Receptor for activated C kinase (RACK) and protein kinase C (PKC) in egg activation

In somatic cells, translocation of PKCs is facilitated by receptor for activated C kinase (RACK); however its involvement in egg activation is still elusive. We have followed the translocation pattern of conventional and novel PKCs (cPKCs and nPKCs, respectively) upon egg activation. Confocal microscopy indicated the expression and localization of RACK1, a specific receptor protein for cPKCs. Activation of MII eggs, led to translocation to the egg cortex of PKCα, βII and δ and the co-translocation of RACK1, with both PKCα and PKCβII. The association of PKC and actin, both known to be involved in cortical granules exocytosis (CGE) with RACK1, was demonstrated by co-immunoprecipitation. Egg activation resulted in an increased RACK1 level along with a decreased level of PKCβII. Based on these results, we suggest that upon egg activation, RACK1 shuttles activated cPKCs to the egg cortex, thus facilitating CGE.     

Protein kinase C beta (PKC beta): normal functions and diseases

PKC beta I and PKC beta II are DAG- and Ca(2+)-dependent conventional or classical isoforms of protein kinase C. Generated by alternative splicing from a single gene, they differ at their C-terminal 50 (beta I) or 52 (beta II) residues. They are expressed as major PKC isoforms in a variety of tissues, and thus the functions ascribed to "PKC" based on early studies using phorbol esters and PKC inhibitors could be attributed to them. As tools to probe into isoform-specific functions have recently become available, our understanding of the normal functions of these isoforms has dramatically increased. This minireview will focus mainly on two areas of signal transduction where the roles of PKC beta I and PKC beta II are relatively well-characterized: immunoreceptor and insulin receptor systems. Their involvement in disorders due to pertubations in these signaling systems, i.e., immunodeficiencies and diabetes, is also reviewed. Finally, patterns of PKC action in these and other biologic systems are discussed.     

Role of protein kinase C (PKC) in bone resorption: effect of the specific PKC inhibitor 1-alkyl-2-methylglycerol.

The specific inhibitor of protein kinase C, 1-O-alkyl-2-O-methylglycerol (AMG), was studied for its effect on bone resorption, measured as 45Ca-release, in fetal mouse calvariae. AMG (1 to 50 microM) had no effect on basal bone resorption. AMG inhibited parathyroid hormone (40 nM) induced bone resorption in a dose-dependent manner. Resorption induced by 1,25 (OH)2-vitamin D3 (10 nM) or prostaglandin E2 (5 microM) was also inhibited by AMG. The release of beta-glucuronidase activity paralleled the course of the 45Ca-release. The production of interleukin 6, induced by parathyroid hormone, in fetal rat calvarial osteoblasts was not affected by AMG. AMG (1 to 50 microM) had no cytotoxic effects on cells or calvariae. From these results it is concluded that protein kinase C may have an important role in the regulation of bone resorption.     

Plectin-RACK1 (receptor for activated C kinase 1) scaffolding: a novel mechanism to regulate protein kinase C activity

Agonist-induced translocation of protein kinase C (PKC) isozymes is mediated by receptors for the activated form of the kinase, shuttling it from one intracellular site to another and enhancing its catalytic activity. It is however unknown whether the receptors themselves are anchored to certain intracellular structures prior to their engagement with PKC. We show here sequestering of receptor for activated C kinase 1 (RACK1) to the cytoskeleton through the cytoskeletal linker protein plectin during the initial stages of cell adhesion. We found that upon PKC activation, RACK1 was released from the cytoskeleton and transferred to the detergent-soluble cell compartment, where it formed an inducible triple complex with one of the PKC isozymes, PKCdelta, and with plectin. In plectin-deficient cells the cytoskeleton-associated RACK1 fraction was reduced, and the protein was found predominantly at sites to which it normally translocated upon PKC activation. Concomitantly, dislocation of PKCdelta and elevated enzymatic activity were observed in these cells. PKCdelta was also more rapidly degraded, likely due to its overactivation. We propose a previously unrecognized function of plectin as cytoskeletal regulator of PKC signaling, and possibly other signaling events, through sequestration of the scaffolding protein RACK1.     

Specific and dual antagonists of alpha(4)beta(1) and alpha(4)beta(7) integrins.

N-(3,5-Dichlorophenylsulfonyl)-(R)-thioprolyl biarylalanine 10a has been identified as a potent and specific antagonist of the alpha(4)beta(1) integrin. Altering the configuration of thioproline from R to S led to a series of dual antagonists of alpha(4)beta(1) and alpha(4)beta(7), and the N-acetyl analogue 8b was found to be the most potent dual antagonist. A binding site model for alpha(4)beta(1) and alpha(4)beta(7) is proposed to explain the structure-activity relationship.     

Protein kinase C gamma (PKC gamma): function of neuron specific isotype

The gamma isotype of protein kinase C (PKC gamma) is a member of the classical PKC (cPKC) subfamily which is activated by Ca(2+) and diacylglycerol in the presence of phosphatidylserine. Physiologically, PKC gamma is activated by a mechanism coupled with receptor-mediated breakdown of inositol phospholipid as other cPKC isotypes such as PKC alpha and PKC beta. PKC gamma is expressed solely in the brain and spinal cord and its localization is restricted to neurons, while PKC alpha and PKC beta are expressed in many tissues in addition to the brain. Within the brain, PKC gamma is the most abundant in the cerebellum, hippocampus and cerebral cortex, where the existence of neuronal plasticity has been demonstrated. Pharmacological and electrophysiological studies have shown that several neuronal functions, including long term potentiation (LTP) and long term depression (LTD), specifically require PKC gamma. Generation of mice deficient in PKC gamma provided more information regarding the physiological functions of this isotype. PKC gamma deficient mice (i) have modified long term potentiation (LTP) in hippocampus, (ii) exhibit mild deficits in spatial and contextual learning (iii) exhibit impaired motor coordination due to persistent multiple innervations of climbing fibers on Purkinje cells, (iv) show attenuation of opioid receptor activation, and (v) show decreased effects of ethanol on type A of gamma-aminobutyric acid (GABA) receptor. Furthermore, a point mutation in the PKC gamma gene may contribute to retinitis pigmentosa and Parkinsonian syndrome. This article reviews the specific functions of this neuron-specific isotype of PKC in neuronal signal transduction.     

Identification of proteins that associate with protein kinase CK2

In order to aid in an understanding of the cellular functions of protein kinase CK2, a search for interacting proteins was carried out using a 32P-labeled CK2 overlay method. Several proteins were found to associate with CK2 by this assay; among them, one protein of 110 kDa appeared to be the most prominent one. The possible association of CK2 with p110 was suggested by experiments involving the co-immunoprecipitation using anti-CK2 antibodies. Further analysis using GST-CK2 fusion proteins demonstrated that the CK2-p110 interaction occurred through the CK2/ subunits. To identify p110, it was purified using a GST-CK2 affinity column, and internal amino acid sequencing was then performed. p110 was found to be nucleolin, a nucleolar protein that may be important for rRNA synthesis; a possible role of CK2 in the control of this process is suggested. Using the same CK2 overlay technique, another interacting protein, insulin receptor substrate 1 (IRS-1), was also identified. By applying a modified overlay method using individual 35S-labeled CK2 subunits, obtained by in vitro translation in rabbit reticulate lysates, it was determined that CK2 associates with IRS-1 through its / subunits; i.e. in keeping with the fact that IRS-1 is a known substrate for CK2. However, further work is needed to examine the association of CK2 with IRS-1 in vivo in order to fully understand the significance of the interaction.     

Role of specific protein kinase C isoforms in modulation of beta1- and beta2-adrenergic receptors

The function of beta-adrenergic receptor (betaAR) is modulated by the activity status of alpha1-adrenergic receptors (alpha1ARs) via molecular crosstalk, and this becomes evident when measuring cardiac contractile responses to adrenergic stimulation. The molecular mechanism underlying this crosstalk is unknown. We have previously demonstrated that overexpression of alpha1B-adrenergic receptor (alpha1BAR) in transgenic mice leads to a marked desensitization of betaAR-mediated adenylyl cyclase stimulation which is correlated with increased levels of activated protein kinase C (PKC) beta, delta and [J. Mol. Cell. Cardiol. 30 (1998) 1827]. Therefore, we wished to determine which PKC isoforms play a role in heterologous betaAR desensitization and also which isoforms of the betaAR were the molecular target(s) for PKC. In experiments using constitutively activated PKC expression constructs transfected into HEK 293 cells also expressing the beta2AR, constitutively active (CA)-PKC overexpression was first confirmed by immunoblots using specific anti-PKC antibodies. We then demonstrated that the different PKC subtypes lead to a decreased maximal cAMP accumulation following isoproterenol stimulation with a rank order of PKCalpha > or = PKCzeta>PKC>PKCbetaII. However, a much more dramatic desensitization of adenylyl cyclase stimulation was observed in cells co-transfected with different PKC isoforms and beta1AR. Further, the modulation of beta1AR by PKC isoforms had a different rank order than for the beta2AR: PKCbetaII>PKCalpha>PKC>PKCzeta. PKC-mediated desensitization was reduced by mutating consensus cAMP-dependent protein kinase (PKA)/PKC sites in the third intracellular loop and/or the carboxy-terminal tail of either receptor. Our results demonstrate therefore that the beta1AR is the most likely molecular target for PKC-mediated heterologous desensitization in the mammalian heart and that modulation of adrenergic receptor activity in any given cell type will depend on the complement of PKC isoforms present.     

Focal adhesion kinase activated by beta(4) integrin ligation to mCLCA1 mediates early metastatic growth

Early metastatic growth occurs at sites of vascular arrest of blood-borne cancer cells and is entirely intravascular. Here we show that lung colonization by B16-F10 cells is licensed by beta(4) integrin adhesion to the mouse lung endothelial Ca(2+)-activated chloride channel protein mCLCA1. In a manner independent of Met, beta(4) integrin-mCLCA1-ligation leads to complexing with and activation of focal adhesion kinase (FAK) and downstream signaling to extracellular signal-regulated kinase (ERK). FAK/ERK signaling is Src-dependent and is interrupted by adhesion blocking antibodies and by dominant-negative (dn)-FAK mutants. Levels of ERK activation in B16-F10 cells transfected with wild-type or mutant FAK are closely associated with rates of proliferation and bromodeoxyuridine (BrdUrd) incorporation of tumor cells grown in mCLCA1-coated dishes, the ability to form tumor cell colonies on CLCA-expressing endothelial cell monolayers, and the extent of pulmonary metastatic growth. Parallel with the transfection rates, B16-F10 cells transfected with dn-FAK mutants and injected intravenously into syngeneic mice generate approximately half the number and size of lung colonies that vector-transfected B16-F10 cells produce. For the first time, beta(4) integrin ligation to its novel CLCA-adhesion partner is shown to be associated with FAK complexing, activation, and signaling to promote early, intravascular, metastatic growth.