Huntington’s disease (HD) is a neurodegenerative autosomal dominant disorder, characterized by symptoms of involuntary movement of the body, loss of cognitive function, psychiatric disorder, leading inevitably to death. It has been previously described that higher levels of brain expression of Ca
v
1 channels are involved in major neurodegenerative disorders, such as Alzheimer’s disease and Parkinson’s disease. Our results demonstrate that a bacterial artificial chromosome (BAC)-mediated transgenic mouse model (BACHD mice) at the age of 3 and 12 months exhibits significantly increased Ca
v
1.2 protein levels in the cortex, as compared with wild-type littermates. Importantly, electrophysiological analyses confirm a significant increase in L-type Ca
2+
currents and total Ca
2+
current density in cortical neurons from BACHD mice. By using an
in vitro
assay to measure neuronal cell death, we were able to observe neuronal protection against glutamate toxicity after treatment with Ca
v
1 blockers, in wild-type and, more importantly, in BACHD neurons. According to our data, Ca
v
1 blockers may offer an interesting strategy for the treatment of HD. Altogether, our results show that mutant huntingtin (mHtt) expression may cause a dysregulation of Ca
v
1.2 channels and we hypothesize that this contributes to neurodegeneration during HD.
Little is known regarding the role of suppressor of cytokine signaling (SOCS) in the control of cytokine signaling in cardiomyocytes. We investigated the consequences of SOCS2 ablation for leukemia inhibitory factor (LIF)-induced enhancement of intracellular Ca ([Ca]) transient by performing experiments with cardiomyocytes from SOCS2-knockout (ko) mice. Similar levels of SOCS3 transcripts were seen in cardiomyocytes from wild-type and SOCS2-ko mice, while SOCS1 mRNA was reduced in SOCS2-ko. Immunoprecipitation experiments showed increased SOCS3 association with gp130 receptor in SOCS2-ko myocytes. Measurements of Ca in wild-type myocytes exposed to LIF showed a significant increase in the magnitude of the Ca transient. This change was absent in LIF-treated SOCS2-ko cells. LIF activation of ERK and STAT3 was observed in both wild-type and SOCS2-ko cells, indicating that in SOCS2-ko, LIF receptors were functional, despite the lack of effect in the Ca transient. In wild-type cells, LIF-induced increase in [Ca] and phospholamban Thr17 [PLN(Thr17)] phosphorylation was inhibited by KN-93, indicating a role for CaMKII in LIF-induced Ca raise. LIF-induced phosphorylation of PLN(Thr17) was abrogated in SOCS2-ko myocytes. In wild-type cardiomyocytes, LIF treatment increased L-type Ca current (), a key activator of CaMKII in response to LIF. Conversely, SOCS2-ko myocytes failed to activate in response to LIF, providing a rationale for the lack of LIF effect on Ca transient. Our data show that absence of SOCS2 turns cardiomyocytes unresponsive to LIF-induced [Ca] raise, indicating that endogenous levels of SOCS2 are crucial for full activation of LIF signaling in the heart.
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