Lactobacillus Restructures the Micro/Mycobiome to Combat Inflammation-Mediated Right Ventricular Dysfunction in Pulmonary Arterial Hypertension.

IF 8.4 1区医学 Q1 CARDIAC & CARDIOVASCULAR SYSTEMS

Circulation: Heart Failure Pub Date : 2025-07-01 Epub Date: 2025-05-16 DOI:10.1161/CIRCHEARTFAILURE.124.012524

Sasha Z Prisco, Madelyn Blake, Felipe Kazmirczak, Ryan Moon, Benjamin P Kremer, Lynn M Hartweck, Minwoo Kim, Neal Vogel, Jenna B Mendelson, Daphne Moutsoglou, Thenappan Thenappan, Kurt W Prins

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引用次数: 0

Abstract

Background: Inflammation suppresses right ventricular (RV) function in pulmonary arterial hypertension (PAH). In particular, we showed GP130 (glycoprotein-130) signaling promotes pathological microtubule remodeling and RV dysfunction in rodent PAH. Emerging data demonstrate the intestinal microbiome regulates systemic inflammation, but the impact of modulating the gut microbiome on the GP130-microtubule axis in RV failure is unknown.

Methods: Two weeks following monocrotaline injection, rats were administered daily Lactobacillus rhamnosus (4×10⁷ colony-forming units) via oral gavage for 10 days. Next-generation metagenomics and internal transcribed spacer 2 sequencing delineated fecal bacterial and fungal compositions. SomaScan proteomics measured levels of 7596 serum proteins. RV immunoblots quantified protein abundances. Light or super resolution confocal microscopy assessed RV, lung, and jejunal morphology. Echocardiography and invasive closed-chest pressure-volume loops evaluated PAH severity and RV function. The relationship between Lactobacillus abundance and RV function was assessed in 65 patients with PAH.

Results: Lactobacillus administration restructured both the intestinal micro- and mycobiome. The alteration in the gut ecosystem improved intestinal health as demonstrated by increased jejunal villus length and glycocalyx thickness and diminished intestinal permeability biomarkers. Serum proteomics revealed Lactobacillus modulated systemic inflammation and decreased circulating GP130 ligands. Lactobacillus-mediated suppression of GP130 signaling blunted pathological microtubule remodeling in RV cardiomyocytes. Microtubule-associated phenotypes, including RV cardiomyocyte and nuclear hypertrophy, transverse tubule integrity, and connexin-43 localization, were all corrected with Lactobacillus. These cellular changes manifested as improved RV function despite no significant alteration in PAH severity. Finally, patients with PAH and detectable fecal Lactobacillus had superior RV function despite similar mean pulmonary arterial pressure and pulmonary vascular resistance as compared with those without detectable Lactobacillus.

Conclusions: Lactobacillus supplementation restructures the gut micro/mycobiome, restores intestinal health, dampens systemic inflammation, and reduces GP130 ligands and associated RV cardiomyocyte microtubule remodeling. These data identify a novel microbiome-inflammation-microtubule axis that has therapeutic relevance for RV dysfunction.

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乳酸杆菌重组微/菌群对抗炎症介导的肺动脉高压右心室功能障碍

背景：炎症抑制肺动脉高压（PAH）患者右心室（RV）功能。特别是，我们发现GP130（糖蛋白-130）信号传导促进啮齿动物PAH的病理性微管重塑和RV功能障碍。新出现的数据表明肠道微生物组调节全身炎症，但在RV衰竭中调节肠道微生物组对gp130 -微管轴的影响尚不清楚。方法：给鼠李糖乳杆菌（4×107菌落形成单位）灌胃，连续灌胃10 d。下一代宏基因组学和内部转录间隔2测序描绘了粪便细菌和真菌组成。SomaScan蛋白质组学测量了7596种血清蛋白的水平。RV免疫印迹定量蛋白丰度。光或超分辨共聚焦显微镜评估右心室、肺和空肠形态。超声心动图和有创胸压-容积闭环评估PAH严重程度和右心室功能。对65例PAH患者的乳酸杆菌丰度与RV功能的关系进行了评估。结果：乳杆菌对肠道菌群和菌群均有重组作用。肠道生态系统的改变改善了肠道健康，空肠绒毛长度和糖萼厚度增加，肠道通透性生物标志物减少。血清蛋白质组学显示乳酸菌调节全身炎症，减少循环GP130配体。乳酸杆菌介导的GP130信号的抑制减弱了RV心肌细胞的病理性微管重塑。微管相关表型，包括RV心肌细胞和核肥大，横小管完整性和连接蛋白43定位，都用乳酸杆菌纠正。这些细胞变化表现为RV功能的改善，尽管PAH严重程度没有明显改变。最后，尽管平均肺动脉压和肺血管阻力与未检测到乳酸杆菌的患者相似，但PAH和可检测到粪便乳酸杆菌的患者的RV功能优于未检测到乳酸杆菌的患者。结论：补充乳酸菌可重组肠道微生物群，恢复肠道健康，抑制全身炎症，减少GP130配体和相关RV心肌细胞微管重塑。这些数据确定了一种新的微生物-炎症-微管轴，它与右心室功能障碍具有治疗相关性。

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来源期刊

Circulation: Heart Failure 医学-心血管系统

CiteScore

12.90

自引率

3.10%

发文量

271

审稿时长

6-12 weeks

期刊介绍： Circulation: Heart Failure focuses on content related to heart failure, mechanical circulatory support, and heart transplant science and medicine. It considers studies conducted in humans or analyses of human data, as well as preclinical studies with direct clinical correlation or relevance. While primarily a clinical journal, it may publish novel basic and preclinical studies that significantly advance the field of heart failure.