Department of Pharmacology and Nutritional Sciences, University of Kentucky, Lexington, KY, USA.
Center for Muscle Biology, University of Kentucky, Lexington, KY, USA.
Mol Med. 2024 Nov 19;30(1):221. doi: 10.1186/s10020-024-00982-w.
Sepsis, mainly caused by bacterial infections, is the leading cause of in-patient hospitalizations. After discharge, most sepsis survivors suffer from long-term medical complications, particularly chronic skeletal muscle weakness. To investigate this medical condition in detail, we previously developed a murine severe sepsis-survival model that exhibits long-term post-sepsis skeletal muscle weakness. While mitochondrial abnormalities were present in the skeletal muscle of the sepsis surviving mice, the relationship between abnormal mitochondria and muscle weakness remained unclear. Herein, we aimed to investigate whether mitochondrial abnormalities have a causal role in chronic post-sepsis muscle weakness and could thereby serve as a therapeutic target.
Experimental polymicrobial abdominal sepsis was induced in 16-18 months old male and female mice using cecal slurry injection with subsequent antibiotic and fluid resuscitation. To evaluate the pathological roles of mitochondrial abnormalities in post-sepsis skeletal muscle weakness, we utilized a transgenic mouse strain overexpressing the mitochondria-specific antioxidant enzyme manganese superoxide dismutase (MnSOD). Following sepsis development in C57BL/6 mice, we evaluated the effect of the mitochondria-targeting synthetic tetrapeptide SS-31 in protecting mitochondria from sepsis-induced damage and preventing skeletal muscle weakness development. In vivo and in vitro techniques were leveraged to assess muscle function at multiple timepoints throughout sepsis development and resolution. Histological and biochemical analyses including bulk mRNA sequencing were used to detect molecular changes in the muscle during and after sepsis RESULTS: Our time course study revealed that post sepsis skeletal muscle weakness develops progressively after the resolution of acute sepsis and in parallel with the accumulation of mitochondrial abnormalities and changes in the mitochondria-related gene expression profile. Transgenic mice overexpressing MnSOD were protected from mitochondrial abnormalities and muscle weakness following sepsis. Further, pharmacological protection of mitochondria utilizing SS-31 during sepsis effectively prevented the later development of muscle weakness.
Our study revealed that the accumulation of mitochondrial abnormalities is the major cause of post-sepsis skeletal muscle weakness. Pharmacological protection of mitochondria during acute sepsis is a potential clinical treatment strategy to prevent post-sepsis muscle weakness.
脓毒症主要由细菌感染引起,是住院患者的主要病因。出院后,大多数脓毒症幸存者都患有长期的医疗并发症,特别是慢性骨骼肌肉无力。为了详细研究这种医疗状况,我们之前开发了一种脓毒症存活的小鼠严重脓毒症模型,该模型表现出长期的脓毒症后骨骼肌肉无力。虽然脓毒症存活小鼠的骨骼肌存在线粒体异常,但异常线粒体与肌肉无力之间的关系尚不清楚。在此,我们旨在研究线粒体异常是否在慢性脓毒症后肌肉无力中起因果作用,并因此作为治疗靶点。
使用盲肠内容物注射加随后的抗生素和液体复苏,在 16-18 个月大的雄性和雌性小鼠中诱导实验性多微生物腹部脓毒症。为了评估线粒体异常在脓毒症后骨骼肌无力中的病理作用,我们利用了一种过表达线粒体特异性抗氧化酶锰超氧化物歧化酶(MnSOD)的转基因小鼠品系。在 C57BL/6 小鼠中发展脓毒症后,我们评估了线粒体靶向合成四肽 SS-31 在保护线粒体免受脓毒症引起的损伤和防止骨骼肌无力发展中的作用。利用体内和体外技术,在脓毒症发展和解决的多个时间点评估肌肉功能。组织学和生化分析,包括批量 mRNA 测序,用于检测脓毒症期间和之后肌肉中的分子变化。
我们的时间进程研究表明,脓毒症后骨骼肌无力在急性脓毒症缓解后逐渐发展,并与线粒体异常的积累和线粒体相关基因表达谱的变化平行。过表达 MnSOD 的转基因小鼠在脓毒症后免受线粒体异常和肌肉无力的影响。此外,在脓毒症期间利用 SS-31 保护线粒体可有效防止后期肌肉无力的发生。
我们的研究表明,线粒体异常的积累是脓毒症后骨骼肌肉无力的主要原因。在急性脓毒症期间保护线粒体是预防脓毒症后肌肉无力的潜在临床治疗策略。
