Lactobacillus helveticus-derived postbiotic and live Saccharomyces boulardii restore gut microbiota after antibiotic disturbance in an in vitro canine gut model.

IF 3.1 4区医学 Q2 MICROBIOLOGY

Beneficial microbes Pub Date : 2025-07-24 DOI:10.1163/18762891-bja00088

C Deschamps, D Humbert, M Brun, S Denis, C Durif, E Apper, S Blanquet-Diot

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引用次数: 0

Abstract

Gut microbiota plays a central role in dog health, supporting nutritional and physiological processes. However, antibiotic treatment can disturb microbiota equilibrium, leading to a perturbated state, called dysbiosis. While probiotic and postbiotic strategies are increasingly studied, their use in dogs remains poorly documented, particularly in the context of antibiotic-induced dysbiosis. In this study, we provide novel insights by evaluating for the first time, the efficacy of two microbiota restoration strategies using a canine-specific in vitro gut model (Canine Mucosal Artificial Colon, CANIM-ARCOL): the probiotic live yeast Saccharomyces boulardii CNCM I-1079 and the postbiotic heat-inactivated Lactobacillus helveticus HA-122. Both were administered at in-field doses twice a day, during and after a 5-day antibiotic treatment (metronidazole/enrofloxacin), to assess their ability to enhance microbiota resistance and/or promote recovery in both lumen and mucus-associated microbiota. Our results demonstrated that within two days post-antibiotic treatment, both interventions significantly mitigated the bloom of Enterobacteriaceae (up to -75% relative abundance, P < 0.05), accelerated the recovery of total bacterial load (increase of ∼1.5 log 10 copies/ml), and promoted a faster restoration of bacterial diversity (Shannon index returning to baseline by day 14 vs day 16 in the control). Additionally, S. boulardii significantly reduced redox potential (+200 mV with antibiotic vs only +80 mV with yeast, P < 0.0001), while L. helveticus preserved short-chain fatty acid concentrations (>100 mM vs 80 mM under control conditions) and upregulated beneficial metabolic pathways (e.g. norspermidine biosynthesis). Moreover, both treatments reduced variability in microbiota profiles and enhanced functional resilience post-antibiotic exposure. These findings provide compelling evidence supporting the relevance of probiotic and postbiotic strategies in companion animal and highlight the potential of the CANIM-ARCOL model as an ethical and robust alternative to in vivo trials for preclinical evaluation of microbiota-targeted intervention in canine nutrition and health.

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在体外犬肠道模型中，helveticus乳杆菌衍生的后生物和活的博拉氏酵母在抗生素干扰后恢复肠道微生物群。

肠道微生物群在狗的健康中起着核心作用，支持营养和生理过程。然而，抗生素治疗会扰乱微生物群的平衡，导致一种被称为生态失调的扰动状态。虽然益生菌和后生物策略的研究越来越多，但它们在狗身上的应用仍然缺乏记录，特别是在抗生素引起的生态失调的情况下。在这项研究中，我们首次利用犬类特异性体外肠道模型（犬粘膜人工结肠，CANIM-ARCOL）评估了两种微生物群恢复策略的效果，这两种策略分别是益生菌活酵母菌博氏酵母菌CNCM I-1079和生后热灭活的helveticus乳杆菌HA-122。在5天抗生素治疗（甲硝唑/恩诺沙星）期间和之后，以现场剂量每天两次给药，以评估它们增强微生物群耐药性和/或促进管腔和黏液相关微生物群恢复的能力。我们的研究结果表明，在抗生素治疗后的两天内，两种干预措施都显著减轻了肠杆菌科的开花（相对丰度高达-75%，P < 0.05），加速了细菌总负荷的恢复（增加了~ 1.5 log 10拷贝/ml），并促进了细菌多样性的更快恢复（香农指数在第14天恢复到基线，而对照组为第16天）。此外，S. boulardii显著降低了氧化还原电位（抗生素组+200 mV，酵母组仅+80 mV， P < 0.0001），而L. helveticus保留了短链脂肪酸浓度（对照条件下为100 mM， L. helveticus为80 mM），并上调了有益的代谢途径（如去亚精子胺生物合成）。此外，这两种治疗都减少了微生物群谱的变异性，增强了抗生素暴露后的功能恢复能力。这些发现提供了令人信服的证据，支持益生菌和后生物策略在伴侣动物中的相关性，并强调了CANIM-ARCOL模型作为临床前评估微生物群靶向干预犬营养和健康的体内试验的伦理和强大替代方案的潜力。

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来源期刊

Beneficial microbes MICROBIOLOGY-NUTRITION & DIETETICS

CiteScore

7.90

自引率

1.90%

发文量

审稿时长

>12 weeks

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