should be encouraged. Human noroviruses are the major cause of acute gastroenteritis and exhibit considerable genetic diversity. Next generation sequencing (NGS) analysis based on environmental surveillance has been proved to be an effective method in norovirus surveillance. Between January 2019 and December 2021, 36 sewage samples were collected and analyzed using real-time quantitative PCR to detect noroviruses. Partial VP1 region was amplified and subjected to NGS analysis to assess the abundance and genetic characterization of various norovirus genotypes across different samples. A total of 23 norovirus genotypes were identified, including 9 genotypes of GI, 13 genotypes of GII and 1 genotype of GIX. The most frequently detected genotypes were GI.5 (86.11%), GII.2 (86.11%), GII.4 (63.89%), GII.17 (58.33%), and GII.13 (55.56%). Additionally, some rare genotypes, such as GI.7, GII.5, GII.9, and GII.16, which had not been previously reported in Shandong, were identified. No significant differences were observed in genotypic diversity or viral copy numbers in sewage samples when comparing pre- and post-COVID-19 periods. A total of 379 partial VP1 sequences were obtained, with the means sequence identity within a genotype of Shandong sequences ranging from 92.69 to 98.37% and a coefficient of variation ranging from 1.46 to 6.73%. Phylogenetic analysis indicated that local noroviruses within each genotype comprised multiple co-circulating lineages. Our data demonstrate that sewage contains noroviruses with considerable high diversities. NGS based environmental surveillance greatly improves the understanding of norovirus circulation and should be encouraged. Human noroviruses are the major cause of acute gastroenteritis and exhibit considerable genetic diversity. Next generation sequencing (NGS) analysis based on environmental surveillance has been proved to be an effective method in norovirus surveillance. Between January 2019 and December 2021, 36 sewage samples were collected and analyzed using real-time quantitative PCR to detect noroviruses. Partial VP1 region was amplified and subjected to NGS analysis to assess the abundance and genetic characterization of various norovirus genotypes across different samples. A total of 23 norovirus genotypes were identified, including 9 genotypes of GI, 13 genotypes of GII and 1 genotype of GIX. The most frequently detected genotypes were GI.5 (86.11%), GII.2 (86.11%), GII.4 (63.89%), GII.17 (58.33%), and GII.13 (55.56%). Additionally, some rare genotypes, such as GI.7, GII.5, GII.9, and GII.16, which had not been previously reported in Shandong, were identified. No significant differences were observed in genotypic diversity or viral copy numbers in sewage samples when comparing pre- and post-COVID-19 periods. A total of 379 partial VP1 sequences were obtained, with the means sequence identity within a genotype of Shandong sequences ranging from 92.69 to 98.37% and a coefficient of variation ranging from 1.46 to 6.73%. Phylogenetic analysis indicated that local noroviruses within each genotype comprised multiple co-circulating lineages. Our data demonstrate that sewage contains noroviruses with considerable high diversities. NGS based environmental surveillance greatly improves the understanding of norovirus circulation and should be encouraged. Background Human noroviruses are the major cause of acute gastroenteritis and exhibit considerable genetic diversity. Next generation sequencing (NGS) analysis based on environmental surveillance has been proved to be an effective method in norovirus surveillance. Methods Between January 2019 and December 2021, 36 sewage samples were collected and analyzed using real-time quantitative PCR to detect noroviruses. Partial VP1 region was amplified and subjected to NGS analysis to assess the abundance and genetic characterization of various norovirus genotypes across different samples. Results A total of 23 norovirus genotypes were identified, including 9 genotypes of GI, 13 genotypes of GII and 1 genotype of GIX. The most frequently detected genotypes were GI.5 (86.11%), GII.2 (86.11%), GII.4 (63.89%), GII.17 (58.33%), and GII.13 (55.56%). Additionally, some rare genotypes, such as GI.7, GII.5, GII.9, and GII.16, which had not been previously reported in Shandong, were identified. No significant differences were observed in genotypic diversity or viral copy numbers in sewage samples when comparing pre- and post-COVID-19 periods. A total of 379 partial VP1 sequences were obtained, with the means sequence identity within a genotype of Shandong sequences ranging from 92.69 to 98.37% and a coefficient of variation ranging from 1.46 to 6.73%. Phylogenetic analysis indicated that local noroviruses within each genotype comprised multiple co-circulating lineages. Conclusions Our data demonstrate that sewage contains noroviruses with considerable high diversities. NGS based environmental surveillance greatly improves the understanding of norovirus circulation and should be encouraged. Keywords: Noroviruses, Sewage, Next generation sequencing (NGS), Diversity |
| ArticleNumber | 18 |
| Audience | Academic |
| Author | Liu, Yao Lin, Xiaojuan Wang, Suting Chen, Meng Tao, Zexin Xu, Mingyi Xiong, Ping Ji, Shengxiang Xu, Aiqiang |
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| BackLink | https://www.ncbi.nlm.nih.gov/pubmed/39871378$$D View this record in MEDLINE/PubMed |
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| Keywords | Next generation sequencing (NGS) Sewage Noroviruses Diversity |
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| Snippet | Human noroviruses are the major cause of acute gastroenteritis and exhibit considerable genetic diversity. Next generation sequencing (NGS) analysis based on... Background Human noroviruses are the major cause of acute gastroenteritis and exhibit considerable genetic diversity. Next generation sequencing (NGS) analysis... BACKGROUND: Human noroviruses are the major cause of acute gastroenteritis and exhibit considerable genetic diversity. Next generation sequencing (NGS)... Abstract Background Human noroviruses are the major cause of acute gastroenteritis and exhibit considerable genetic diversity. Next generation sequencing (NGS)... |
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| SubjectTerms | Caliciviridae Infections - epidemiology Caliciviridae Infections - virology Causes of China China - epidemiology COVID-19 - epidemiology COVID-19 - virology Distribution Diversity DNA sequencing environmental monitoring Gastroenteritis Gastroenteritis - epidemiology Gastroenteritis - virology Genetic aspects Genetic Variation Genotype Health aspects High-Throughput Nucleotide Sequencing Humans Identification and classification Next generation sequencing (NGS) Norovirus Norovirus - classification Norovirus - genetics Norovirus - isolation & purification Noroviruses Nucleotide sequencing Phylogeny quantitative polymerase chain reaction RNA, Viral - genetics sequence analysis Sewage Sewage - virology |
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| Title | Detection of human noroviruses in sewage by next generation sequencing in Shandong Province, 2019–2021 |
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