RESUMO
BCL-2-like protein 1 (BCL2L1) is a key component of cell survival and death mechanisms. Its dysregulation and altered ratio of splicing variants associate with pathologies. However, isoform-specific loss-of-function analysis of BCL2L1 remains unexplored. Here we show the functional impact of genetically inhibiting Bcl-x short-isoform (Bcl-xS) in vivo. Bcl-xS is expressed in most tissues with predominant expression in the spleen and blood cells in mice. Bcl-xS knockout (KO) mice show no overt abnormality until 3 months of age. Thereafter, KO mice develop cardiac hypertrophy with contractile dysfunction and splenomegaly by 6 months. Cardiac fibrosis significantly increases in KO, but the frequency of apoptosis is indistinguishable despite cardiomyopathy. The Akt/mTOR and JNK/cJun signaling are upregulated in male KO heart, and the JNK/cJun is activated with increased Bax expression in KO spleen. These results suggest that Bcl-xS may be dispensable for development but is essential for maintaining the homeostasis of multiple organs.
RESUMO
The anti-apoptotic function of Bcl-xL in the heart during ischemia/reperfusion is diminished by K-Ras-Mst1-mediated phosphorylation of Ser14, which allows dissociation of Bcl-xL from Bax and promotes cardiomyocyte death. Here we show that Ser14 phosphorylation of Bcl-xL is also promoted by hemodynamic stress in the heart, through the H-Ras-ERK pathway. Bcl-xL Ser14 phosphorylation-resistant knock-in male mice develop less cardiac hypertrophy and exhibit contractile dysfunction and increased mortality during acute pressure overload. Bcl-xL Ser14 phosphorylation enhances the Ca2+ transient by blocking the inhibitory interaction between Bcl-xL and IP3Rs, thereby promoting Ca2+ release and activation of the calcineurin-NFAT pathway, a Ca2+-dependent mechanism that promotes cardiac hypertrophy. These results suggest that phosphorylation of Bcl-xL at Ser14 in response to acute pressure overload plays an essential role in mediating compensatory hypertrophy by inducing the release of Bcl-xL from IP3Rs, alleviating the negative constraint of Bcl-xL upon the IP3R-NFAT pathway.