Background: Cardiac hypertrophy is a major risk factor for adverse cardiovascular events including heart failure and arrhythmia. However, the precise orientation of cell and organ growth varies considerably depending on stress type and duration with important implications for cardiac function. Despite this, little is known regarding the mechanisms that regulate hypertrophic orientation. Here we evaluate the role of the cytoskeletal protein β IV -spectrin and signal transducer and activator of transcription (STAT3) in directing the orientation of pressure overload-induced hypertrophy. Methods: Transgenic mouse models with altered STAT3 signaling through modified interaction with its scaffolding partner β IV -spectrin, or phospho-regulation of STAT3 directly, were evaluated at baseline and transaortic constriction (TAC) for its role in promoting concentric versus eccentric morphologies and resulting impact on systolic function. Unbiased screening of gene expression from these structurally divergent states were evaluated for pathways responsible for directing myocyte length/width. These pathways were tested in vitro using primary mouse myocytes and in vivo to tune growth patterns for therapeutic intervention. Results: Loss of β IV -spectrin or direct STAT3 activation promoted a preferential increase in myocyte length over width, resulting in dilation of the left ventricular (LV) chamber (eccentric hypertrophy) and decreased systolic function. Conversely, preservation of β IV -spectrin favored an increase in myocyte width without LV dilation (concentric hypertrophy) and preserved systolic function in response to TAC. Differential expression of genes associated with microtubule dynamics were identified in concentric vs. eccentric hypertrophic states. In vitro assays revealed a relationship between β IV -spectrin/STAT3 signaling and microtubule stability which impacted spatial distribution of mRNA for the sarcomeric gene actc1 . Finally, intervention with pharmacologic STAT3 inhibition following chronic 6-week TAC successfully recovered concentric growth with improved systolic function. Conclusions: These data identify a novel and pivotal role for β IV -spectrin/STAT3 to modify microtubule dynamics and sarcomeric transcript distribution to direct myocyte geometry and therapeutically serve in the prevention or recovery from HF. These mechanisms further illustrate the unique separation of hypertrophic drivers from growth orientation as distinct pathways in cardiac remodeling.
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