High-methionine diet in skeletal muscle remodeling: epigenetic mechanism of homocysteine-mediated growth retardation

Epigenetic DNA methylation (1-carbon metabolism) is crucial for gene imprinting/off-printing that ensures epigenetic memory but also generates a copious amount of homocysteine (Hcy), unequivocally. That is why during pregnancy, expectant mothers are recommended folic acid preemptively to avoid birth defects in the young ones because of elevated Hcy levels (i.e., hyperhomocysteinemia (HHcy)). As we know, children born with HHcy have several musculoskeletal abnormalities, including growth retardation. Here, we focus on the gut-dysbiotic microbiome implication(s) that we believe instigates the 1-carbon metabolism and HHcy causing growth retardation along with skeletal muscle abnormalities. We test our hypothesis whether high-methionine diet (HMD) (an amino acid that is high in red meat), a substrate for Hcy, can cause skeletal muscle and growth retardation, and treatment with probiotics (PB) to mitigate skeletal muscle dysfunction. To test this, we employed cystathionine beta-synthase, CBS deficient mouse (CBS+/-) fed with/without HMD and with/without a probiotic (Lactobacillus rhamnosus) in drinking water for 16 weeks. Matrix metalloproteinase (MMP) activity, a hallmark of remodeling, was measured by zymography. Muscle functions were scored via electric stimulation. Our results suggest that compared to the wild-type, CBS+/- mice exhibited reduced growth phenotype. MMP-2 activity was robust in CBS+/- and HMD effects were successfully attenuated by PB intervention. Electrical stimulation magnitude was decreased in CBS+/- and CBS+/- treated with HMD. Interestingly, PB mitigated skeletal muscle growth retardation and atrophy. Collectively, results imply that individuals with mild/moderate HHcy seem more prone to skeletal muscle injury and its dysfunction.

Automated summary

This study focuses on the impact of 1-carbon metabolism and HHcy on growth retardation and muscle abnormalities, while also considering the potential role of gut dysbiosis in this process. The results suggest that individuals with mild to moderate HHcy may be more susceptible to muscle injury and dysfunction.