Bacillus subtilis DE111 partially reverses endothelial dysfunction in western-diet fed mice.

Benef Microbes

Department of Food Science and Human Nutrition, 3447Colorado State University, Fort Collins, CO 80523-1571, USA.

Published: December 2024

AI Article Synopsis

  • - Imbalances in gut microbiome can lead to endothelial dysfunction, a risk factor for cardiovascular disease, prompting the exploration of microbiome-targeting interventions like Bacillus subtilis DE111.
  • - In a study involving obese mice, B. subtilis DE111 improved endothelial function after eight weeks of treatment, despite no major changes in gut health or metabolic parameters.
  • - Analysis of gut microbiota showed significant differences between mice on a Western diet and those on a standard diet, indicating that while B. subtilis DE111 improved some endothelial dysfunction, the exact mechanisms remain unclear.

Article Abstract

Imbalances in the gut microbiome have emerged as an important factor in endothelial dysfunction, a significant risk factor for cardiovascular disease. Thus, interventions targeting the microbiome may prove helpful in preventing or reversing this impairment. We previously reported that spore-forming Bacillus subtilis DE111 improved endothelial function in a cohort of healthy, non-obese humans after a four-week intervention. Building on these promising results, the present study sought to investigate whether administering B. subtilis DE111 could reverse endothelial dysfunction in mice with diet-induced obesity. Male C57BL/6J mice were fed a Western diet (WD; n = 24) or standard diet (SD; n = 24) for ten weeks to induce endothelial dysfunction, after which half of the animals in each group (n = 12) were allocated to receive B. subtilis DE111 (hereafter, PB) formulated into the diet for an additional eight weeks. Outcomes included endothelial-dependent arterial dilation, glucose tolerance, body weight changes, microbiota profiles, and assessments of intestinal permeability and mucosal immunity markers. Furthermore, a cell culture model of gut barrier function was used to assess the effects of PB on gut barrier integrity. PB treatment significantly attenuated WD-induced mesenteric endothelial-dependent arterial dilation, independent of changes in other cardiometabolic parameters or changes in gut barrier function. In vitro trans-epithelial electrical resistance of the Caco-2 cell culture confirmed that neither PB-conditioned media nor faecal waters from B. subtilis-treated human stool resulted in gut barrier improvements, nor did they protect against inflammation-associated barrier disruptions. Unsurprisingly, microbiota analysis revealed significant differences in Shannon's alpha diversity of WD-fed animals compared to SD. These data suggest that PB consumption significantly attenuated WD diet-induced endothelial dysfunction; however, the underlying mechanisms of this protection were not determined. Improvement in endothelial function was independent of PB-mediated changes to body weight or gut barrier function. Further studies should explore B. subtilis-mediated immune responses or metabolite production as mechanisms underlying these endothelial protective effects.

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Source
http://dx.doi.org/10.1163/18762891-bja00052DOI Listing

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