ASlc5a6Deficient Mouse Model Reveals a Metabolically Driven Dilated Cardiomyopathy with Therapeutic Potential for Vitamin-Based Intervention

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Abstract

Background and Aims

The sodium-dependent multivitamin transporter, encoded bySLC5A6, mediates cellular uptake of the vitamins, biotin and pantothenic acid, both of which are essential cofactors for energy metabolism. Here, we report two families withSLC5A6mutations presenting with early-onset dilated cardiomyopathy (DCM). To investigate the link between vitamin deficiency and DCM, we generated a novel cardiac-specificSlc5a6knockout (Slc5a6cKO) mouse model and tested the therapeutic potential of vitamin supplementation.

Methods

Cardiac function inSlc5a6cKOmice was assessed by cardiac magnetic resonance imaging and ECG measurements. Histological, biochemical, and proteomic analyses were conducted to identify structural and metabolic changes. The impact of dietary biotin and pantothenic acid supplementation on disease progression was evaluated.

Results

Slc5a6cKOmice developed progressive cardiac dysfunction, manifesting as DCM with cardiac dilation, cardiomyocyte hypertrophy, fibrosis, impaired Coenzyme A synthesis, and metabolic imbalance, culminating in premature death by 26 weeks. Proteomic analysis revealed early mitochondrial metabolic disruption and extracellular matrix protein upregulation at 8 weeks, preceding overt cardiac dysfunction. Strikingly, vitamin supplementation from preconception onwards, prevented the cardiac phenotype, preserving cardiac structure, function, morphology and survival. This parallels the clinical outcome in one patient who received early vitamin treatment, compared to another who required a heart transplant following delayed vitamin treatment.

Conclusions

This study establishes a direct link between SLC5A6-mediated vitamin transport, mitochondrial function, and cardiac health. It highlights how vitamin deficiency contributes to DCM pathogenesis and supports early vitamin supplementation as a potential therapeutic strategy for metabolic cardiomyopathies.

Translational perspective

This study highlights the therapeutic potential of vitamin supplementation in treating dilated cardiomyopathy (DCM) caused by mitochondrial abnormalities. Using a cardiac-specificSlc5a6knockout mouse model, we demonstrated that deficiencies in key vitamins, biotin and pantothenic acid, impair mitochondrial energy metabolism, leading to DCM progression. Remarkably, vitamin supplementation preserved cardiac function, morphology, and survival, suggesting that restoring vitamin levels could be a promising therapeutic strategy for DCM and other cardiomyopathies linked to metabolic deficiencies. These findings could inform newborn screening programmes and clinical approaches for treating mitochondrial-related cardiac diseases by targeting specific vitamin deficiencies.

Key Question

What is the underlying molecular cause of early-onset dilated cardiomyopathy in patients withSLC5A6mutations, and can insights from a cardiac-specific knockout mouse model reveal potential metabolic mechanisms and therapeutic strategies involving vitamin supplementation?

Key Finding

Cardiac-specific deletion ofSlc5a6in mice caused early mitochondrial dysfunction, metabolic derangement, and progressive dilated cardiomyopathy. Strikingly, early and continuous supplementation with biotin and pantothenic acid completely preserved cardiac structure, function, and survival, paralleling successful outcomes in patients treated early.

Take Home Message

This study establishes a mechanistic link betweenSLC5A6mutations, vitamin deficiency and mitochondrial abnormalities as a cause of dilated cardiomyopathy. Early vitamin supplementation prevents disease onset, highlighting the potential of targeted vitamin therapy in metabolic cardiomyopathies.

Abstract Figure

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