Phospholipase C-gamma as a signal-transducing element

A ubiquitous signaling event in hormonal responses is the phospholipase C (PLC)-catalyzed hydrolysis of phosphatidylinositol 4, 5-bisphosphate to produce the metabolite second messenger molecules inositol 1,4,5-trisphosphate and diacylglycerol. The former provokes a transient increase in intracellular free Ca(2+), while the latter serves as a direct activator of protein kinase C. In tyrosine kinase-dependent signaling pathways this reaction is mediated by the PLC-gamma isozymes. These are direct substrates of many tyrosine kinases in a wide variety of cell types. The mechanism of PLC-gamma activation involves its association with and phosphorylation by receptor and non-receptor tyrosine kinases, as well as interaction with specialized adaptor molecules and, perhaps, other second messenger molecules. However, the biochemistry of PLC-gamma is at a more advanced state than a clear understanding of exactly how this signaling element functions in the generation of a mitogenic response.     

Dynamic gap junctional communication: a delimiting model for tissue responses.

Gap junctions are aqueous intercellular channels formed by a diverse class of membrane-spanning proteins, known as connexins. These aqueous pores provide partial cytoplasmic continuity between cells in most tissues, and are freely permeable to a host of physiologically relevant second messenger molecules/ionic species (e.g., Ca2+, IP3, cAMP, cGMP). Despite the fact that these second messenger molecules/ionic species have been shown to alter junctional patency, there is no clear basis for understanding how dynamic and transient changes in the intracellular concentration of second messenger molecules might modulate the extent of intercellular communication among coupled cells. Thus, we have modified the tissue monolayer model of Ramanan and Brink (1990) to account for both the up-regulatory and down-regulatory effects on junctions by second messenger molecules that diffuse through gap junctions. We have chosen the vascular wall as our morphological correlate because of its anisotropy and large investment of gap junctions. The model allows us to illustrate the putative behavior of gap junctions under a variety of physiologically relevant conditions. The modeling studies demonstrated that transient alterations in intracellular second messenger concentrations are capable of producing 50-125% changes in the number of cells recruited into a functional syncytial unit, after activation of a single cell. Moreover, the model conditions required to demonstrate such physiologically relevant changes in intercellular diffusion among coupled cells are commonly observed in intact tissues and cultured cells.     

Selective permeability of different connexin channels to the second messenger cyclic AMP

Gap junctions are intercellular conduits that are formed in vertebrates by connexin proteins and allow diffusion exchange of intracellular ions and small molecules. At least 20 different connexin genes in the human and mouse genome are cell-type specifically expressed with overlapping expression patterns. A possible explanation for this diversity could be different permeability of biologically important molecules, such as second messenger molecules. We have recently demonstrated that cyclic nucleotide-gated channels can be used to quantify gap junction-mediated diffusion of cyclic AMP. Using this method we have compared the relative permeability of gap junction channels composed of connexin 26, 32, 36, 43, 45, or 47 proteins toward the second messenger cAMP. Here we show that cAMP permeates through the investigated connexin channels with up to 30-fold different efficacy. Our results suggest that intercellular cAMP signaling in different cell types can be affected by the connexin expression pattern.     

What is the importance of multivesicular bodies in retrograde axonal transport in vivo?

Neurons with long axons have a unique problem in generating signaling cascades that are able to reach the nucleus after receptor activation by neurotrophins at the nerve terminal. The straightforward concept of receptor binding and local generation of 2nd second messenger cascades is too simplistic. In this review we will outline a mechanism that would enable the complex signals generated at the nerve terminal to be conveyed intact to the cell body. There are three different sites in the neuron where 2nd messenger proteins can interact with the signaling complex and be activated. Signaling cascades are initiated both at the nerve terminal and at the cell body when 2nd messengers are recruited to the plasma membrane by activated receptors. After receptor-mediated endocytosis, 2nd messenger molecules continue to be recruited to the internalized vesicle; however, the mix of proteins differs in the nerve terminal and in the cell body. At the nerve terminal the activated pathways result in the formation of the neurotrophin signaling endosome, which includes molecules to be retrogradely transported to the cell body. When the retrograde neurotrophin signaling endosome reaches the cell body, it can recruit additional 2nd messenger molecules to finally generate the unique signal derived from the nerve terminal. We propose that the multivesicular body observed in vivo functions as an endosome carrier vehicle or retrosome. This retrosome enables the mix of signaling molecules recruited at the terminal to be transported intact to the cell body. This will allow the cell body to receive a snapshot of the events occurring at the nerve terminal at the time the retrosome is formed.     

Inhibition of plant plasma membrane phosphoinositide phospholipase C by the actin-binding protein, profilin

A key event in signal transduction in many eukaryotes is activation of polyphosphoinositide-specific phospholipase C (PIC). This enzyme hydrolyses the plasma membrane-associated lipid, phosphatidylinositol(4,5)bisphosphate (Ptdlns(4,5)P₂) which leads to the production of the two second messenger molecules: inositol(1,4,5)trisphosphate (Ins(1,4,5)P₃) and 1,2-diacylglycerol (DG). In plants, an enzyme which functionally resembles mammalian PIC is known to exist in the plasma membrane, but little is understood about how its activity is regulated. The recent discovery of several plant proteins with 30–40% homology to the mammalian actin- and phosphoinositide-binding protein, profilin, has prompted an investigation as to whether these proteins (plant profilins) are able to interact with polyphosphoinositides and, if so, whether such interactions have physiological relevance for signal transduction via the plant phosphoinositide system.
In this study it is demonstrated that a direct and highly specific interaction does exist between plant profilin and polyphosphoinositides and that these interactions dramatically affect the ability of plant plasma membrane phosphoinositide phospholipase C to utilize phosphoinositides for second messenger production. These data are the first to demonstrate a functional role of plant profilin in controlling polyphosphoinositide turnover and also provide the first evidence for a direct effect of an actin-binding protein on a membrane-associated signalling enzyme. These findings indicate a novel mechanism for control of plant phosphoinositide turnover, and suggest a possible link between plant cell activation, second messenger production and modulation of cytoskeletal dynamics.     

Glycosylphosphatidylinositol anchored recognition molecules that function in axonal fasciculation, growth and guidance in the nervous system.

A large number of glycoproteins in the central nervous system are attached to the cell membrane via covalent linkage to glycosylphosphatidylinositol (GPI). Many of them, including the drosophila fasciclin 1 as well as the mammalian glycoproteins Thy-1, TAG1, N-CAM and F11,F3, contactin are members of the immunoglobulin gene superfamily. These and other GPI-linked molecules have been implicated in key developmental events including selective axonal fasciculation and highly specific growth to and innervation of target tissues. In model systems fasciclin 1, TAG1 and N-CAM have been shown to be capable of mediating cell-cell adhesion via a homophilic binding mechanism confirming their operational classification as cell adhesion molecules (CAMs). However, of these molecules, only N-CAM has been shown to mediate a complex response (neurite outgrowth) via a homophilic binding mechanism. Whether the other molecules in this family mediate biological responses by binding to themselves and/or other molecules remains to be determined. Studies on N-CAM provide an ideal model system for understanding the function of GPI anchors since alternative splicing of the NCAM gene generates both lipid-linked and transmembrane N-CAM isoforms. Recent studies have shown that neurons can recognise and respond (by increased neurite outgrowth) to both lipid-linked and transmembrane N-CAM isoforms expressed on the surface of non-neuronal cells following transfection with appropriate cDNAs. The major determinant of neuronal responsiveness was the level of N-CAM expression rather than the isoform type. Neurite outgrowth in response to transfected N-CAM is mediated by transmembrane N-CAM isoforms expressed by neurons and this involves the activation of classical second messenger pathways in the neurons. One possibility is that GPI anchors are utilised when a cell has simply to provide recognition or positional information to a second cell whereas transmembrane molecules might be required for cells that actively respond to such information. The hypothesis is compatible with all the known information on N-CAM expression and function and may be extended to other adhesive events.     

Phospholipase A2 promotes raft budding and fission from giant liposomes

Cellular processes involving membrane vesiculation are related to cellular transport and membrane components trafficking. Endocytosis, formation of caveolae and caveosomes, as well as Golgi membranes traffic have been linked to the existence and dynamics of particular types of lipid/protein membrane domains, enriched in sphingolipids and cholesterol, called rafts [Nature 387 (1997) 569; Trends Cell Biol. 12 (2002) 296; Biochemistry 27 (1988) 6197]. In addition, the participation of phospholipases in the vesiculation of Golgi and other membranes has been already established [Traffic 1 (2000) 504] essentially in their role in the production of second messenger molecules. In this work we illustrate with raft-containing giant lipid vesicles a mechanism for raft-vesicle expulsion from the membrane due to the activity of a single enzyme-phospholipase A(2) (PLA(2)). This leads to the hypothesis that the PLA(2), apart from its role in second messenger generation, might play a direct and general role in the vesiculation processes underlying the intermembrane transport of rafts through purely physicochemical mechanisms. These mechanisms would be: enzyme adsorption leading to membrane curvature generation (budding), and enzyme activity modulation of the line tension at the raft boundaries, which induces vesicle fission.     

Mechanisms of association learning in the post-synaptic neurone

A general mechanism for association learning in neurones is presented based on the biochemistry and electrophysiology of synaptic receptor regions. The mechanism involves the voltage sensitive generation of second messengers in the post-synaptic neurone, and their subsequent influence on the sensitivity of the local receptor region. The mechanism is examined in detail using a computer model of the reaction dynamics of two important synaptic receptors; the adrenergic receptor and the NMDA-type glutamate receptor. The computer model simulates concentration changes of several molecules in the post-synaptic neurone following an input to a receptor. It also models changes in membrane potential caused by the cell firing, and allows for the impact of these potential changes on second messenger generation within the cell. Finally the model incorporates two possible mechanisms whereby high concentrations of second messenger can lead to long-lasting changes in receptor sensitivity. The model demonstrates an enhancement of synaptic response when previous inputs to the same receptor region have occurred when the cell was firing. Using the model, long term potentiation (LTP) of the glutamate response is demonstrated following a high frequency input to the glutamate receptor. A neurone with ten glutamate receptors is simulated and demonstrates that individual neurones should be capable of recognising patterns of input activity when those patterns have repeatedly occurred at times of major cellular activity.     

Structural basis of cyclic oligoadenylate degradation by ancillary Type III CRISPR-Cas ring nucleases

Type III CRISPR-Cas effector systems detect foreign RNA triggering DNA and RNA cleavage and synthesizing cyclic oligoadenylate molecules (cA) in their Cas10 subunit. cAs act as a second messenger activating auxiliary nucleases, leading to an indiscriminate RNA degradation that can end in cell dormancy or death. Standalone ring nucleases are CRISPR ancillary proteins which downregulate the strong immune response of Type III systems by degrading cA. These enzymes contain a CRISPR-associated Rossman-fold (CARF) domain, which binds and cleaves the cA molecule. Here, we present the structures of the standalone ring nuclease from Sulfolobus islandicus (Sis) 0811 in its apo and post-catalytic states. This enzyme is composed by a N-terminal CARF and a C-terminal wHTH domain. Sis0811 presents a phosphodiester hydrolysis metal-independent mechanism, which cleaves cA₄ rings to generate linear adenylate species, thus reducing the levels of the second messenger and switching off the cell antiviral state. The structural and biochemical analysis revealed the coupling of a cork-screw conformational change with the positioning of key catalytic residues to proceed with cA₄ phosphodiester hydrolysis in a non-concerted manner.     

Electrically triggered all-or-none Ca(2)+-liberation during action potential in the giant alga Chara.

Electrically triggered action potentials in the giant alga Chara corallina are associated with a transient rise in the concentration of free Ca(2)+ in the cytoplasm (Ca(2)+(cyt)). The present measurements of Ca(2)+(cyt) during membrane excitation show that stimulating pulses of low magnitude (subthreshold pulse) had no perceivable effect on Ca(2)+(cyt). When the strength of a pulse exceeded a narrow threshold (suprathreshold pulse) it evoked the full extent of the Ca(2)+(cyt) elevation. This suggests an all-or-none mechanism for Ca(2)+ mobilization. A transient calcium rise could also be induced by one subthreshold pulse if it was after another subthreshold pulse of the same kind after a suitable interval, i.e., not closer than a few 100 ms and not longer than a few seconds. This dependency of Ca(2)+ mobilization on single and double pulses can be simulated by a model in which a second messenger is produced in a voltage-dependent manner. This second messenger liberates Ca(2)+ from internal stores in an all-or-none manner once a critical concentration (threshold) of the second messenger is exceeded in the cytoplasm. The positive effect of a single suprathreshold pulse and two optimally spaced subthreshold pulses on Ca(2)+ mobilization can be explained on the basis of relative velocity for second messenger production and decomposition as well as the availability of the precursor for the second messenger production. Assuming that inositol-1,4,5,-trisphosphate (IP(3)) is the second messenger in question, the present data provide the major rate constants for IP(3) metabolism.     

Structures of human and rabbit beta-globin precursor messenger RNAs in solution

The structures in solution of human and rabbit beta-globin precursor messenger RNAs containing their first intervening sequence have been investigated. This was accomplished by chemical probing experiments to determine sites of potential base pairing, and by cross-linking experiments to determine the sites of long-range interactions. Secondary structures for both molecules were predicted by using this information. Both molecules are arranged into two separate domains. The first domain, consisting of the first exon, contains several long-range interactions between the beginning of the molecule and sites adjacent to the donor splice site and a partially conserved stem/loop structure. The second domain contains part of the intervening sequence and the beginning of the second exon. The secondary structures involved in the second domain are different in the two molecules. These studies indicate a lack of connection between the donor and acceptor splice sites in these two molecules on the level of the secondary structure. Furthermore, given the absence of strongly conserved structures, it is unlikely that there could be any strict requirements for secondary structures that influence splice site usage.     

Roles of cADPR and NAADP in pancreatic cells

Cyclic ADP-ribose (cADPR) and nicotinic acid adenine dinucleotide phosphate (NAADP) are Ca(2+)-mobilizing nucleotides that were discovered in the late 1980s. Two decades of investigations have built up a considerable understanding about these two molecules that are related because both are derived from pyridine nucleotides and known to be generated by CD38/ADP-ribosyl cyclases. cADPR has been shown to target the ryanodine receptors in the endoplasmic reticulum whereas NAADP stimulates the two-pore channels in the endo-lysosomes. Accumulating results indicate that cADPR and NAADP are second messenger molecules mediating Ca(2+) signaling activated by a wide range of agonists. This article reviews what is known about these two molecules, especially regarding their signaling roles in the pancreatic cells.     

What do ras oncogenes do?

The ras oncogenes play a crucial role in the regulation of cellular proliferation, probably by coupling growth factor receptors to the PI second messenger pathway. Additional experiments are needed to verify and detail this mechanism, and to examine the question of differing roles for the three ras variants.     

Inositol tetrakisphosphate as a second messenger: confusions, contradictions, and a potential resolution.

The second messenger function of inositol 1,4,5-trisphosphate (InsP3) is now well-defined--it mobilizes Ca2+ from intracellular stores so that cystolic Ca2+ increases. However, the function of inositol 1,3,4,5-tetrakisphosphate (InsP4) has proved much more difficult to fathom, as it has been reported to exert a wide variety of effects in a collection of experimental systems. In this review, a proposed molecular mechanism for InsP4's actions is discussed; it is suggested that InsP4 is the second messenger that controls Ca2+ entry into cells, and that it does so by binding to a receptor which itself interacts, directly or indirectly, with the receptor for InsP3. It is proposed that this is InsP4's true physiological function, but the mechanism by which it exerts this function has led to confusing data concerning its action, and also to some misconceptions about how inositol phosphates control Ca2+ entry.     

NAADP as a second messenger: neither CD38 nor base-exchange reaction are necessary for in vivo generation of NAADP in myometrial cells

Nicotinic acid adenine dinucleotide phosphate (NAADP) has recently been shown to act as a second messenger controlling intracellular Ca²⁺ responses in mammalian cells. Many questions remain regarding this signaling pathway, including the role of the ryanodine receptor (RyR) in NAADP-induced Ca²⁺ transients. Furthermore, the exact metabolic pathway responsible for the synthesis of NAADP in vivo has not been determined. Here, we demonstrate that the NAADP mediated Ca²⁺ release system is present in human myometrial cells. We also demonstrate that human myometrial cells use the NAADP second messenger system to generate intracellular Ca²⁺ transients in response to histamine. It has been proposed in the past that the NAADP system in mammalian cells is dependent on the presence of functional RyRs. Here, we observed that the histamine-induced Ca²⁺ transients are dependent on both the NAADP and inositol 1,4,5-trisphosphate signaling pathways but are independent of RyRs. The enzyme CD38 has been shown to catalyze the synthesis of NAADP in vitro by the base-exchange reaction. Furthermore, it has been proposed that this enzyme is responsible for the intracellular generation of NAADP in vivo. Using CD38 knockout mice, we observed that both the basal and histamine stimulated levels of NAADP are independent of CD38 and the base-exchange reaction. Our group is the first to demonstrate that NAADP is a second messenger for histamine-elicited Ca²⁺ transients in human myometrial cells. Furthermore, the NAADP mediated mechanism in mammalian cells can be independent of RyRs and CD38. Our data provides novel insights into the understanding of the mechanism of action and metabolism of this new second messenger system. cADP ribose; inositol 1,4,5-trisphosphate; endoplasmic reticulum; ryanodine channel; nicotinic acid adenine dinucleotide phosphate; CD38; base-exchange reaction     

A micro-method for the assay of polyadenylate-containing ribonucleic acid by gel electrophoresis.

A micro-method for the determination of the electrophoretic profile of the various poly(A)-containing RNA species in a RNA sample was developed. The method is simple to carry out and allows for great reproducibility. It combines the resolving power of electrophoresis in agarose with the specificity of binding of poly(A) to poly(U)-containing glass-fibre filters. It consists of the following steps. (1) The molecules in an RNA sample are first separated according to their molecular weight by electrophoresis in agarose, at low ionic strength. 2. The molecules thus seperated are then submitted to a second electrophoresis in 'binding buffer' in a direction perpendicular to the first one. In the course of this electrophoresis the poly(A)-containing RNA species are seperated from other RNA species as they bind to a poly(U)-containing glass-fibre filter which is placed across the electrophoresis path. The method was used to determine the electrophoretic profile of Rhynchosciara salivary-gland messenger RNA. It was found that the population of messenger RNA in the gland is dominated by forms moving as 18 and 158 S peaks, but there is also polydisperse RNA with slower mobility.     

Substance P modulates single-channel properties of neuronal nicotinic acetylcholine receptors.

Substance P (SP) is present in avian sympathetic ganglia and accelerates the decay rate of acetylcholine (ACh)-evoked macroscopic currents in sympathetic neurons. We demonstrate here that SP modulates ACh-elicited single channels in a manner consistent with an enhancement of ACh receptor (AChR) desensitization. Furthermore, since AChR channel function was monitored in cell-attached patches with SP applied to the extra-patch membrane, the peptide must act via a second messenger mechanism. SP specifically decreases the net ACh-activated single-channel current across the patch membrane by decreasing both channel opening frequency and mean open time kinetics. These experiments demonstrate that a peptide can modulate neuronal AChR function by a second messenger mechanism.