Maria Elena Martino, Martin Schwarzer, Pauline Joncour, Hugo Gervais, Stéphanie Geoffroy, Benjamin Gillet, Sandrine Hughes, François Leulier
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引用次数: 0
Abstract
The gut microbiota has a profound impact on animal physiology, improving organ function and promoting growth under different nutritional conditions. Complex mechanisms underlying growth-promotion by the gut microbiota have been described. In particular, strains of the same bacterial species within different genera exhibit strain-specific growth promotion. In a previous study, we used artificial selection on a poorly growth-promoting strain of Lactiplantibacillus plantarum (NIZO2877) and isolated evolved strains with enhanced growth-promoting capabilities in insects. However, it remains unclear to what extent existing growth-promoting strains can further optimise their benefits and whether these effects persist in well-fed mammals. Here, we experimentally evolved a Drosophila growth-promoting strain of L. plantarum (WJL) under conditions of nutrient deprivation. This strain had not undergone any prior evolutionary adaptation. Our aim was to maximize its growth-promoting benefits while evaluating the translation of this phenotype in different animal models. After artificial selection across ten Drosophila generations, we identified an evolved strain (L. plantarum IGFL1) that significantly improved Drosophila juvenile growth compared to the ancestral strain. Administration of IGFL1 to conventional C57Bl/6j male mice under both nutrient deprivation and normal dietary conditions significantly increased body length and weight growth rates compared to placebo-fed animals. These effects were comparable to those of the ancestral strain, suggesting a context-dependent phenotype. Genome sequencing of IGFL1 revealed the presence of four mutations that may be related to more effective utilization of nutrients. Our results demonstrate the high adaptive potential of L. plantarum, although functional improvements in promoting animal growth are strictly context-dependent. Despite this specificity in adaptation, both strains (the ancestral WJL and the evolved IGFL1) show transferable potential in terms of animal growth promotion, as they are both highly beneficial in flies and mice. These results pave the way for testing these strains to enhance the growth performance of agricultural target species.
肠道菌群在不同营养条件下对动物生理、改善器官功能和促进生长具有深远的影响。肠道菌群促进生长的复杂机制已经被描述。特别是,不同属内同一菌种的菌株表现出菌株特异性生长促进作用。在之前的研究中,我们对植物乳杆菌(Lactiplantibacillus plantarum, NIZO2877)的促生长能力较差的菌株进行了人工选择,并在昆虫中分离出促生长能力较强的进化菌株。然而,目前尚不清楚现有的促生长菌株能在多大程度上进一步优化它们的益处,以及这些影响是否会在营养充足的哺乳动物中持续存在。在营养匮乏的条件下,我们实验进化出了一株促进果蝇生长的L. plantarum (WJL)菌株。这个菌株没有经历过任何先前的进化适应。我们的目的是最大化其促进生长的益处,同时评估该表型在不同动物模型中的翻译。经过十代果蝇的人工选择,我们发现了一个进化菌株(L. plantarum IGFL1),与祖先菌株相比,它显著改善了果蝇幼体的生长。在营养剥夺和正常饮食条件下,对常规C57Bl/6j雄性小鼠给予IGFL1,与安慰剂喂养的动物相比,显著增加了体长和体重的生长率。这些影响与祖先菌株相当,表明环境依赖表型。IGFL1的基因组测序显示存在四个突变,可能与更有效地利用营养物质有关。虽然植物乳杆菌促进动物生长的功能改善严格依赖于环境,但我们的研究结果表明植物乳杆菌具有很高的适应潜力。尽管具有这种适应性特异性,但这两种菌株(祖先WJL和进化后的IGFL1)在促进动物生长方面显示出可转移的潜力,因为它们对果蝇和小鼠都非常有益。这些结果为测试这些菌株以提高农业目标物种的生长性能铺平了道路。
期刊介绍:
Beneficial Microbes is a peer-reviewed scientific journal with a specific area of focus: the promotion of the science of microbes beneficial to the health and wellbeing of man and animal. The journal contains original research papers and critical reviews in all areas dealing with beneficial microbes in both the small and large intestine, together with opinions, a calendar of forthcoming beneficial microbes-related events and book reviews. The journal takes a multidisciplinary approach and focuses on a broad spectrum of issues, including safety aspects of pro- & prebiotics, regulatory aspects, mechanisms of action, health benefits for the host, optimal production processes, screening methods, (meta)genomics, proteomics and metabolomics, host and bacterial physiology, application, and role in health and disease in man and animal. Beneficial Microbes is intended to serve the needs of researchers and professionals from the scientific community and industry, as well as those of policy makers and regulators.
The journal will have five major sections:
* Food, nutrition and health
* Animal nutrition
* Processing and application
* Regulatory & safety aspects
* Medical & health applications
In these sections, topics dealt with by Beneficial Microbes include:
* Worldwide safety and regulatory issues
* Human and animal nutrition and health effects
* Latest discoveries in mechanistic studies and screening methods to unravel mode of action
* Host physiology related to allergy, inflammation, obesity, etc.
* Trends in application of (meta)genomics, proteomics and metabolomics
* New developments in how processing optimizes pro- & prebiotics for application
* Bacterial physiology related to health benefits
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