INFLUENCE OF LONG-TERM ANTIBIOTIC THERAPY ON GUT MICROBIOME COMPOSITION AND METABOLIC PROFILE IN PULMONARY TUBERCULOSIS

M. Yunusbaeva, D. Terentyeva, L. Borodina, A. Zakirova, S. Bulatov, F. Bilalov, B. Yunusbayev
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Abstract

The use of long-term multicomponent antibiotic therapy is the most effective way to treat tuberculosis (TB). However, little is known about the effect of this chemotherapy on the human intestinal microflora. The purpose of this study was to analyze an effect of long-term antibiotic therapy on gut microbiome composition and metabolic profile in TB patients. We used deep sequencing of fecal samples from 23 treatment-naive TB patients to reconstruct the metabolic capacity and strain/species-level abundance in the gut microbiome. Two fecal samples were obtained from each patient: before and after treatment. We showed that TB treatment regimen does not disrupt the overall diversity of the gut microbiome but does have an impact on gut bacterial microbiome composition and metabolic profile. While taking first-line anti-tuberculosis drugs (isoniazid, rifampicin, ethambutol, pyrazinamide), TB patients showed an apparent increase in Actinobacteria abundance. Pairwise comparison of metagenomic data revealed 28 differentially represented bacterial taxa, of which three species Bacteroides cellulosilyticus, Enterocloster aldensis, Clostridium spiroforme were strongly enriched in TB patients post-chemotherapy, whereas 25 species were enriched in TB patients before treatment (Bifidobacterium catenulatum, Enterococcus faecium, Bacteroides salyersiae, Bacteroides xylanisolvens, Bacteroides eggerthii, Lachnospira eligens, Akkermansia muciniphila, Ruminococcus lactaris, etc.) (p 0.05). The metabolic profile of the gut microbiome was characterized by increased metabolic processes aimed at the growth and division of microbial cells. Iron is the main limiting factor for growth and reproduction. In addition, it is important to note the prevalence of glycolysis and lactate fermentation as the major means for energy production by intestinal microbiota.
长期抗生素治疗对肺结核患者肠道微生物组组成和代谢特征的影响
长期使用多成分抗生素疗法是治疗结核病(TB)最有效的方法。然而,人们对这种化疗对人体肠道微生物区系的影响知之甚少。本研究旨在分析长期抗生素治疗对肺结核患者肠道微生物组组成和代谢特征的影响。我们对 23 名未经治疗的肺结核患者的粪便样本进行了深度测序,以重建肠道微生物组的代谢能力和菌株/物种丰度。每位患者在治疗前和治疗后均获得了两份粪便样本。我们的研究表明,结核病治疗方案不会破坏肠道微生物组的整体多样性,但会对肠道细菌微生物组的组成和代谢状况产生影响。在服用一线抗结核药物(异烟肼、利福平、乙胺丁醇、吡嗪酰胺)期间,结核病患者的放线菌数量明显增加。对元基因组数据进行配对比较后发现,在化疗后的肺结核患者中,有 28 个细菌类群的表现存在差异,其中有 3 个细菌类群在化疗后的肺结核患者中大量富集,分别是纤维素丝状乳杆菌(Bacteroides cellulosilyticus)、艾氏肠球菌(Enterocloster aldensis)和螺旋梭菌(Clostridium spiroforme)、而在治疗前,有 25 个物种在肺结核患者中富集(双歧杆菌、粪肠球菌、沙雷氏乳杆菌、木聚糖乳杆菌、鸡蛋乳杆菌、Lachnospira eligens、Akkermansia muciniphila、Ruminococcus lactaris 等)(P 0.05)。) (p 0.05).肠道微生物群的代谢特征是微生物细胞生长和分裂的代谢过程增加。铁是生长和繁殖的主要限制因素。此外,值得注意的是,糖酵解和乳酸发酵是肠道微生物群产生能量的主要方式。
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