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严重幼儿早期龋中牙菌斑的碳源利用模式及微生物对蔗糖、乳糖和苯丙氨酸消耗的反应

Carbon source utilization patterns in dental plaque and microbial responses to sucrose, lactose, and phenylalanine consumption in severe early childhood caries.

作者信息

Shi Weihua, Tian Jing, Xu He, Wang Guiyan, Zhou Qiong, Qin Man

机构信息

Department of Pediatric Dentistry, Peking University School and Hospital of Stomatology, Beijing, China.

出版信息

J Oral Microbiol. 2020 Jun 23;12(1):1782696. doi: 10.1080/20002297.2020.1782696.

DOI:10.1080/20002297.2020.1782696
PMID:32944149
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC7482870/
Abstract

BACKGROUND

Severe early childhood caries (S-ECC) is mainly caused by the interaction of microbiota and environmental factors. However, the metabolic profiles of S-ECC microbial communities and the community-level microbial responses to carbohydrates and amino acids are poorly understood.

METHODS

We collected supragingival plaques from 15 caries-free (CF) and 14 S-ECC children. Cultivation on Biolog AN microplates together with next-generation sequencing was used to analyze sole carbon source utilization patterns and microbial responses to sucrose, lactose and phenylalanine.

RESULTS

S-ECC plaques had greater overall metabolic activity than those of CF ones. Comparing with CF, S-ECC plaques utilized more sucrose and lactose but less phenylalanine and then had greater response to carbohydrates. A remarkable increase of non-mutans Streptococci was observed in sucrose and lactose consumption. Lactose led to less differently distributed taxa than sucrose in both CF and S-ECC groups. Sucrose made the originally different S-ECC and CF communities eventually became similar to each other, but they remained dissimilar in lactose.

CONCLUSION

S-ECC plaques had more active interaction with cariogenic carbohydrates like sucrose and lactose than healthy plaques. We supported lactose has less cariogenicity compared with sucrose from microbial community structural aspect. Phenylalanine may have a potentially inhibitory effect on caries development.

摘要

背景

重度幼儿龋齿(S-ECC)主要由微生物群与环境因素的相互作用引起。然而,人们对S-ECC微生物群落的代谢谱以及群落水平上微生物对碳水化合物和氨基酸的反应了解甚少。

方法

我们从15名无龋(CF)儿童和14名S-ECC儿童中收集龈上菌斑。使用Biolog AN微孔板培养并结合下一代测序来分析单一碳源利用模式以及微生物对蔗糖、乳糖和苯丙氨酸的反应。

结果

S-ECC菌斑的总体代谢活性高于CF菌斑。与CF相比,S-ECC菌斑利用更多的蔗糖和乳糖,但利用的苯丙氨酸较少,因此对碳水化合物的反应更大。在蔗糖和乳糖消耗过程中观察到非变形链球菌显著增加。在CF组和S-ECC组中,乳糖导致的分类群分布差异均小于蔗糖。蔗糖使原本不同的S-ECC和CF群落最终变得彼此相似,但在乳糖环境下它们仍然不同。

结论

与健康菌斑相比,S-ECC菌斑与蔗糖和乳糖等致龋碳水化合物的相互作用更活跃。从微生物群落结构方面来看,我们支持乳糖的致龋性低于蔗糖。苯丙氨酸可能对龋齿发展具有潜在的抑制作用。

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Int J Oral Sci. 2017 Dec;9(12):e6. doi: 10.1038/ijos.2017.47. Epub 2017 Dec 20.
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