Charles S. Rubin

Regulation of cAMP-mediated Signal Transduction via Interaction of Caveolins with the Catalytic Subunit of Protein Kinase A

cAMP-dependent processes are essential for cell growth, differentiation, and homeostasis. The classic components of this system include the serpentine receptors, heterotrimeric G-proteins, adenylyl cyclase, protein kinase A (PKA), and numerous downstream target substrates. Evidence is accumulating that some members of this cascade are concentrated within membrane microdomains, termed caveolae and caveolae-related domains. In addition, the caveolin-1 protein has been shown to interact with some of these components, and this interaction inhibits their enzymatic activity. However, the functional effects of caveolins on cAMP-mediated signaling at the most pivotal step, PKA activation, remain unknown. Here, we show that caveolin-1 can dramatically inhibit cAMP-dependent signaling in vivo. We provide evidence for a direct interaction between caveolin-1 and the catalytic subunit of PKA both in vitro and in vivo. Caveolin-1 binding appears to be mediated both by the caveolin scaffolding domain (residues 82–101) and a portion of the C-terminal domain (residues 135–156). Further functional analysis indicates that caveolin-based peptides derived from these binding regions can inhibit the catalytic activity of purified PKA in vitro. Mutational analysis of the caveolin scaffolding domain reveals that a series of aromatic residues within the caveolin scaffolding domain are critical for mediating inhibition of PKA. In addition, co-expression of caveolin-1 and PKA in cultured cells results in their co-localization as seen by immunofluorescence microscopy. In cells co-expressing caveolin-1 and PKA, PKA assumed a punctate distribution that coincided with the distribution of caveolin-1. In contrast, in cells expressing PKA alone, PKA was localized throughout the cytoplasm and yielded a diffuse staining pattern. Taken together, our results suggest that the direct inhibition of PKA by caveolin-1 is an important and previously unrecognized mechanism for modulating cAMP-mediated signaling.

Organelle-specific Targeting of Protein Kinase AII (PKAII) MOLECULAR AND IN SITU CHARACTERIZATION OF MURINE A KINASE ANCHOR PROTEINS THAT RECRUIT REGULATORY SUBUNITS OF PKAII TO THE CYTOPLASMIC SURFACE OF MITOCHONDRIA

Experiments were designed to test the idea that A kinase anchor proteins (AKAPs) tether regulatory subunits (RII) of protein kinase AII (PKAII) isoforms to surfaces of organelles that are bounded by phospholipid bilayers. S-AKAP84, one of three RII-binding proteins encoded by a single-copy murine gene, was studied as a prototypic organelle-associated AKAP. When S-AKAP84 was expressed in HEK293 cells, the anchor protein was targeted to mitochondria and excluded from other cell compartments. The RII tethering site is located in the cytoplasm adjacent to the mitochondrial surface. Endogenous RII subunits are not associated with mitochondria isolated from control cells. Expression of S-AKAP84 in transfected HEK293 cells triggered a redistribution of 15% of total RII to mitochondria. Thus, the tethering region of the organelle-inserted anchor protein is properly oriented and avidly binds RII (PKAII) isoforms in intact cells. Two critical domains in S-AKAP84 were mapped. Residues 1 to 30 govern insertion of the polypeptide into the outer mitochondrial membrane; amino acids 306–325 constitute the RII-binding site. Properties established for S-AKAP84 in vitro and in situ strongly suggest that a physiological function of this protein is to concentrate and immobilize RII (PKAII) isoforms at the cytoplasmic face of a phospholipid bilayer.

Molecular Characterization of an Anchor Protein (AKAPCE) That Binds the RI Subunit (RCE) of Type I Protein Kinase A from Caenorhabditis elegans

Classical A kinase anchor proteins (AKAPs) preferentially tether type II protein kinase A (PKAII) isoforms to sites in the cytoskeleton and organelles. It is not known if distinct proteins selectively sequester regulatory (R) subunits of type I PKAs, thereby diversifying functions of these critical enzymes. InCaenorhabditis elegans, a single type I PKA mediates all aspects of cAMP signaling. We have discovered a cDNA that encodes a binding protein (AKAPCE) for the regulatory subunit (RCE) of C. elegans PKAICE. AKAPCE is a novel, highly acidic RING finger protein composed of 1,280 amino acids. It binds RI-like RCE with high affinity and neither RIIα nor RIIβ competitively inhibits formation of AKAPCE·RCE complexes. The RCE-binding site was mapped to a segment of 20 amino acids in an N-terminal region of AKAPCE. Several hydrophobic residues in the binding site align with essential Leu and Ile residues in the RII-selective tethering domain of prototypic mammalian AKAPs. However, the RCE-binding region in AKAPCEdiverges sharply from consensus RII-binding sites by inclusion of three aromatic amino acids, exclusion of a highly conserved Leu or Ile at position 8 and replacement of C-terminal hydrophobic amino acids with basic residues. AKAPCE·RCE complexes accumulate in intact cells.

Regulation of Cytoskeleton Organization and Paxillin Dephosphorylation by cAMP STUDIES ON MURINE Y1 ADRENAL CELLS

Cyclic AMP induces corticosteroid production, differential gene transcription, and cell cycle arrest in adrenal cortex-derived Y1 cells. These responses follow a cAMP-controlled transformation in Y1 cell morphology: the conversion of flat epithelial cells into rounded, highly refractile cells with short processes. Little is known about effector proteins and mechanisms that link activated protein kinase A to the alteration in cell shape. We now report that cAMP causes rapid (≤1 min) and selective tyrosine dephosphorylation of paxillin, a focal adhesion protein. Paxillin is maximally dephosphorylated before other physiological effects of cAMP are detected in Y1 cells. Dephosphopaxillin translocates from focal adhesions to the cytoplasm as stress fibers vanish and F-actin accumulates in membrane ruffles and cytoplasmic aggregates. Remnants of focal adhesion complexes dissociate from the cell cortex and coalesce into large structures that contain aggregated F-actin. Pervanadate, an inhibitor of protein-tyrosine phosphatases, abrogates all effects of cAMP. Conversely, genistein-sensitive protein-tyrosine kinase activity is essential for establishing epithelial morphology and reversing effects of cAMP in Y1 cells. Thus, cAMP/protein kinase A (PKA) actions are initially targeted to focal adhesions and cortical actin cytoskeleton; paxillin is an early and unexpected downstream target in a PKA-mediated signaling pathway, and protein-tyrosine phosphatase activity provides an essential link between PKA activation and the control of cell shape.

Structure and Expression of Novel Spliced Leader RNA Genes in Caenorhabditis elegans

Approximately 25% of Caenorhabditis elegans genes are organized as operons. Polycistronic transcripts are converted to monocistronic mRNAs by 3′ cleavage/polyadenylation and 5′ trans-splicing with untranslated, 5′-terminal exons called spliced leaders, (SLs). The 5′ termini of mRNAs encoded by downstream genes in operons are acceptors for ≥7 recently discovered “novel” SLs and a classical SL (SL2). Diversity in SL exons is now partly explained by the discovery and characterization of five novel genes that encode C. elegans SL RNAs. These novel SL RNAs contain a 22- or 23-nucleotide SL followed by conserved splice donor and downstream sequences that are essential for catalysis of trans-splicing reactions. The SL3α, SL4, and SL5 RNA genes are tightly clustered on chromosome III; their 114-nucleotide transcripts deliver three distinct SLs to mRNAs. The SL3β and SL3γ RNA genes are on chromosome I, but are not tightly linked. SL RNAs 3α, 3β, and 3γ provide identical 5′ leader exons, although their 3′ sequences diverge. Transcription of SL 3-5 RNA genes appears to be driven by flanking DNA elements that are homologous with segments of promoters for the C. elegans SL2 RNA and small nuclear RNA genes. RNase protection assays demonstrated that novel SL RNAs are transcribed in vivo and accumulate in the poly(A−) RNA pool. SL3 exons are transferred to mRNAs as frequently as SL2 exons. In contrast, SL4 is appended to mRNAs 10% as frequently as SL3. The abundance of SL4 RNA increased 6-fold during postembryonic development, and the SL4 RNA gene promoter is active principally in hypodermal cells.

The role of cyclic AMP in the phosphorylation of proteins in human erythrocyte membranes

Abstract Three protein components of human erythrocyte membranes served as substrates for membrane-bound protein kinase. Cyclic AMP stimulated the rates of phosphorylation of two polypeptides, but the phosphorylation of the principal phosphate-acceptor was not enhanced by the cyclic nucleotide. These observations demonstrate the presence of cyclic AMP-dependent protein kinase and its homologous substrates in erythrocyte membranes and suggest that cyclic AMP could mediate alterations in the properties of membranes.

A Kinase Anchor Protein 75 Targets Regulatory (RII) Subunits of cAMP-dependent Protein Kinase II to the Cortical Actin Cytoskeleton in Non-neuronal Cells

Neuronal A kinase anchor protein (AKAP) homologs, such as AKAPs 75 and 150, tether cAMP-dependent protein kinase II (PKAII) isoforms to the postsynaptic cytoskeleton, thereby creating target sites for cAMP action. These AKAPs, which bind regulatory subunits (RIIs) of PKAII, are also expressed in certain non-neuronal cells. Non-neuronal cell lines that stably express wild type and mutant AKAP75 transgenes were generated to investigate the extraneuronal function of AKAPs. In non-neuronal cells, AKAP75 accumulates selectively in the actin-rich, cortical cytoskeleton in close proximity with the plasma membrane. AKAP75 efficiently sequesters cytoplasmic RIIα and RIIβ (PKAII isoforms) and translocates these polypeptides to the cell cortex. Two structural modules in AKAP75, T1 (residues 27-48), and T2 (residues 77-100), are essential for targeting AKAP75·RII complexes to the cortical cytoskeleton. Deletions or amino acid substitutions in T1 and/or T2 result in the dispersion of both AKAP75 and RII subunits throughout the cytoplasm. AKAP75 is co-localized with F-actin and fodrin in the cortical cytoskeleton. Incubation of cells with 5 μM cytochalasin D disrupts actin filaments and dissociates actin from the cell cortex. In contrast, the bulk of AKAP75 and fodrin remain associated with the cortical region of cytochalasin D-treated cells. Thus, targeting of AKAP75 does not depend upon direct binding with F-actin. Rather, AKAP75 (like fodrin) may be associated with a multiprotein complex that interacts with integral plasma membrane proteins.

Protein kinase D: Coupling extracellular stimuli to the regulation of cell physiology

Protein kinase D (PKD) mediates the actions of stimuli that promote diacylglycerol (DAG) biogenesis. By phosphorylating effectors that regulate transcription, fission and polarized transport of Golgi vesicles, as well as cell migration and survival after oxidative stress, PKDs substantially expand the range of physiological processes controlled by DAG. Dysregulated PKDs have been linked to pathologies including heart hypertrophy and cancer invasiveness. Our understanding of PKD regulation by trans‐ and autophosphorylation, as well as the subcellular dynamics of PKD substrate phosphorylation, have increased markedly. Selective PKD inhibitors provide new, powerful tools for elucidating the physiological roles of PKDs and potentially treating cardiac disease and cancer.

Molecular Characterization of a cDNA That Encodes Six Isoforms of a Novel Murine A Kinase Anchor Protein

We have cloned cDNA that encodes six novel A kinase anchor proteins (collectively named AKAP-KL). AKAP-KL diversity is generated by alternative mRNA splicing and utilization of two translation initiation codons. AKAP-KL polypeptides are evident in lung, kidney, and cerebellum, but are absent from many tissues. Different isoforms predominate in different tissues. Thus, AKAP-KL expression is differentially regulated in vivo. All AKAP-KL isoforms contain a 20-residue domain that avidly binds (K d ∼ 10 nm) regulatory subunits (RII) of protein kinase AII and is highly homologous with the RII tethering site in neuronal AKAP75. The distribution of AKAP-KL is strikingly asymmetric (polarized) in situ. Anchor protein accumulates near the inner, apical surface of highly polarized epithelium in tubules of nephrons. Both RII and AKAP-KL are enriched at an intracellular site that lies just below the plasma membrane of alveolar epithelial cells in lung. AKAP-KL interacts with and modulates the structure of the actin cytoskeleton in transfected cells. We also demonstrate that the tethering domain of AKAP-KL avidly ligates RII subunits in intact cells. AKAP-KL may be involved in (a) establishing polarity in signaling systems and (b) physically and functionally integrating PKAII isoforms with downstream effectors to capture, amplify, and precisely focus diffuse, trans-cellular signals carried by cAMP.

A-kinase anchor protein 75 increases the rate and magnitude of cAMP signaling to the nucleus

A-kinase anchor protein 75 (AKAP75) binds regulatory subunits (RIIalpha and RIIbeta) of type II protein kinase A (PKAII) isoforms and targets the resulting complexes to sites in the cytoskeleton that abut the plasma membrane [1-7]. Co-localization of AKAP75-PKAII with adenylate cyclase and PKA substrate/effector proteins in cytoskeleton and plasma membrane effects a physical and functional integration of up-stream and downstream signaling proteins, thereby ensuring efficient propagation of signals carried by locally generated cyclic AMP (cAMP) [4-9]. An important, but previously untested, prediction of the AKAP model is that efficient, cyclic nucleotide-dependent liberation of diffusible PKA catalytic subunits from cytoskeleton-bound AKAP75-PKAII complexes will also enhance signaling to distal organelles, such as the nucleus. We tested this idea by suing HEK-A75 cells, in which PKAII isoforms are immobilized in cortical cytoskeleton by AKAP75. Abilities of HEK-A75 and control cells (with cytoplasmically dispersed PKAII isoforms) to respond to increases in cAMP content were compared. Cells with anchored PKAII exhibited a threefold higher level of nuclear catalytic subunit content and 4-10-fold greater increments in phosphorylation of a regulatory serine residue in cAMP response element binding protein (CREB) and in phosphoCREB-stimulated transcription of the c-fos gene. Each effect occurred more rapidly in cells containing targeted AKAP75-PKAII complexes. Thus, anchoring of PKAII in actin cortical cytoskeleton increases the rate, magnitude and sensitivity of cAMP signaling to the nucleus.