The impact of butyrate on group B Streptococcus-induced intestinal barrier disruption.

IF 2.9 3区 医学 Q3 IMMUNOLOGY
Infection and Immunity Pub Date : 2024-10-15 Epub Date: 2024-08-12 DOI:10.1128/iai.00200-24
Kristen Dominguez, Alexia N Pearah, April K Lindon, Leigh-Anne M Worthington, Rico R Carter, Nichol John-Lewis Edwards, Thao T B Ho, Sophie E Darch, Tara M Randis
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Abstract

Group B Streptococcus (Streptococcus agalactiae; GBS) is a leading cause of neonatal sepsis worldwide. As a pathobiont of the intestinal tract, it is capable of translocating across barriers leading to invasive disease. Neonatal susceptibility to invasive disease stems from immature intestinal barriers. GBS intestinal colonization induces major transcriptomic changes in the intestinal epithelium related to barrier function. Butyrate, a microbial metabolite produced by fermentation of dietary fiber, bolsters intestinal barrier function against enteric pathogens, and these effects can be transferred in utero via the placenta to the developing fetus. Our aim was to determine if butyrate mitigates GBS disruption of intestinal barriers. We used human intestinal epithelial cell (IEC) lines to evaluate the impact of butyrate on GBS-induced cell death and GBS adhesion and invasion. IECs and human fetal tissue-derived enteroids were used to evaluate monolayer permeability. We evaluated the impact of maternal butyrate treatment (mButyrate) using our established mouse model of neonatal GBS intestinal colonization and late-onset sepsis. We found that butyrate reduces GBS-induced cell death, GBS invasion, monolayer permeability, and translocation in vitro. In mice, mButyrate decreases GBS intestinal burden in offspring. Our results demonstrate the importance of bacterial metabolites, such as butyrate, in their potential to bolster epithelial barrier function and mitigate neonatal sepsis risk.IMPORTANCEGroup B Streptococcus (GBS) is a leading cause of neonatal morbidity and mortality. It is a commensal of the intestines that can translocate across barriers leading to sepsis in vulnerable newborns. With the rise in antibiotic-resistant strains and no licensed vaccine, there is an urgent need for preventative strategies. Butyrate, a short-chain fatty acid metabolized in the gut, enhances barrier function against pathogens. Importantly, butyrate is transferred in utero, conferring these benefits to infants. Here, we demonstrate that butyrate reduces GBS colonization and epithelial invasion. These effects were not microbiome-driven, suggesting butyrate directly impacts epithelial barrier function. Our results highlight the potential impact of maternal dietary metabolites, like butyrate, as a strategy to mitigate neonatal sepsis risk.

丁酸盐对 B 群链球菌引起的肠屏障破坏的影响
B 群链球菌(无乳链球菌;GBS)是全球新生儿败血症的主要病因。作为肠道的致病菌,它能够跨越屏障,导致侵袭性疾病。新生儿易患侵袭性疾病的原因是肠道屏障尚未发育成熟。GBS 的肠道定植会诱导肠上皮细胞发生与屏障功能有关的重大转录组变化。丁酸盐是膳食纤维发酵产生的一种微生物代谢产物,可增强肠道屏障功能,抵御肠道病原体,这些作用可在子宫内通过胎盘传递给发育中的胎儿。我们的目的是确定丁酸盐是否能减轻 GBS 对肠道屏障的破坏。我们使用人类肠上皮细胞(IEC)系来评估丁酸盐对 GBS 诱导的细胞死亡以及 GBS 粘附和侵袭的影响。我们使用 IEC 和源自人类胎儿组织的肠液来评估单层渗透性。我们利用已建立的新生儿 GBS 肠道定植和晚期败血症小鼠模型评估了母体丁酸盐治疗(mButyrate)的影响。我们发现,丁酸盐可减少 GBS 诱导的体外细胞死亡、GBS 入侵、单层渗透性和转运。在小鼠体内,丁酸盐可减少后代肠道中 GBS 的负担。我们的研究结果表明了细菌代谢产物(如丁酸盐)在增强上皮屏障功能和降低新生儿败血症风险方面的重要性。重要意义B组链球菌(GBS)是新生儿发病和死亡的主要原因。它是肠道中的一种共生菌,可以跨越屏障,导致易感新生儿败血症。随着抗生素耐药菌株的增加,而目前还没有获得许可的疫苗,因此迫切需要制定预防策略。丁酸盐是一种在肠道中代谢的短链脂肪酸,可增强屏障功能,抵御病原体。重要的是,丁酸盐可在子宫内转移,从而为婴儿带来这些益处。在这里,我们证明了丁酸盐能减少肠道GBS定植和上皮侵袭。这些影响不是由微生物驱动的,表明丁酸盐能直接影响上皮屏障功能。我们的研究结果凸显了母体膳食代谢物(如丁酸盐)作为降低新生儿败血症风险策略的潜在影响。
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来源期刊
Infection and Immunity
Infection and Immunity 医学-传染病学
CiteScore
6.00
自引率
6.50%
发文量
268
审稿时长
3 months
期刊介绍: Infection and Immunity (IAI) provides new insights into the interactions between bacterial, fungal and parasitic pathogens and their hosts. Specific areas of interest include mechanisms of molecular pathogenesis, virulence factors, cellular microbiology, experimental models of infection, host resistance or susceptibility, and the generation of innate and adaptive immune responses. IAI also welcomes studies of the microbiome relating to host-pathogen interactions.
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