Transmitters in early embryogenesis (new data)

New author's findings and published experimental data on participation of transmitters in first cleavage divisions are discussed. The data on qualitative peculiarities of intracellular transmitter receptors (or their functional equivalents), functional coupling of transmitters with secondary messengers and role of cortical cytoskeleton in realization of transmitter functions are confirmed.     

Possible role of “prenervous” neurotransmitters in cellular interactions of early embryogenesis: A hypothesis

Evidence is presented in support of the working hypothesis that prenervous neurotransmitters directly participate in cell-cell interactions occurring during the first several cleavage divisions of sea urchin embryos, a function which may occur during the early development of higher animals as well. This intercellular signaling could be a link in the evolutionary progression from the use of these substances as intracellular regulators to their participation in cell-cell interactions occurring during synaptic transmission.     

The possibility of participation of different protein kinases in the regulation of degradation of Glp6[125I]Tyr8SP6-11 with different endopeptidases in subcellular fractions of rat brain.

1. Nuclear fraction of cortex and synaptosomal fraction of hippocampus of rat brain were preincubated with ATP and different, "second messengers" as well as some "classical" neurotransmitters and then incubated with Glp6[125I]Tyr8SP6-11 (JP). 2. It was found that different neurotransmitters and especially "second messengers" might be involved in the activation or inhibition of peptidase I and II. 3. Activation of different protein kinases results in substantial modulation of degradation of JP (SP C-terminal fragment). 4. The data confirm that products of one peptidase might be inhibitors of the second peptidase acting on JP, although the second enzyme might be affected additionally in conditions activating different protein kinase systems.     

Minireview: Functional Modulation of Ligand-Gated GABAA and NMDA Receptor Channels by Phosphorylation

Abstract

Ion channels are ubiquitous membrane proteins that may be organized into different families according to their predicted transmembrane topology. They are concerned with rapid signalling over plasma and intracellular membranes and are activated, depending on their type, by transmembrane voltage, intracellular second messengers or extracellular neurotransmitters. Intracellular activities of protein kinases and phosphatases act to modulate ion channel activity (e.g. ref. 1). The modulation of the function of ligand activated, neuronal ion channels, that are crucial for synaptic transmission, may be an important basis for a modulation of a synaptic efficiency. The following review concentrates, due to space limitations, on the postranslational modification, and on the modulation of the function by protein kinase C and protein kinase A, of ligand-gated GABA_A channels and NMDA channels on a molecular level.     

A second look at the second messenger hypothesis

Several hundred hormones, neurotransmitters, growth factors and other "first messengers" bind to specific cell membrane receptors and induce a myriad of effects: short term, transport, metabolic, mitotic and regulation of thousands of specific genes. Yet, less than a dozen "second messengers" have been clearly established to date. Even allowing for the discovery of a large number of additional second messengers, there remains a paradox in terms of information-transfer within the cell: how can so many specific signals produce so many effects through so few relatively nonspecific intermediates? We consider several possible solutions to this paradox, including the hypothesis that signal specificity is encoded in part in the primary structure of the receptor.     

Excitatory amino acids: The involvement of second messengers in the signal transduction process

1. Excitatory amino acids (EAA) can activate second messenger systems in addition to a direct gating of ion channels. A discrete coupling between novel EAA receptor subtypes and second messenger systems has been previously proposed. 2. EAAs have been suggested to activate both adenylate and guanylate cyclases and also to induce phosphoinositide (PI) turnover. The increased PI turnover was observed in both central neurons and glia, and a "quisqualate-type" receptor has been most frequently involved, which may differ from the quisqualate receptor previously defined by electrophysiological studies. 3. The roles of EAA-induced calcium influx into neurons and raised intracellular calcium levels are discussed regarding the activation of phosphoinositide turnover. 4. This review examines the data supporting a link between EAA receptors and second messengers and considers whether there is any need for adopting new EAA receptor subtypes. Also, the use of the Xenopus laevis oocyte for expressing EAA receptors and studying any putative links to second messenger systems is discussed.     

Maxadilan activates PAC1 receptors expressed in Xenopus laevis xelanophores

Functional interactions between ligands and their cognate receptors can be investigated using the ability of melanophores from Xenopus laevis to disperse or aggregate their pigment granules in response to alterations in the intracellular levels of second messengers. We have examined the response of long-term lines of cultured melanophores from X. laevis to pituitary adenylate cyclase activating peptide (PACAP), a neuropeptide with vasodilatory activity, and maxadilan, a vasodilatory peptide present in the salivary gland extracts of the blood feeding sand fly. Pituitary adenylate cyclase activating peptide increased the intracellular levels of cyclic adenosine monophosphate (cAMP) and induced pigment dispersion in the pigment cells, confirming that melanophores express an endogenous PACAP receptor. Maxadilan did not induce a response in non-transfected melanophores. When the melanophores were transfected with complementary DNA (cDNA) from the three different members of the PACAP receptor family, maxadilan induced pigment dispersion specifically and cAMP accumulation in melanophores transfected with the cDNA for PAC1 receptors but not VPAC1 or VPAC2 receptors. A melanophore line was generated that stably expresses the PAC1 receptor.     

AKAP signalling complexes: focal points in space and time

Multiprotein signalling networks create focal points of enzyme activity that disseminate the intracellular action of many hormones and neurotransmitters. Accordingly, the spatio-temporal activation of protein kinases and phosphatases is an important factor in controlling where and when phosphorylation events occur. Anchoring proteins provide a molecular framework that orients these enzymes towards selected substrates. A-kinase anchoring proteins (AKAPs) are signal-organizing molecules that compartmentalize various enzymes that are regulated by second messengers.     

Furrow-related contractions are inhibited but furrow-unrelated contractions are not affected in af mutant eggs of Xenopus laevis

In embryos from af mutant females of Xenopus laevis, the cleavage furrows stayed on the surface and cytoplasmic divisions did not take place at all, while nuclear divisions continued (Kubota et al., 1991). To gain insights into the roles of the normal product of af on early development, contractile events which have been observed in the period from fertilization until first cleavage in wild-type eggs were examined in af mutant eggs. Activation waves, activation contraction, and surface contraction waves which were identical to those in wild-type eggs were observed in af eggs by time-lapse video recording. However, second polar body elimination was inhibited in af eggs, although a sign of the polar body formation was indicated by the cytoplasmic bulge of the egg surface as seen by light and electron microscopy. These results indicate that the normal product of af regulates furrow-related contractile events which involve formation of the contractile ring, but exerts no effects on furrow-unrelated contractions in early Xenopus eggs.     

Membrane receptors and intracellular calcium

The mechanisms of Ca2+ level regulation in the cytoplasm by neurotransmitters, hormones, and growth factors and described. The role of G-proteins, second messengers and protein kinases in the regulation of activity of Ca2+ channels and pumps is discussed. The contributions of the endoplasmic reticulum, plasma membrane, nucleus, mitochondria and other intercellular compartments to the increase in the cytoplasmic Ca2+ concentration are estimated. The data concerning the relationships between the activities of systems of active and passive Ca2+ transport across the membrane are reviewed. The general mechanisms of intracellular Ca2+ oscillation are summarized, and a possible role of this process in the neuroendocrine signal transduction is discussed.     

Regulation of gene expression by the intracellular second messengers IP3 and diacylglycerol

In Dictyostelium, extracellular cAMP interacts specifically with cell-surface receptors to promote the accumulation of a variety of intracellular second messengers, such as 3'-5' cyclic adenosine monophosphate (cAMP) and 1,4,5 inositol trisphosphate (IP3). We and others have shown that activation of the cell-surface cAMP receptor can also modulate the expression of the Dictyostelium genome during development. In at least one instance, synthesis of intracellular cAMP is required for appropriate gene regulation. However, the induction of most cAMP-dependent gene expression can occur in the absence of receptor-mediated activation of adenylate cyclase and a consequent accumulation of intracellular cAMP. These results suggest that other intracellular second messengers produced in response to receptor activation may potentially act as signal transducers to modulate gene expression during development. In vertebrate cells, IP3 and diacylglycerol (DAG) are intracellular activators of specific protein kinases; they are produced in equimolar amounts by cleavage of phosphoinositol bisphosphate after a receptor-mediated activation of a membrane-bound phosphodiesterase. IP3 and, thus, by inference, diacyl-glycerol are synthesized in Dictyostelium as a response to cAMP interacting with its cell-surface receptor. Using defined conditions to inhibit the accumulation of extracellular cAMP, we have examined the effects of these compounds on the expression of genes that require cAMP for their maximal expression. Our results suggest that intracellular IP3 and DAG may in part mediate the action of extracellular cAMP on the expression of the Dictyostelium genome.     

'METACHRONOUS' CLEAVAGE AND INITIATION OF GASTRULATION IN AMPHIBIAN EMBRYOS

The cleavage pattern in the egg of Xenopus laevis has been investigated with the aid of time-lapse cinematography. From the 5th cleavage onward, divisions of the surface blastomeres are not synchronous but metachronous. A few blastomeres in a very restricted region which is situated in most cases in the dorsal side of the animal hemisphere, slightly distant from the median line and near the equatorial junction of the animal and vegetal hemispheres, divide before the other blastomeres, and a wave-like propagation of the divisions travels along the surface from that region toward the animal and vegetal poles. The wave-like propagation ends in the vegetal pole region. In the animal hemisphere, this pattern of cleavage is continued until the 13th cleavage and thereafter the divisions of surface blastomeres become asynchronous. In the vegetal pole region, however, the 14th metachronous division of blastomeres is clearly observed in the film. Gastrulation begins after 14 cleavages.     

Cross-Talk between Signaling Pathways Can Generate Robust Oscillations in Calcium and cAMP

Background

To control and manipulate cellular signaling, we need to understand cellular strategies for information transfer, integration, and decision-making. A key feature of signal transduction is the generation of only a few intracellular messengers by many extracellular stimuli.

Methodology/Principal Findings

Here we model molecular cross-talk between two classic second messengers, cyclic AMP (cAMP) and calcium, and show that the dynamical complexity of the response of both messengers increases substantially through their interaction. In our model of a non-excitable cell, both cAMP and calcium concentrations can oscillate. If mutually inhibitory, cross-talk between the two second messengers can increase the range of agonist concentrations for which oscillations occur. If mutually activating, cross-talk decreases the oscillation range, but can generate ‘bursting’ oscillations of calcium and may enable better filtering of noise.

Conclusion

We postulate that this increased dynamical complexity allows the cell to encode more information, particularly if both second messengers encode signals. In their native environments, it is unlikely that cells are exposed to one stimulus at a time, and cross-talk may help generate sufficiently complex responses to allow the cell to discriminate between different combinations and concentrations of extracellular agonists.     

The Embryos Obtained from the Karyoplasts of Starfish Oocytes: Their Development and Sensitivity to Cytostatic Neurotransmitter Antagonists

Karyoplasts obtained from full-grown oocytes of the starfish Aphelasterias japonica have practically no cytoplams and are incapable of maturation. Karyoplasts of oocytes of starfishes Marthasterias glacialis and Acanthaster planci have the cytoplasm (10%–15% of the total karyoplast volume) and are often capable of maturation, fertilization and one or several cleavage divisions. The embryoskaryoplasts completely lose supersensitivity and retain usual sensitivity to cytostatic antagonists of neurotransmitters. The assumption is made that the incapability or limited capability of this embryos for development might be due to a deficiency of certain components of the "prenervous" neurotransmitter systems.     

Phospholipids and electrolyte transport.

Our understanding of the role of phospholipids in ion transport processes is only beginning to be appreciated. Although the role of polyphosphoinositide and its derived second messenger molecules IP3, diacylglycerol, and arachidonic acid are well studied, we are still not certain as to how changes in the lipid bilayer structure influence the status of ion channels. This review focused on those studies which show a strong correlation with ion conductance changes and the status of the membrane phospholipids. In addition, a number of observations point to a major role of lipid second messengers that activate enzymes involved in protein phosphorylations, i.e., protein kinase C, as major regulators of a variety of ion channels and transporters. Such lipid second messengers provide a cellular mechanism whereby hormones, neurotransmitters, and pharmacologic agents functionally control the ionic environment and intracellular pH of target cells. Some of these pathways still remain to be elucidated; however, an appreciation for the participation of membrane phospholipids in these actions has been presented.     

Die Cytologie der Parthenogenese bei dem Tardigraden Hypsibius dujardini

Hypsibius dujardini Doy. (Articulata, Tardigrada) shows obligatory parthenogenesis under given cultivating conditions. Males were never found. The first meiotic division reduces the number of chromosomes; the (2n=10) chromosomes are divided between a small polar body and the egg nucleus. Prior to the second division the dyads divide, thus restoring the diploid number. A diploid polar body is formed subsequent to the second division. After the egg nucleus has moved toward the center of the egg, the cleavage divisions begin. — During meiosis II and the first cleavage divisions the chromosomes can develop into “large chromosomes” which presumably consist mostly of RNA. No “large chromosomes” are found after the seventh cleavage division. Sometimes a plate of coloured material (“elimination chromatin”) can be observed between the anaphase daughter plates of the first cleavage divisions. In this case the chromosomes are always small.     

Molecular biology of cell activation

This article summarizes common features of activation of different types of cells along different physiological lines such as proliferation, differentiation, and execution of function of terminally differentiated cells. The common basis of many of these phenomena includes (i) first messengers (growth factors, cytokines, neurotransmitters, etc.) acting on membrane receptors, (ii) second messengers (cAMP, IP3, DAG, Ca2+) spreading an activating signal inside the cell, and (iii) elevated expression of some genes (c-fos, c-myc, ornithine decarboxylase). The role of the genetic correlate in cell activation is emphasized, and it is concluded that the aforementioned genes (their protein products) should be called third messengers, whose function is mediation of long-term phenotypic changes.     

G protein regulation of phospholipase A2

Many neurotransmitters and hormones activate receptors that are known to be coupled to their effectors by GTP-binding regulatory proteins, G proteins. Activation of many of these same receptors elicits arachidonate release and metabolism. During the past few years, novel experimental techniques have revealed that in many cells arachidonate release is independent of generation of other second messengers, including inositol phosphates, diacylglycerols, and elevation in free intracellular calcium. Much evidence has accumulated to implicate phospholipase A2 as the enzyme catalyzing arachidonate release, and suggesting that this effector enzyme, too, is activated by G proteins. In neural tissues as well as epithelium, endothelium, contractile and connective tissues, and blood cells, G proteins coupled to receptors for a variety of peptide and nonpeptide neurotransmitters and hormones have been shown to directly activate phospholipase A2. In retinal rod outer segments, transducin is the coupling G protein, but the G proteins coupling receptor activation to phospholipase A2 in other cell types is less clear. Some are pertussis toxin-sensitive, whereas others are not, and evidence exists that the ras gene product G protein may also be coupled to and regulate phospholipase A2.     

Mechanisms of cross-talk between G-protein-coupled receptors

There is increasing evidence to suggest that 'cross-talk' occurs between G-protein-coupled receptors and their intracellular second messenger pathways. Cross-talk between different pathways may occur at the level of receptors, G-proteins, effectors or second messengers and may serve to fine-tune cell signalling. There is a growing body of evidence to suggest that cellular compartmentalization may play a crucial role in regulating these cross-talk interactions. Understanding the mechanisms of cross-talk may therefore be the key to the design and application of future therapeutics and the development of drug specificity.     

Non-kinase second-messenger signaling: new pathways with new promise

Intercellular signaling by growth factors, hormones and neurotransmitters produces second messenger molecules such as cyclic adenosine monophosphate (cAMP) and diacylglycerol (DAG). Protein Kinase A and Protein Kinase C are the principal effector proteins of these prototypical second messengers in certain cell types. Recently, novel receptors for cAMP and DAG have been identified. These proteins, designated EPAC (Exchange Protein directly Activated by cAMP) or cAMP-GEF (cAMP regulated Guanine nucleotide Exchange Factor) and CalDAG-GEF (Calcium and Diacylglycerol regulated Guanine nucleotide Exchange Factor) or RasGRP (Ras Guanine nucleotide Releasing Protein) are able to mediate some of the physiologic effects of the second messengers in a protein-kinase-independent fashion. These proteins are exchange factors for Ras family GTPases that operate in pathways that run parallel to the classic kinase-dependent pathways. The rapidly emerging recognition of the functions of these "non-kinase" effectors in diverse processes such as insulin secretion, thymocyte development, asthma and malignant transformation creates new opportunities for discovery and identifies potential new therapeutic targets.