MAP kinases (MAPKs), such as ERK1/2, exert profound effects on a variety of physiological processes. In steroidogenic cells, ERK1/2 are involved in the expression and activation of steroidogenic acute regulatory protein, which plays a central role in the regulation of steroidogenesis. In MA-10 Leydig cells, LH and chorionic gonadotropin (CG) trigger transient ERK1/2 activation via protein kinase A, although the events that lead to ERK1/2 inactivation are not fully described. Here, we describe the hormonal regulation of MAPK phosphatase-1 (MKP-1), an enzyme that inactivates MAPKs, in MA-10 cells. In our experiments, human CG (hCG)/cAMP stimulation rapidly and transiently increased MKP-1 mRNA levels by a transcriptional action. This effect was accompanied by an increase in protein levels in both nuclear and mitochondrial compartments. In cells transiently expressing flag-MKP-1 protein, hCG/cAMP promoted the accumulation of the recombinant protein in a time-dependent manner (10-fold at 1 h). Moreover, hCG/cAMP triggered ERK1/2-dependent MKP-1 phosphorylation. The blockade of cAMP-induced MAPK kinase/ERK activation abated MKP-1 phosphorylation but only partially reduced flag-MKP-1 protein accumulation. Together, these results suggest that hCG regulates MKP-1 at transcriptional and posttranslational level, protein phosphorylation being one of the mechanisms involved in this regulation. Our study also demonstrates that MKP-1 overexpression reduces the effects of cAMP on ERK1/2 phosphorylation, steroidogenic acute regulatory gene promoter activity, mRNA levels, and steroidogenesis, whereas MKP-1 down-regulation by small interfering RNA produces opposite effects. In summary, our data demonstrate that hCG regulates MKP-1 expression at multiple stages as a negative feedback regulatory mechanism to modulate the hormonal action on ERK1/2 activity and steroidogenesis.
The protein kinase liver kinase B1 (LKB1) regulates cell polarity and intercellular junction stability. Also, LKB1 controls the activity of salt-inducible kinase 1 (SIK1). The role and relevance of SIK1 and its downstream effectors in linking the LKB1 signals within these processes are partially understood. We hypothesize that SIK1 may link LKB1 signals to the maintenance of epithelial junction stability by regulating E-cadherin expression. Results from our studies using a mouse lung alveolar epithelial (MLE-12) cell line or human renal proximal tubule (HK2) cell line transiently or stably lacking the expression of SIK1 (using SIK1 siRNAs or shRNAs), or with its expression abrogated (sik1(+/+) vs. sik1(-/-) mice), indicate that suppression of SIK1 (∼40%) increases the expression of the transcriptional repressors Snail2 (∼12-fold), Zeb1 (∼100%), Zeb2 (∼50%), and TWIST (∼20-fold) by activating cAMP-response element binding protein. The lack of SIK1 and activation of transcriptional repressors decreases the availability of E-cadherin (mRNA and protein expression by ∼100 and 80%, respectively) and the stability of intercellular junctions in epithelia (decreases in transepithelial resistance). Furthermore, LKB1-mediated increases in E-cadherin expression are impaired in cells where SIK1 has been disabled. We conclude that SIK1 is a key regulator of E-cadherin expression, and thereby contributes to the stability of intercellular junctions.
Rationale:In human genetic studies a single nucleotide polymorphism within the salt-inducible kinase 1 (SIK1) gene was associated with hypertension. Lower SIK1 activity in vascular smooth muscle cells (VSMCs) leads to decreased sodium-potassium ATPase activity, which associates with increased vascular tone. Also, SIK1 participates in a negative feedback mechanism on the transforming growth factor-β1 signaling and downregulation of SIK1 induces the expression of extracellular matrix remodeling genes.Objective: To evaluate whether reduced expression/activity of SIK1 alone or in combination with elevated salt intake could modify the structure and function of the vasculature, leading to higher blood pressure. Methods and Results: SIK1 knockout (sik1 −/−) and wild-type (sik1 +/+ ) mice were challenged to a normal-or chronic high-salt intake (1% NaCl). Under normal-salt conditions, the sik1 −/− mice showed increased collagen deposition in the aorta but similar blood pressure compared with the sik1 +/+ mice. During high-salt intake, the sik1 +/+ mice exhibited an increase in SIK1 expression in the VSMCs layer of the aorta, whereas the sik1 −/− mice exhibited upregulated transforming growth factor-β1 signaling and increased expression of endothelin-1 and genes involved in VSMC contraction, higher systolic blood pressure, and signs of cardiac hypertrophy. In vitro knockdown of SIK1 induced upregulation of collagen in aortic adventitial fibroblasts and enhanced the expression of contractile markers and of endothelin-1 in VSMCs. Conclusions: Bertorello et al SIK1, Hypertension, and Vascular Remodeling 643Elevated arterial blood pressure can occur as a consequence of increased vascular stiffness attributed to both extracellular matrix deposition/remodeling and enhanced contractility/stiffness of VSMCs. [10][11][12][13] Transforming growth factor-β1 (TGF-β1) is a pleiotropic cytokine that mediates extracellular matrix remodeling processes within the vasculature in addition to promote VSMCs differentiation toward a contractile phenotype.14-18 SIK1 participates in a negative feedback mechanism on the TGF-β1 signaling pathway. 19 We have reported that in epithelial cells the loss of SIK1 increased the expression of SNAI2 and TWIST1, known transcription factors involved in fibrosis and extracellular matrix remodeling. Recently, brain SIK1 activity has been shown to be relevant for blood pressure regulation in rodents by regulating sympathetic activity. Higher hypothalamic activity of SIK1 was associated with reduced sympathoexcitatory activity and lower arterial blood pressure in rats after a high-salt diet and intracerebroventricular infusion of Na + . 20Because SIK1 is present in the vasculature and lower SIK1 activity was associated with elevated blood pressure in humans and rodents, we hypothesize that the lack of SIK1 could trigger vascular remodeling processes leading to increased vascular stiffness and consequently to higher blood pressure. Furthermore, these events alone or in combination with other risk factors (high-s...
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