The PKARI�� Subunit of Protein Kinase A Modulates the Activation of p90RSK1 and Its Function

Previously, we showed that interactions between p90^RSK1 (RSK1) and the subunits of type I protein kinase A (PKA) regulate the activity of PKA and cellular distribution of active RSK1 (Chaturvedi, D., Poppleton, H. M., Stringfield, T., Barbier, A., and Patel, T. B. (2006) Mol. Cell Biol. 26, 4586–4600). Here we examined the role of the PKARIα subunit of PKA in regulating RSK1 activation and cell survival. In mouse lung fibroblasts, silencing of the PKARIα increased the phosphorylation and activation of RSK1, but not of RSK2 and RSK3, in the absence of any stimulation. Silencing of PKARIα also decreased the nuclear accumulation of active RSK1 and increased its cytoplasmic content. The increased activation of RSK1 in the absence of any agonist and changes in its subcellular redistribution resulted in increased phosphorylation of its cytoplasmic substrate BAD and increased cell survival. The activity of PKA and phosphorylation of BAD (Ser-155) were also enhanced when PKARIα was silenced, and this, in part, contributed to increased cell survival in unstimulated cells. Furthermore, we show that RSK1, PKA subunits, D-AKAP1, and protein phosphatase 2A catalytic subunit (PP2Ac) exist in a complex, and dissociation of RSK1 from D-AKAP1 by either silencing of PKARIα, depletion of D-AKAP1, or by using a peptide that competes with PKARIα for binding to AKAPs, decreased the amount of PP2Ac in the RSK1 complex. We also demonstrate that PP2Ac is one of the phosphatases that dephosphorylates RSK, but not ERK1/2. Thus, in unstimulated cells, the increased phosphorylation and activation of RSK1 after silencing of PKARIα or depletion of D-AKAP1 are due to decreased association of PP2Ac in the RSK1 complex.Cyclic AMP-dependent protein kinase (PKA)³ plays a pivotal role in manifesting an array of biological actions ranging from cell proliferation and tumorigenesis to increased inotropic and chronotropic effects in the heart as well as regulation of long term potentiation and memory. The PKA holoenzyme is a heterotetramer and consists of two catalytic (PKAc) subunits bound to a dimer of regulatory subunits. To date, four isoforms of the PKAc (PKAcα, PKAcβ, PKAcγ, and PKAcδ) and four isoforms of the regulatory subunits (RIα, RIβ, RIIα, and RIIβ) have been described (1). The various isoforms of PKA subunits are expressed differently in a tissue- and cell-specific manner (2). In addition to binding and inhibiting the activity of PKAc via their pseudo substrate region (3–6), the R subunits also interact with PKA-anchoring proteins (AKAPs) and facilitate the localization of PKA in specific subcellular compartments (7, 8). More than 50 AKAP family members have been described, and although most of these have a higher affinity for the RII subunits (9), certain AKAPs such as D-AKAP1 and D-AKAP2 preferentially bind the PKARIα subunit (10–12). Because the AKAPs also bind other signaling molecules such as phosphatases (PP2B) and kinases (protein kinase C), they act as scaffolds to organize and integrate specific signaling events within specific compartments in the cells (7, 8, 13, 14).We have shown that the PKARIα and PKAcα subunits of PKA interact with the inactive and active forms of p90^RSK1 (RSK1), respectively (15). Binding of inactive RSK1 to PKARIα decreases the interactions between PKARIα and PKAc, whereas the association of active RSK1 with PKAc increases interactions between PKARIα and PKAc such that larger amounts of cAMP are required to activate PKAc in the presence of active RSK1 (15). Moreover, the indirect (via subunits of PKA) interaction of RSK1 with AKAPs is required for the nuclear localization of active RSK1 (15), and disruption of the interactions of RSK1·PKA complex from AKAPs results in increased cytoplasmic distribution of active RSK1 with a concomitant increase in phosphorylation of its cytosolic substrates such as BAD and reduced cellular apoptosis (15). These findings show the functional and biological significance of RSK1·PKA·AKAP interactions.Besides inhibiting PKAc activity, the physiological role of PKARIα is underscored by the findings that mutations in the PKAR1A gene that result in haploinsufficiency of PKARIα are the underlying cause of Carney complex (CNC) (16, 17). CNC is an autosomal dominant multiple neoplasia syndrome in which myxomas of the skin, heart, and/or vicera are recurrent and also associated with high incidence of endocrine and ovarian tumors as well as Schwannomas (18–20). The majority of patients with the multiple neoplasia CNC syndrome harbor mutations in the PKAR1A gene (21) that result in PKARIα haploinsufficiency. Importantly, however, loss of heterozygosity or alterations in PKA activity may not contribute toward the tumorigenicity in either CNC patients or mouse model of CNC (21). This suggests that loss of function(s) of PKARIα other than inhibition of PKA activity is(are) involved in the enhanced tumorigenicity in CNC patients and in the murine CNC model.Because RSK1 regulates cell growth, survival, and tumorigenesis (22–27), and because its subcellular localization and ability to inhibit apoptosis is regulated by its interactions via PKARIα with AKAPs (15), we reasoned that in conditions such as CNC where PKARIα levels are decreased, the increase in tumorigenicity may emanate from aberrant regulation of the activity and/or subcellular localization of RSK1. Therefore, herein we have investigated whether PKARIα regulates the activation of RSK1 and its biological functions. Decreasing expression of PKARIα by small interfering RNA (siRNA) enhanced the activation of RSK1, but not RSK2 or RSK3, in the absence of an agonist such as EGF. This was accompanied by an increase in the cytoplasmic localization of the active RSK1 and enhanced cell survival in the absence of any growth factor. Silencing of PKARIα also increased PKAc activity and while part of the anti-apoptotic response could be attributed to an increase in PKAc activity, activation of RSK1 under basal conditions contributed significantly to cell survival. The elevation in RSK1 activity upon PKARIα silencing was not due to increased PKAc activity. Rather the activation of RSK1 in the absence of PKARIα was due to a decrease in PP2A in the RSK1 complex. These findings demonstrate a novel role for PKARIα in the regulation of RSK1 activation, a key enzyme that mediates the downstream actions of the ERK1/2 cascade.     

Protein Kinase Cα Isoform Regulates the Activation of the MAP Kinase ERK1/2 in Human Glioma Cells: Involvement in Cell Survival and Gene Expression

Protein kinase C is a family of serine/threonine protein kinases involved in many cellular responses, including cell survival and apoptosis. We have recently found that specific inhibition of the PKCα isoform by nucleic acid enzymes induced apoptosis in sensitive cells. Here we show that in PKCα DNA enzyme-treated glioma cells the activation of MAP kinases ERK1/2 is inhibited, whereas their total level was not significantly affected by the treatment. Similar results were obtained when the overall activity of the PKC was inhibited by calphostin, a specific inhibitor for PKC. These results would indicate that the ERK1/2 signaling pathway plays an important role in glioma cell survival and that the PKCα isoform is the main modulator of this pathway. Furthermore, we show that the ERK1/2 signaling pathway is required for the constitutive expression of the basic fibroblast growth factor, a potent mitogen for glioma cell growth.     

Distribution of Water Channel Protein RWC3 and Its Regulation by GA and Sucrose in Rice （Oryza sativa）

Water channel proteins facilitate water flux across cell membranes and play important roles in plant growth and development. By GUS histochemical assay in RWC3 promoter-GUS transgenic rice (Oryza sativa L. cv. Shenxiangjin 4), one of the members of water channel proteins in rice, RWC3, was found to distribute widely in variety of organs, from vegetative and reproductive organs. Further studies showed that gibberellin (GA) enhanced the GUS activity in the transgenic calli, suspension cells and leaves, whereas ancymidol (anc), an inhibitor of GA synthesis, reduced the GUS activity. Sucrose was found to inhibit the effects induced by addition of GA, suggesting a possible cross-talk between GA and sucrose signaling on regulation of the RWC3 gene expression.     

Protein Kinase Cα (PKCα) Regulates p53 Localization and Melanoma Cell Survival Downstream of Integrin αv in Three-dimensional Collagen and in Vivo

Protein kinase C α (PKCα) is overexpressed in numerous types of cancer. Importantly, PKCα has been linked to metastasis of malignant melanoma in patients. However, it has been unclear how PKCα may be regulated and how it exerts its role in melanoma. Here, we identified a role for PKCα in melanoma cell survival in a three-dimensional collagen model mimicking the in vivo pathophysiology of the dermis. A pathway was identified that involved integrin αv-mediated up-regulation of PKCα and PKCα-dependent regulation of p53 localization, which was connected to melanoma cell survival. Melanoma survival and growth in three-dimensional microenvironments requires the expression of integrin αv, which acts to suppress p53 activity. Interestingly, microarray analysis revealed that PKCα was up-regulated by integrin αv in a three-dimensional microenvironment-dependent manner. Integrin αv was observed to promote a relocalization of endogenous p53 from the nucleus to the cytoplasm upon growth in three-dimensional collagen as well as in vivo, whereas stable knockdown of PKCα inhibited the integrin αv-mediated relocalization of p53. Importantly, knockdown of PKCα also promoted apoptosis in three-dimensional collagen and in vivo, resulting in reduced tumor growth. This indicates that PKCα constitutes a crucial component of the integrin αv-mediated pathway(s) that promote p53 relocalization and melanoma survival.     

The Role of β Cell Glucagon-like Peptide-1 Signaling in Glucose Regulation and Response to Diabetes Drugs

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Expression of HIF-1α and Its Target Genes in the Nanorana parkeri Heart:Implications for High Altitude Adaptation

Hypoxia-inducible factor 1 alpha(HIF-1α) and its target genes vascular endothelial growth factor(VEGF) and transferrins(TF) play an important role in native endothermic animals' adaptation to the high altitude environments. For ectothermic animals – especially frogs – it remains undetermined whether HIF-1α and its target genes(VEGF and TF) play an important role in high altitude adaptation, too. In this study, we compared the gene sequences and expression of HIF-1α and its target genes(VEGF and TF) between three Nanorana parkeri populations from different altitudes(3008 m a.s.l., 3440 m a.s.l. and 4312 m a.s.l.). We observed that the c DNA sequences of HIF-1A exhibited high sequence similarity(99.38%) among the three altitudinally separated populations; but with increasing altitude, the expression of HIF-1A and its target genes(VEGF and TF) increased significantly. These results indicate that HIF-1α plays an important role in N. parkeri adaptation to the high altitude, similar to its role in endothermic animals.     

The Phosphoinositide 3-Kinase p110α Isoform Regulates Leukemia Inhibitory Factor Receptor Expression via c-Myc and miR-125b to Promote Cell Proliferation in Medulloblastoma

Medulloblastoma (MB) is the most common malignant brain tumor in childhood and represents the main cause of cancer-related death in this age group. The phosphoinositide 3-kinase (PI3K) pathway has been shown to play an important role in the regulation of medulloblastoma cell survival and proliferation, but the molecular mechanisms and downstream effectors underlying PI3K signaling still remain elusive. The impact of RNA interference (RNAi)-mediated silencing of PI3K isoforms p110α and p110δ on global gene expression was investigated by DNA microarray analysis in medulloblastoma cell lines. A subset of genes with selectively altered expression upon p110α silencing in comparison to silencing of the closely related p110δ isoform was revealed. Among these genes, the leukemia inhibitory factor receptor α (LIFR α) was validated as a novel p110α target in medulloblastoma. A network involving c-Myc and miR-125b was shown to be involved in the control of LIFRα expression downstream of p110α. Targeting the LIFRα by RNAi, or by using neutralizing reagents impaired medulloblastoma cell proliferation in vitro and induced a tumor volume reduction in vivo. An analysis of primary tumors revealed that LIFRα and p110α expression were elevated in the sonic hedgehog (SHH) subgroup of medulloblastoma, indicating its clinical relevance. Together, these data reveal a novel molecular signaling network, in which PI3K isoform p110α controls the expression of LIFRα via c-Myc and miR-125b to promote MB cell proliferation.     

Pin1 modulates p63α protein stability in regulation of cell survival,proliferation and tumor formation

The homolog of p53 gene, p63, encodes multiple p63 protein isoforms. TAp63 proteins contain an N-terminal transactivation domain similar to that of p53 and function as tumor suppressors; whereas ΔNp63 isoforms, which lack the intact N-terminal transactivation domain, are associated with human tumorigenesis. Accumulating evidence demonstrating the important roles of p63 in development and cancer development, the regulation of p63 proteins, however, is not fully understood. In this study, we show that peptidyl-prolyl isomerase Pin1 directly binds to and stabilizes TAp63α and ΔNp63α via inhibiting the proteasomal degradation mediated by E3 ligase WWP1. We further show that Pin1 specifically interacts with T₅₃₈P which is adjacent to the P₅₅₀PxY₅₄₃ motif, and disrupts p63α–WWP1 interaction. In addition, while Pin1 enhances TAp63α-mediated apoptosis, it promotes ΔNp63α-induced cell proliferation. Furthermore, knockdown of Pin1 in FaDu cells inhibits tumor formation in nude mice, which is rescued by simultaneous knockdown of WWP1 or ectopic expression of ΔNp63α. Moreover, overexpression of Pin1 correlates with increased expression of ΔNp63α in human oral squamous cell carcinoma samples. Together, these results suggest that Pin1-mediated modulation of ΔNp63α may have a causative role in tumorigenesis.     

The Antagonistic Actions of Endogenous Interleukin-1β and 15-Deoxy-{Delta}12,14-prostaglandin J2 Regulate the Temporal Synthesis of Matrix Metalloproteinase-9 in Sheared Chondrocytes

Mechanical overloading of articular cartilage producing hydrostatic stress, tensile strain, and fluid flow results in irreversible cartilage erosion and osteoarthritis (OA). Application of high fluid shear to chondrocytes recapitulates the earmarks of OA as evidenced by the induction of proinflammatory cytokines and prostaglandins, which are capable of inducing the expression of matrix-degrading enzymes. Matrix metalloproteinase-9 (MMP-9) synthesis is detected at early but not late stages of OA. However, the underlying mechanism(s) of the MMP-9 temporal regulation remains unknown. Using the T/C-28a2 chondrocyte cell line as a model system, we demonstrated that high fluid shear induces a marked increase in MMP-9 expression at short shear exposure times (3-6 h), which falls below basal levels after prolonged shear exposure (12-48 h). High fluid shear stress induced the rapid and sustained synthesis of IL-1β, activating PI3K, ERK1/2, and JNK, which are in turn responsible for MMP-9 expression. Prolonged shear exposure (>12 h) induced 15-deoxy-Δ(12,14)-prostaglandin J(2) (15d-PGJ(2)) synthesis, which exerted an antagonistic effect on IL-1β-mediated PI3K-, ERK1/2-, and JNK-dependent NF-κB activation, thereby suppressing MMP-9 expression in human chondrocytes. Reconstructing the signaling network that regulates shear-mediated MMP-9 expression in human chondrocytes may provide insights for developing strategies to treat arthritic disorders.