The Caries and Caries-Free Archaeome

IF 5.7 1区医学 Q1 DENTISTRY, ORAL SURGERY & MEDICINE

Journal of Dental Research Pub Date : 2025-04-21 DOI:10.1177/00220345251329343

N. Dame-Teixeira, J. Lynch, X. Yu, J.A. Cena, T. Do

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Abstract

The difficulty of establishing a relationship between archaea and oral diseases such as dental caries stems from the challenges of detecting, identifying, and isolating these microorganisms. This study aimed to detect archaea in publicly available datasets comprising caries and caries-free saliva and dental plaque by using a tailored bioinformatic pipeline for shotgun sequencing analysis. A systematic search was performed to identify studies using shotgun metagenomics or metatranscriptomics on samples obtained from individuals with dental caries. Two reviewers selected studies based on eligibility criteria. Sequencing and metadata from each study were retrieved from the SRA Bioproject. A count table was generated for each database by mapping reads against an archaea genome database, specifically tailored for this study, using stringent filtering parameters of greater than 97% similarity and 90% query coverage. Archaeal prevalence was determined using an arbitrary cutoff point (>500 reads). An effect size meta-analysis was performed to determine the overall prevalence. Phyloseq and DESeq2 packages were used to determine alpha and beta diversities, differential abundance in different taxonomic levels, and differential expression comparing caries and caries-free samples. Spearman correlation was performed with the bacteriome. The search yielded 154 titles, from which a collection of 7 datasets from 8 studies was obtained. Of 397 samples, N = 63 were positive for archaea using postfiltering, comprising a putative prevalence of 20% (confidence interval = 0%–40%) and identifying Euryarchaeota , Thermoplasmatota , and Nitrosphaeria . Methanogens were present in both the caries and caries-free groups ( Methanobrevibacter spp., Methanosarcina , and Methanosphaera ) and positively correlated with Stenotrophomonas , Streptococcus , Actinomyces , Abiotrophia , Gemella , and Corynebacterium . Several methanogenesis genes, including methyl-coenzyme M reductase, which catalyzes the final step of methane production in methanogens, were underexpressed in caries-active samples compared with caries-free samples. Saliva and dental plaque emerged as sites of low-abundance archaea, with methanogenesis genes underexpressed in caries-active samples.

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龋齿和无龋齿古生菌群

建立古细菌与龋齿等口腔疾病之间关系的困难源于检测、鉴定和分离这些微生物的挑战。本研究旨在通过使用定制的生物信息学管道进行鸟枪测序分析，在包括龋齿和无龋齿唾液和牙菌斑的公开数据集中检测古细菌。进行了系统搜索，以确定使用散弹枪宏基因组学或元转录组学对龋齿个体样本进行的研究。两位审稿人根据资格标准选择研究。每项研究的测序和元数据均从SRA Bioproject检索。通过对古细菌基因组数据库进行比对，为每个数据库生成一个计数表，该数据库是专门为本研究量身定制的，使用严格的过滤参数，相似性大于97%，查询覆盖率大于90%。使用任意截断点（>500 reads）确定古菌流行率。进行效应大小荟萃分析以确定总体患病率。使用Phyloseq和DESeq2包测定α和β多样性，不同分类水平的差异丰度，以及龋和无龋样品的差异表达。与细菌组进行Spearman相关性分析。检索得到154个标题，从中获得来自8项研究的7个数据集。在397份样品中，经后过滤，N = 63份古细菌呈阳性，推定流行率为20%（置信区间为0%-40%），鉴定出Euryarchaeota、Thermoplasmatota和Nitrosphaeria。产甲烷菌存在于龋齿组和无龋齿组（methanobrebacter spp.、Methanosarcina和Methanosphaera），与窄养单胞菌、链球菌、放线菌、无营养菌、Gemella和棒状杆菌呈正相关。几个产甲烷基因，包括甲基辅酶M还原酶，在产甲烷菌中催化甲烷产生的最后一步，与无龋齿的样品相比，在龋齿活跃的样品中表达不足。唾液和牙菌斑是低丰度古细菌的聚集地，在龋齿活性样本中，产甲烷基因表达不足。

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来源期刊

Journal of Dental Research 医学-牙科与口腔外科

CiteScore

15.30

自引率

3.90%

发文量

155

审稿时长

3-8 weeks

期刊介绍： The Journal of Dental Research (JDR) is a peer-reviewed scientific journal committed to sharing new knowledge and information on all sciences related to dentistry and the oral cavity, covering health and disease. With monthly publications, JDR ensures timely communication of the latest research to the oral and dental community.