Evany Dinakis scite author profile

Gut microbiota-derived metabolites, such as short-chain fatty acids (SCFAs) have vasodilator properties in animal and human ex vivo arteries. However, the role of the gut microbiota and SCFAs in arterial stiffness in humans is still unclear. Here we aimed to determine associations between the gut microbiome, SCFA and their G-protein coupled sensing receptors (GPCRs) in relation to human arterial stiffness. MethodsAmbulatory arterial stiffness index (AASI) was determined from ambulatory blood pressure (BP) monitoring in 69 participants from regional and metropolitan regions in Australia (55.1% women; mean, 59.86 SD, 7.26 years of age). The gut microbiome was determined by 16S rRNA sequencing, SCFA levels by gas chromatography, and GPCR expression in circulating immune cells by real-time PCR. ResultsThere was no association between metrics of bacterial a and b diversity and AASI or AASI quartiles in men and women. We identified two main bacteria taxa that were associated with AASI quartiles: Lactobacillus spp. was only present in the lowest quartile, while Clostridium spp. was present in all quartiles but the lowest. AASI was positively associated with higher levels of plasma, but not faecal, butyrate. Finally, we identified that the expression of GPR43 (FFAR2) and GPR41 (FFAR3) in circulating immune cells were negatively associated with AASI. ConclusionsOur results suggest that arterial stiffness is associated with lower levels of the metabolite-sensing receptors GPR41/GPR43 in humans, blunting its response to BP-lowering metabolites such as butyrate. The role of Lactobacillus spp. and Clostridium spp., as well as butyrate-sensing receptors GPR41/GPR43, in human arterial stiffness needs to be determined.

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Association Between the Gut Microbiome and Their Metabolites With Human Blood Pressure Variability

Dinakis

Nakai

Gill

et al. 2022

Hypertension

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Background: Blood pressure (BP) variability is an independent risk factor for cardiovascular events. Recent evidence supports a role for the gut microbiota in BP regulation. However, whether the gut microbiome is associated with BP variability is yet to be determined. Here, we aimed to investigate the interplay between the gut microbiome and their metabolites in relation to BP variability. Methods: Ambulatory BP monitoring was performed in 69 participants from Australia (55.1% women; mean±SD, 59.8±7.26 years; body mass index, 25.2±2.83 kg/m 2 ). These data were used to determine nighttime dipping, morning BP surge (MBPS) and BP variability as SD. The gut microbiome was determined by 16S ribosomal RNA (rRNA) sequencing and metabolite levels by gas chromatography. Results: We identified specific taxa associated with systolic BP variability, nighttime dipping, and MBPS. Notably, Alistipesfinegoldii and Lactobacillus spp. were only present in participants within the normal ranges of BP variability, MBPS and dipping, while Prevotella spp. and Clostridium spp., were found to be present in extreme dippers and the highest quartiles of BP SD and MBPS. There was a negative association between MBPS and microbial α-diversity (r=−0.244, P =0.046). MBPS was also negatively associated with plasma levels of microbial metabolites called short-chain fatty acids (r=−0.305, P =0.020), particularly acetate (r=−0.311, P =0.017). Conclusions: Gut microbiome diversity, levels of microbial metabolites, and the bacteria Alistipesfinegoldii and Lactobacillus were associated with lower BP variability and Clostridium and Prevotella with higher BP variability. Thus, our findings suggest the gut microbiome and metabolites may be involved in the regulation of BP variability.

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Maternal diet and gut microbiota influence predisposition to cardiovascular disease in the offspring

Jama

Dinakis

Nakai

et al. 2022

Preprint

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Cardiovascular disease is one of the most significant causes of death globally, especially in regions where unhealthy diets are prevalent and dietary fibre intake is low.1,2 Fibre, particularly prebiotic types that feed gut microbes, is essential for maintaining healthy gut microbial ecosystems.3 One assumption has been that cardiovascular health relates directly to lifestyle choices in adult life. Here, we show in mice that some of these benefits operate from the prenatal stage and relate to the diet and gut microbiome of the mother. Intake of fibre during pregnancy shaped the mothers' gut microbiome, which had a lasting founding effect on the offspring's microbial composition and function. Maternal fibre intake during pregnancy significantly changed the cardiac cellular and molecular landscape in the offspring, protecting them against the development of cardiac hypertrophy, remodelling, and inflammation. These suggest a role for foetal exposure to maternal-derived gut microbial metabolites, which are known to cross the placenta and drive epigenetic changes. Maternal fibre intake led to foetal epigenetic reprogramming of the atrial natriuretic peptide gene (Nppa), protective against heart failure. These results underscore the importance of dietary intake and the gut microbiome of the mother during pregnancy for cardiovascular disease in the offspring.

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Renal ACE2 (Angiotensin-Converting Enzyme 2) Expression Is Modulated by Dietary Fiber Intake, Gut Microbiota, and Their Metabolites

et al. 2021

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GPR41/43 regulates blood pressure by improving gut epithelial barrier integrity to prevent TLR4 activation and renal inflammation

Muralitharan

Zheng

Dinakis

et al. 2023

Preprint

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Fermentation of dietary fibre by the gut microbiota leads to the production of metabolites called short-chain fatty acids (SCFAs), which have emerged as potent regulators of immune, metabolic, and tissue barrier functions. More recently, a high fibre diet and SCFA supplementation were shown to lower blood pressure and be cardio-protective. SCFAs activate host signalling responses via the receptors GPR41 and GPR43, which have redundancy in their signalling pathways. Whether these receptors play a role in hypertension or mediate the cardio-protective effects of fibre remains unknown. Using an experimental model that lacks both GPR41 and GPR43, we show that lack of signalling via these receptors increases risk to high blood pressure and leads to cardiorenal fibrosis and hypertrophy. Moreover, we demonstrate that GPR41/43 signalling is essential in maintaining gut epithelial barrier, which prevents the translocation of the bacterial toxins lipopolysaccharides (LPS) from entering the peripheral circulation. In the absence of GPR41/43, this is accompanied by macrophage infiltration to the kidneys, resulting in pro-inflammatory cytokine production. Using an antagonist against the LPS receptor, TLR4, a potent pro-inflammatory signalling pathway, we were able to rescue the cardiovascular phenotype in GPR41/43 knockout mice. We also demonstrate that GPR41/43 are, at least partially, responsible for the blood pressure-lowering and cardio-protective effects of a high fibre diet; however, improvements of gut barrier integrity and macrophages in the kidney were independent of GPR41/43 signalling. Finally, using the UK Biobank, we provide translational evidence that variants associated with lower expression of both GPR41/43 are more prevalent in hypertensive patients. Our findings highlight that lack of SCFA-receptor signalling via both GPR41/43 increases risk of high blood pressure, suggesting these receptors could be targeted as a new treatment.

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Evany Dinakis

The Gut Microbiota and Their Metabolites in Human Arterial Stiffness

Association Between the Gut Microbiome and Their Metabolites With Human Blood Pressure Variability

Maternal diet and gut microbiota influence predisposition to cardiovascular disease in the offspring

Renal ACE2 (Angiotensin-Converting Enzyme 2) Expression Is Modulated by Dietary Fiber Intake, Gut Microbiota, and Their Metabolites

GPR41/43 regulates blood pressure by improving gut epithelial barrier integrity to prevent TLR4 activation and renal inflammation

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