Signal transduction and protein phosphorylation in smooth muscle contraction

Smooth muscles are important constituents of vertebrate organisms that provide for contractile activity of internal organs and blood vessels. Basic molecular mechanism of both smooth and striated muscle contractility is the force-producing ATP-dependent interaction of the major contractile proteins, actin and myosin II molecular motor, activated upon elevation of the free intracellular Ca²⁺ concentration ([Ca²⁺]_i). However, whereas striated muscles display a proportionality of generated force to the [Ca²⁺]_i level, smooth muscles feature molecular mechanisms that modulate sensitivity of contractile machinery to [Ca²⁺]_i. Phosphorylation of proteins that regulate functional activity of actomyosin plays an essential role in these modulatory mechanisms. This provides an ability for smooth muscle to contract and maintain tension within a broad range of [Ca²⁺]_i and with a low energy cost, unavailable to a striated muscle. Detailed exploration of these mechanisms is required to understand the molecular organization and functioning of vertebrate contractile systems and for development of novel advances for treating cardiovascular and many other disorders. This review summarizes the currently known and hypothetical mechanisms involved in regulation of smooth muscle Ca²⁺-sensitivity with a special reference to phosphorylation of regulatory proteins of the contractile machinery as a means to modulate their activity.     

Signal transduction in the vomeronasal organ of garter snakes: ligand-receptor binding-mediated protein phosphorylation.

The vomeronasal (VN) system of garter snakes plays an important role in several species-typical behaviors, such as prey recognition and responding to courtship pheromones. We (X.C. Jiang et al., J. Biol. Chem. 265 (1990) 8736-8744 and Y. Luo et al., J. Biol. Chem. 269 (1994) 16867-16877) have demonstrated previously that in the snake VN sensory epithelium, the chemoattractant ES20, a 20-kDa glycoprotein derived from electric shock-induced earthworm secretion, binds to its receptor which is coupled to PTX-sensitive G-proteins. Such binding results in elevated levels of IP3. We now report that ES20-receptor binding regulates the phosphorylation of two membrane-bound proteins with molecular masses of 42- and 44-kDa (p42/44) in both intact and cell-free preparations of the VN sensory epithelium. ES20 and DAG regulate the phosphorylation of p42/44 in a similar manner. ES20-receptor binding-mediated phosphorylation of p42/44 is rapid and transient, reaching a peak value within 40 seconds and decaying thereafter. Phosphorylation of p42/44 appears to be regulated by the countervailing actions of a specific membrane-bound protein kinase and a protein phosphatase. The phosphorylation of these membrane-bound proteins significantly reduces the activity of G-proteins as evidenced by a decrease in GTPase activity, but has little effect on ligand-receptor binding. These findings suggest that p42/44 play a role in modulating the signal transduction induced by ES20 in the vomeronasal system.     

Signal transduction at a protein synapse

Contraction of the bacteriophage T4 tail in the act of host cell penetration represents a massive structural change powered by conformational free energy. A paper in this issue of Cell by compares cryo-electron microscopic reconstructions of the initial and final states and reveals that the basic underlying mechanism is concerted rigid-body movements of the constituent protein subunits, akin to the tumbling of gears in a lock.     

Phosphoinositides and protein phosphorylation in plant signal transduction

A highly complex set of interactions are responsible for the perception and transduction of signals in living cells. It is likely that a number of fundamental principles of signalling mechanisms are of early evolutionary origin, have been highly conserved and are shared by apparently disparate organisms. Possible clues to the biochemical and molecular basis of plant signalling might thus be obtained from research carried out on other eukaryotes. Like mammalian cells, plant cells have been found to possess a phosphoinositide system and also make extensive use of phosphorylation and dephosphorylation cascades. The potential role of these mechanisms in plant cell signalling is reviewed.     

Naringin-sensitive phosphorylation of plectin,a cytoskeletal cross-linking protein,in isolated rat hepatocytes

To identify phosphoproteins that might play a role in naringin-sensitive hepatocellular cytoskeletal disruption and apoptosis induced by algal toxins, hepatocyte extracts were separated by gel electrophoresis and immunostained with a phosphothreonine-directed antibody. Use of dilute (5%) polyacrylamide gels containing 6 m urea allowed the resolution of one very large (approximately 500-kDa) okadaic acid- and naringin-sensitive phosphoprotein, identified by tryptic fingerprinting, matrix-assisted laser desorption/ionization time-of-flight mass spectrometry, and immunostaining as the cytolinker protein, plectin. The naringin-sensitive phosphorylation induced by okadaic acid and microcystin-LR probably reflected inhibition of a type 2A protein phosphatase, whereas the naringin-resistant phosphorylation induced by calyculin A, tautomycin, and cantharidin probably involved a type 1 phosphatase. Okadaic acid caused a collapse of the plectin-immunostaining bile canalicular sheaths and the general cytoskeletal plectin network into numerous medium-sized plectin aggregates. Inhibitors of protein kinase C, cAMP-dependent protein kinase, or Ca(2+)/calmodulin-dependent kinase II had moderate or no protective effects on plectin network disruption, whereas naringin offered 86% protection. Okadaic acid induced a naringin-sensitive phosphorylation of AMP-activated protein kinase (AMPK), the stress-activated protein kinases SEK1 and JNK, and S6 kinase. The AMPK-activating kinase (AMPKK) is likely to be the target of inhibition by naringin, the other kinases serving as downstream components of an AMPKK-initiated signaling pathway.     

Signal transduction of bone morphogenetic protein receptors

Bone morphogenetic proteins (BMPs) play a crucial role during all stages of embryonic development. Although only two major signaling pathways have been characterized (the p38 and Smad pathways), the BMP signaling is complex and includes several negative feedback mechanisms. This article reviews the current state of BMP receptor signaling and provides a summary of the crosstalk of the BMP receptor pathway with other major signaling pathways.     

Signal transduction through the cAMP-dependent protein kinase

Molecular and Cellular Biochemistry - Temporal cellular events responsible for hormonal activation of responses mediated by the cAMP-dependent protein kinase (PKA) have been studied in living...     

Signal transduction: Gyrating protein kinases.

Recently determined structures have linked histidine kinases with class II topoisomerases, the DNA repair enzyme MutL and the molecular chaperone Hsp90. This surprising finding may foreshadow a shift in our understanding of energy coupling mechanisms in signal transduction networks.     

Involvement of altered cytoskeletal protein phosphorylation in aluminum-induced CNS dysfunction

In the present investigation, we have studied the effects of aluminum (10 mg/kg of body weight per day, i.p.) and desferrioxamine (6 mg/kg of body weight per day, i.p.) alone and in combination for 4 weeks on the regulation of phosphorylation of neuronal proteins. A marked decrease in the biological activity of calmodulin was observed after aluminum treatment; however, in combination with desferrioxamine, a reversal in the levels of calmodulin, in terms of nmol cAMP hydrolyzed/min/mg protein, was observed. Exogenous addition of calmodulin had an inhibitory effect on calmodulin-mediated synaptosomal protein phosphorylation in aluminum-exposed animals. An almost complete reversal of this inhibition was observed following coexposure to aluminum and desferrioxamine. Cyclic AMP-dependent synaptosomal protein phosphorylation was, however, stimulated following aluminum exposure. Coadministration of desferrioxamine along with aluminum was found to mitigate the neurotoxic effect of aluminum. © 1997 John Wiley & Sons, Inc.     

Role of protein phosphorylation in neuronal signal transduction

Protein phosphorylation is involved in the regulation of a wide variety of physiological processes in the nervous system. Studies in which purified protein kinases or kinase inhibitors have been microinjected into defined cells while a specific response is monitored have demonstrated that protein phosphorylation is both necessary and sufficient to mediate responses of excitable cells to extracellular signals. The precise molecular mechanisms involved in neuronal signal transduction processes can be further elucidated by identification and characterization of the substrate proteins for the various protein kinases. The roles of three such substrate proteins in signal transduction are described in this article: 1) synapsin I, whose phosphorylation increases neurotransmitter release and thereby modulates synaptic transmission presynaptically; 2) the nicotinic acetylcholine receptor, whose phosphorylation increases its rate of desensitization and thereby modulates synaptic transmission postsynaptically; and 3) DARPP-32, whose phosphorylation converts it to a protein phosphatase inhibitor and which thereby may mediate interactions between dopamine and other neurotransmitter systems. The characterization of the large number of additional phosphoproteins that have been found in the nervous system should elucidate many additional molecular mechanisms involved in signal transduction in neurons.     

Signal perception and transduction: the role of protein kinases

Cells can react to environmental changes by transduction of extracellular signals, to produce intracellular responses. Membrane-impermeable signal molecules are recognized by receptors, which are localized on the plasma membrane of the cell. Binding of a ligand can result in the stimulation of an intrinsic enzymatic activity of its receptor or the modulation of a transducing protein. The modulation of one or more intracellular transducing proteins can finally lead to the activation or inhibition of a so-called 'effector protein'. In many instances, this also results in altered gene expression. Phosphorylation by protein kinases is one of the most common and important regulatory mechanisms in signal transmission. This review discusses the non-channel transmembrane receptors and their downstream signaling, with special focus on the role of protein kinases.     

Signal processing by protein tyrosine phosphorylation in plants

Protein phosphorylation is a reversible post-translational modification controlling many biological processes. Most phosphorylation occurs on serine and threonine, and to a less extend on tyrosine (Tyr). In animals, Tyr phosphorylation is crucial for the regulation of many responses such as growth or differentiation. Only recently with the development of mass spectrometry, it has been reported that Tyr phosphorylation is as important in plants as in animals. The genes encoding protein Tyr kinases and protein Tyr phosphatases have been identified in the Arabidopsis thaliana genome. Putative substrates of these enzymes, and thus Tyr-phosphorylated proteins have been reported by proteomic studies based on accurate mass spectrometry analysis of the phosphopeptides and phosphoproteins. Biochemical approaches, pharmacology and genetic manipulations have indicated that responses to stress and developmental processes involve changes in protein Tyr phosphorylation. The aim of this review is to present an update on Tyr phosphorylation in plants in order to better assess the role of this post-translational modification in plant physiology.Key words: protein tyrosine phosphorylation, kinases, phosphatases, proteomics, mass spectrometry, signaling     

Signal sequence insufficiency contributes to neurodegeneration caused by transmembrane prion protein

Protein translocation into the endoplasmic reticulum is mediated by signal sequences that vary widely in primary structure. In vitro studies suggest that such signal sequence variations may correspond to subtly different functional properties. Whether comparable functional differences exist in vivo and are of sufficient magnitude to impact organism physiology is unknown. Here, we investigate this issue by analyzing in transgenic mice the impact of signal sequence efficiency for mammalian prion protein (PrP). We find that replacement of the average efficiency signal sequence of PrP with more efficient signals rescues mice from neurodegeneration caused by otherwise pathogenic PrP mutants in a downstream hydrophobic domain (HD). This effect is explained by the demonstration that efficient signal sequence function precludes generation of a cytosolically exposed, disease-causing transmembrane form of PrP mediated by the HD mutants. Thus, signal sequences are functionally nonequivalent in vivo, with intrinsic inefficiency of the native PrP signal being required for pathogenesis of a subset of disease-causing PrP mutations.     

Signal transduction of constitutively active protein kinase C epsilon

The protein kinase C (PKC) family is the most prominent target of tumor-promoting phorbol esters. For the PKCε isozyme, different intracellular localizations and oncogenic potential in several but not all experimental systems have been reported. To obtain information about PKCε-signaling, we investigated the effects of constitutively active rat PKCε (PKCεA/E, alanine 159 is replaced by glutamic acid) in HeLa cells in a doxycycline-inducible vector. Upon induction of PKCεA/E expression by doxycycline, the major part of PKCεA/E was localized to the Golgi. This led (i) to phosphorylations of PKCε^S729, Elk-1^S383, PDK1^S241 and Rb^S807/S811, (ii) to elevated expression of receptor of activated C kinase 2 (RACK2) after 12 h, and (iii) increased colony formation in soft agar, increased cell migration and invasion, but not to decreased doubling time. Following induction of PKCεA/E-expression by doxycycline for 24 h and additional short-term treatment with 12-O-tetradecanoylphorbol-13-acetate (TPA), PKCεA/E translocated to the plasma membrane and increased phosphorylation of MARCKS^S152/156. Treatment with doxycycline/TPA or TPA alone increased phosphorylations of Elk-1^S383, PDK1^S241, Rb^S807/S811, PKCδ^T505, p38MAPK^T180/Y182, MEK1/2^S217/S221 and ERK2^T185/T187. MARCKS was not phosphorylated after treatment with TPA alone, demonstrating that in this system it is phosphorylated only by PKCε localized to the plasma membrane but not by PKCα or δ, the other TPA-responsive PKC isozymes in HeLa cells. These results demonstrate that PKCε can induce distinctly different signaling from the Golgi and from the plasma membrane.     

Signal transduction by plant heterotrimeric G‐protein

Heterotrimeric G‐proteins are complexes that regulate important signalling pathways essential for growth and development in both plants and animals. Although plant cells are composed of the core components (Gα, Gβ and Gγ subunits) found in animal G‐proteins, the complexities of the architecture, function and signalling mechanisms of those in animals are dissimilar to those identified in some plants. Current studies on plant G‐proteins have improved knowledge of the essential physiological and agronomic properties, which when harnessed, could potentially impact global food security. Extensive studies on the molecular mechanisms underlying these properties in diverse plant species will be imperative in improving our current understanding of G‐protein signalling pathways involved in plant growth and development. The advancement of G‐protein signalling networks in distinct plant species could significantly aid in better crop development. This review summarizes current progress, novel discoveries and future prospects for this area in potential crop improvement.