Mitochondrial Permeability Transition in Skeletal Muscle Phenocopies Muscle Alterations seen in Cancer Cachexia and other Wasting Conditions

BackgroundSkeletal muscle in wasting conditions often exhibits a common set of phenotypes that include atrophy, mitochondrial respiratory dysfunction, and fragmentation of the acetylcholine receptor (AChR) cluster at the endplate. Mitochondria are frequently implicated in driving muscle pathology in these conditions, although which aspects of mitochondrial function are most relevant is poorly understood. MethodsTo address this gap, we focused on mitochondrial permeability transition (mPT), a well-established pathological mechanism in ischemia-reperfusion injury and neurodegeneration but poorly studied in skeletal muscle. We performed a broad assessment of the consequences of mPT in skeletal muscle, focusing on features that are common in wasting conditions. We then tested whether tumor-host factors could promote mPT and compared differentially expressed genes (DEGs) with mPT and a mouse model of pancreatic cancer cachexia. ResultsInducing mPT in mouse skeletal muscle bundles in a Ca2+ retention capacity assay progressively altered mitochondrial morphology, beginning with cristae swirling and condensation, progressing to mitochondrial cristae displacement, and culminating in breach of the outer mitochondrial membrane; features that are common in wasting conditions. Inducing mPT with Bz423 in single mouse muscle fibers increased mROS and Caspase 3 (Casp3) activity and was prevented by inhibitors of mPT, mROS or Casp3. Incubating single muscle fibers with Bz423 for 24 h reduced fiber diameter by [~]20% which was prevented by inhibiting mPT, mROS, or Casp3. Inducing mPT caused a complex I-specific mitochondrial respiratory impairment and increased co-localization of lysosomes with mitochondria. Inducing mPT also fragmented the AChR cluster at the muscle endplate and was prevented by inhibiting mPT or Casp3. The Ca2+ threshold for mPT and mitochondrial calcein colocalization were reduced by pancreatic tumor-conditioned media in skeletal muscle or C2C12 myoblasts, respectively, and these effects were counteracted by mPT inhibition or cyclophilin D knockout. Finally, there was significant overlap between the transcriptome of mPT and that seen in diaphragm muscle in a mouse model of pancreatic cancer cachexia, particularly during the muscle wasting phase. ConclusionsWe conclude that inducing mPT in skeletal muscle recapitulates muscle phenotypes common with muscle wasting conditions like cachexia. Furthermore, mPT is engaged by tumor-host factors and had significant overlap with DEGs seen during the muscle wasting phase in a mouse model of pancreatic cancer cachexia, warranting further investigation of mPT as a therapeutic target.