Convergent reductive evolution in bee-associated lactic acid bacteria.

IF 3.9 2区 生物学 Q2 BIOTECHNOLOGY & APPLIED MICROBIOLOGY Applied and Environmental Microbiology Pub Date : 2024-11-20 Epub Date: 2024-10-23 DOI:10.1128/aem.01257-24
Ana Pontes, Marie-Claire Harrison, Antonis Rokas, Carla Gonçalves
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Abstract

Distantly related organisms may evolve similar traits when exposed to similar environments or engaging in certain lifestyles. Several members of the Lactobacillaceae [lactic acid bacteria (LAB)] family are frequently isolated from the floral niche, mostly from bees and flowers. In some floral LAB species (henceforth referred to as bee-associated LAB), distinctive genomic (e.g., genome reduction) and phenotypic (e.g., preference for fructose over glucose or fructophily) features were recently documented. These features are found across distantly related species, raising the hypothesis that specific genomic and phenotypic traits evolved convergently during adaptation to the floral environment. To test this hypothesis, we examined representative genomes of 369 species of bee-associated and non-bee-associated LAB. Phylogenomic analysis unveiled seven independent ecological shifts toward the bee environment in LAB. In these species, we observed significant reductions of genome size, gene repertoire, and GC content. Using machine leaning, we could distinguish bee-associated from non-bee-associated species with 94% accuracy, based on the absence of genes involved in metabolism, osmotic stress, or DNA repair. Moreover, we found that the most important genes for the machine learning classifier were seemingly lost, independently, in multiple bee-associated lineages. One of these genes, acetaldehyde-alcohol dehydrogenase (adhE), encodes a bifunctional aldehyde-alcohol dehydrogenase which has been associated with the evolution of fructophily, a rare phenotypic trait that is pervasive across bee-associated LAB species. These results suggest that the independent evolution of distinctive phenotypes in bee-associated LAB has been largely driven by independent losses of the same sets of genes.IMPORTANCESeveral LAB species are intimately associated with bees and exhibit unique biochemical properties with potential for food applications and honeybee health. Using a machine learning-based approach, our study shows that adaptation of LAB to the bee environment was accompanied by a distinctive genomic trajectory deeply shaped by gene loss. Several of these gene losses occurred independently in distantly related species and are linked to some of their unique biotechnologically relevant traits, such as the preference for fructose over glucose (fructophily). This study underscores the potential of machine learning in identifying fingerprints of adaptation and detecting instances of convergent evolution. Furthermore, it sheds light onto the genomic and phenotypic particularities of bee-associated bacteria, thereby deepening the understanding of their positive impact on honeybee health.

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蜜蜂相关乳酸菌的趋同还原进化
亲缘关系较远的生物在暴露于相似的环境或从事某种生活方式时,可能会进化出相似的性状。乳酸菌(LAB)]家族的一些成员经常从花卉生态位中分离出来,其中大部分来自蜜蜂和花卉。在一些花卉 LAB 物种(以下称为蜜蜂相关 LAB)中,最近记录了独特的基因组(如基因组减少)和表型(如偏好果糖而非葡萄糖或嗜果糖)特征。这些特征在亲缘关系较远的物种中均有发现,这就提出了一个假设,即特定的基因组和表型特征是在适应花环境的过程中趋同进化而来的。为了验证这一假设,我们研究了 369 种蜜蜂相关和非蜜蜂相关 LAB 的代表性基因组。系统发生组分析揭示了酵母菌向蜜蜂环境的七次独立生态转变。在这些物种中,我们观察到基因组大小、基因剧目和 GC 含量的显著减少。通过机器精益分析,我们可以根据新陈代谢、渗透压或 DNA 修复相关基因的缺失情况,以 94% 的准确率区分与蜜蜂相关和非蜜蜂相关的物种。此外,我们还发现,对机器学习分类器来说最重要的基因似乎在多个蜜蜂相关种系中独立丢失。其中一个基因乙醛醇脱氢酶(adhE)编码一种双功能醛醇脱氢酶,它与嗜果性的进化有关,而嗜果性是一种罕见的表型特征,在与蜜蜂相关的 LAB 物种中普遍存在。这些结果表明,蜜蜂相关酵母菌独特表型的独立进化在很大程度上是由同组基因的独立损失所驱动的。重要意义一些酵母菌物种与蜜蜂密切相关,并表现出独特的生化特性,具有食品应用和蜜蜂健康的潜力。利用基于机器学习的方法,我们的研究表明,LAB 对蜜蜂环境的适应伴随着基因缺失而形成的独特的基因组轨迹。这些基因缺失中有几个是在远缘物种中独立发生的,并与它们的一些独特的生物技术相关性状有关,如对果糖的偏好超过了对葡萄糖的偏好(嗜果性)。这项研究强调了机器学习在识别适应性指纹和检测趋同进化实例方面的潜力。此外,它还揭示了蜜蜂相关细菌的基因组和表型特征,从而加深了人们对其对蜜蜂健康的积极影响的理解。
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来源期刊
Applied and Environmental Microbiology
Applied and Environmental Microbiology 生物-生物工程与应用微生物
CiteScore
7.70
自引率
2.30%
发文量
730
审稿时长
1.9 months
期刊介绍: Applied and Environmental Microbiology (AEM) publishes papers that make significant contributions to (a) applied microbiology, including biotechnology, protein engineering, bioremediation, and food microbiology, (b) microbial ecology, including environmental, organismic, and genomic microbiology, and (c) interdisciplinary microbiology, including invertebrate microbiology, plant microbiology, aquatic microbiology, and geomicrobiology.
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