Association Between Oral Microbiota and Cigarette Smoking in the Chinese Population

The oral microbiota has been observed to be influenced by cigarette smoking and linked to several human diseases. However, research on the effect of cigarette smoking on the oral microbiota has not been systematically conducted in the Chinese population. We profiled the oral microbiota of 316 health...

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Bibliographic Details
Published in:Frontiers in cellular and infection microbiology 2021-05, Vol.11, p.658203-658203
Main Authors: Jia, Yi-Jing, Liao, Ying, He, Yong-Qiao, Zheng, Mei-Qi, Tong, Xia-Ting, Xue, Wen-Qiong, Zhang, Jiang-Bo, Yuan, Lei-Lei, Zhang, Wen-Li, Jia, Wei-Hua
Format: Article
Language:English
Subjects:
16S rRNA gene sequencing
Cellular and Infection Microbiology
China
cigarette smoking
oral microbiota
saliva
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Summary:The oral microbiota has been observed to be influenced by cigarette smoking and linked to several human diseases. However, research on the effect of cigarette smoking on the oral microbiota has not been systematically conducted in the Chinese population. We profiled the oral microbiota of 316 healthy subjects in the Chinese population by 16S rRNA gene sequencing. The alpha diversity of oral microbiota was different between never smokers and smokers ( P = 0.002). Several bacterial taxa were first reported to be associated with cigarette smoking by LEfSe analysis, including Moryella ( q = 1.56E-04), Bulleidia ( q = 1.65E-06), and Moraxella ( q = 3.52E-02) at the genus level and Rothia dentocariosa ( q = 1.55E-02), Prevotella melaninogenica ( q = 8.48E-08), Prevotella pallens ( q = 4.13E-03), Bulleidia moorei ( q = 1.79E-06), Rothia aeria ( q = 3.83E-06), Actinobacillus parahaemolyticus ( q = 2.28E-04), and Haemophilus parainfluenzae ( q = 4.82E-02) at the species level. Two nitrite-producing bacteria that can increase the acidity of the oral cavity, Actinomyces and Veillonella , were also enriched in smokers with FDR-adjusted q -values of 3.62E-06 and 1.10E-06, respectively. Notably, we observed that two acid production-related pathways, amino acid-related enzymes ( q = 6.19E-05) and amino sugar and nucleotide sugar metabolism ( q = 2.63E-06), were increased in smokers by PICRUSt analysis. Finally, the co-occurrence analysis demonstrated that smoker-enriched bacteria were significantly positively associated with each other and were negatively correlated with the bacteria decreased in smokers. Our results suggested that cigarette smoking may affect oral health by creating a different environment by altering bacterial abundance, connections among oral microbiota, and the microbiota and their metabolic function.
ISSN:2235-2988
2235-2988
DOI:10.3389/fcimb.2021.658203