A second look at the second messenger hypothesis

A new mechanism of synapse-specific neuronal plasticity

According to current concepts, long-term memory is based on structural-functional changes in particular synaptic connections between neurons in the brain (synapse-specific plasticity), which depend on the processes of translation and transcription. Studies on neurons in the mollusk Aplysia and the mammalian hippocampus have addressed a mechanism of synapse-specific plasticity which does not require synapse-specific molecular genetic processes. Stimulation of a synapse has been shown to lead to activation of intracellular second messengers in the synapse as well as "synaptic tagging"--the formation of mechanisms "recognizing" transcription products. In the neuron body, second messengers induce the synthesis of RNA and protein molecules which are widely distributed in neuron processes and which are inserted selectively only into stimulation-tagged synapses, evoking long-term changes in their functional and morphological characteristics. The results of our studies on common snail defensive behavior command neurons LPl1 and RPl1 suggest the existence of another mechanism controlling synapse-specific plasticity. On acquisition of sensitization, a number of second messengers and the genes controlled by them are involved in supporting the plasticity of defined synaptic inputs of these neurons in snails. The processes of induction of long-term facilitation in the sensory inputs of neurons from chemoreceptors on the head have been shown to involve cAMP and cAMP-dependent transcription factors of the immediate early gene C/EBP (CAAT/enhancer binding protein), while the mechanisms controlling the other sensory input of neurons LPl1 and RPl1--from mechanoreceptors on the head--involve protein kinase C and protein kinase C-dependent transcription factor SRF (serum response factor). The immediate early gene zif268 is involved in controlling the inputs from both chemo-and mechanoreceptors on the head. These results are regarded as experimental support for the hypothesis that the molecular mechanisms of synapse-specific plasticity during learning may form on the basis of a selective neurochemical "projection" of the synaptic connections onto defined genes in the neuron.

The selective effect of a protein kinase C inhibitor on synaptic plasticity in defensive behavior command neurons during development of sensitization in the snail

Studies of defensive behavior command neurons LP11 and RP11 in semi-intact common snail preparations addressed the effects of the protein kinase C antagonist polymyxin B on the effect of nociceptive sensitization. Neurons in control snails responded to application of nociceptive stimuli to the head with membrane depolarization, increases in excitability, and depression of neuron responses to sensory stimulation during the short-term stage, with marked facilitation of responses during the long-term stage of sensitization. Acquisition of sensitization in the presence of polymyxin B resulted in partial suppression of responses to nociceptive stimuli. Changes in command neuron membrane excitability in these conditions, as well as changes in responses to tactile stimulation of the foot and chemical stimulation of the head, were similar to those seen in neurons of sensitized control animals. The inhibitor also had no effect on short-term depression of neuron responses induced by tactile stimulation of the head. In addition, acquisition of sensitization during administration of polymyxin B led to complete suppression of the facilitation of responses to tactile stimulation of the snail's head during the long-term stage of sensitization. It is suggested that in sensitized common snails, protein kinase C is involved in controlling the mechanisms of nociception and is also involved in the mechanisms of selective induction of plasticity in the synaptic inputs of command neurons, which are activated by tactile stimulation of the animal's head.

Cross signaling, cell specificity, and physiology

The literature on intracellular signal transduction presents a confusing picture: every regulatory factor appears to be regulated by all signal transduction cascades and to regulate all cell processes. This contrasts with the known exquisite specificity of action of extracellular signals in different cell types in vivo. The confusion of the in vitro literature is shown to arise from several causes: the inevitable artifacts inherent in reductionism, the arguments used to establish causal effect relationships, the use of less than adequate models (cell lines, transfections, acellular systems, etc.), and the implicit assumption that networks of regulations are universal whereas they are in fact cell and stage specific. Cell specificity results from the existence in any cell type of a unique set of proteins and their isoforms at each level of signal transduction cascades, from the space structure of their components, from their combinatorial logic at each level, from the presence of modulators of signal transduction proteins and of modulators of modulators, from the time structure of extracellular signals and of their transduction, and from quantitative differences of expression of similar sets of factors.

Kinetic behavior of a receptor-enzyme system: a model for drug addiction

A theoretical kinetic model describing the behavior of a receptor-enzyme system during formation of drug addiction is considered in this article. The model assumes concomitant action of narcotic on at least two targets with opposite effects. Theoretical kinetic principles that the system must satisfy for the development of drug addiction are formulated. These kinetic principles are the slow inactivation of receptor-enzyme system and the divergence of characteristic times of dynamic concentration of product and enzyme.

Some computational models at the cellular level

A number of viewpoints on how a cell can be modelled are discussed in this paper in light of the ability it has to process information. The paper begins with a very brief summary of four general types of computation: sequential, parallel, distributed, and emergent. These form the general framework from which a number of comparisons are made. Several metaphors are introduced to enable reflections to be made about cellular computational properties. The most important metaphor, namely the cell as a machine, is discussed, and then a number of other ideas are introduced that complement much current thinking in this area. The idea of networks or circuits in the cell is then developed, as this provides a means of describing the mechanisms within a machine. Following on from this, three further metaphors are applied in order to overcome certain limitations in current machine thinking, cell-as-society, cell-as-text, and cell-as-field.

Complexation studies on inositol-phosphates. II. Alkali-metal complexes of D-myo-inositol 1,2,6 trisphosphate

The complexation properties of the D-myo-inositol 1,2,6 trisphosphate (Ins(1,2,6)P3) towards Li+, Na+, K+, Rb+, and Cs+ cations were studied at 25 degrees C in a 0.1 M tetra-n-butylammonium bromide medium. For all cations, mononuclear and protonated species were found. For smaller cations (Li+, Na+, and K+) a dinuclear complex was also put into evidence. The main characteristic of the complexes is its high stability; and of the ligand, its nonselectivity. The Ins(1,2,6)P3-K system was ascertained using Sammartano's method which additionally enabled the influence of various K+ concentrations on the protonations constants to be considered.

Interactions between cyclic AMP and inositol phosphate transduction systems in astrocytes in primary culture

Astroglial cells in primary culture possess receptors with cyclic AMP and inositol phosphates (IP) as second messengers. The beta-receptor agonist, isoproterenol induces an increase in the accumulation of cyclic AMP, the alpha 2-receptor agonist clonidine inhibits the isoproterenol-induced accumulation of cyclic AMP, while the alpha 1-receptor agonist phenylephrine acts only on the inositol phosphate system. 5-Hydroxytryptamine (5-HT) stimulates, the formation of inositol phosphate, while isoproterenol and clonidine per se do not affect the inositol phosphate system. In the present paper the possibility of interactions between the cyclic AMP and the inositol phosphate transduction systems were investigated. In the presence of 10(-5) M 5-HT, in itself ineffective on the formation of cyclic AMP, isoproterenol stimulated the accumulation of cyclic AMP far more than in the absence of 5-HT. The potentiation was blocked by the 5-HT2 receptor antagonist ketanserin. On the other hand, there were no indications for a beta-receptor influence on the 5-HT-induced inositol phosphate formation. Stimulation of the alpha 2-receptor did not induce accumulation of inositol phosphate but significantly potentiated 5-HT2-receptor transduction, as measured by hydrolysis of phosphoinositide and formation of inositol phosphate. Stimulation by 5-HT also increased the formation of inositol phosphate after adrenergic stimulation and this effect was found to be synergistic at certain concentrations of adrenergic agonists. In addition, there was a statistically significant accumulation of cyclic AMP in the presence of both 5-HT and phenylephrine, none of which stimulated cyclic AMP alone. The results suggest specific interactions between the cyclic AMP and inositol phosphate systems on cultured astroglial cells.

Molecular mechanisms of neuronal plasticity during learning: the role of secondary messengers

We present published data along with our own results concerning the role of second messengers and their intracellular receptors in molecular mechanisms associated with the plasticity of neurons during learning. The participation of cyclic 3',5'-adenosine monophosphate, cyclic 3',5'-guanosine monophosphate, calcium, calmodulin, and also the metabolic products of inositol phospholipids, inositol-1,4,5-triphosphate, diacylglycerol and the protein kinase C activated by it, arachidonic acid, and the products of its lipoxygenase oxidation during the regulation of neuronal plasticity over the course of prolonged potentiation, sensitization, habituation, and classical associative training are discussed.

[Inositol trisphosphate, a new "second messenger" for positive inotropic effects on the heart?]

Myocardial alpha 1-adrenoceptors mediate a positive inotropic effect and influence the inositol phosphate cycle. The receptor-stimulated, phospholipase C-mediated hydrolysis of phosphatidylinositol bisphosphate (PIP2) results in the generation of two novel second messengers, inositol trisphosphate (IP3) and diacylglycerol (DG). This effect is concentration-dependent and precedes the increase in force of contraction. Recently, it has been shown that the alpha 1-adrenoceptor-mediated increase in IP3 and force of contraction exists in the human heart as well. Possible mechanisms for an inositol phosphate-mediated positive inotropic effect are: (i) release of Ca2+ from the sarcoplasmic reticulum, elicited by IP3, (ii) increase in Ca2+ sensitivity of the contractile proteins, elicited by IP3, inositol tetrakisphosphate (IP4) and/or DG, (iii) increase in slow Ca2+ inward current, elicited directly by IP4 and/or indirectly by DG through a phosphorylation of the protein kinase C substrate in the sarcolemma. In ventricular cardiac preparations muscarinic agonists have a weak positive inotropic effect, but in cardiac atrial preparations they have a negative inotropic effect. In both preparations, these different effects coincide with a concentration-dependent increase in IP3. Thus, the possible positive inotropic effect in atrial preparations is probably masked by an activation of a K+ outward current. The relationship between the inositol phosphate cycle and the positive inotropic effect is in some points still speculative because not all of the mechanisms discussed are well settled yet. However, the stimulation of myocardial phosphoinositide breakdown resulting in an increased IP3 may be involved in the mechanism(s) whereby alpha1-adrenergic and muscarinic receptor stimulation exert an increase in myocardial force of contraction.(ABSTRACT TRUNCATED AT 250 WORDS)

Buspirone: an update on a unique anxiolytic agent

Buspirone (Buspar) is a azaspirodecanedione anxiolytic agent. Its mechanism of action is extremely complex, but current investigations indicate that its main neuropharmacologic effects are mediated by the 5-HT1A receptors. Other neuroreceptor systems could be involved, as buspirone displays some affinity for DA2 autoreceptors and 5-HT2 receptors. It has been proposed that inhibition of synthesis and release of serotonin result through the combined interactions of neuroreceptors and secondary messenger systems. This action leads to inhibition of the firing rate of 5-HT-containing neurons in the dorsal raphe. From this novel profile, that differs from that of the benzodiazepines, buspirone lacks anticonvulsant and muscle-relaxant properties, and causes only minimal sedation. The drug is rapidly absorbed after oral administration, with a mean bioavailability of 3.9%. After a single oral dose, the mean elimination half-life is 2.1 hours. Buspirone is mainly bound to albumin and alpha 1-acid glycoprotein. It is metabolized to an active metabolite 1-(2-pyrimidinyl) piperazine (1-PP). The mean elimination half-life of 1-PP is 6.1 hours. Buspirone is indicated in the treatment of generalized anxiety disorders. Its efficacy is comparable to the benzodiazepines. Its use in depression and panic disorders requires further investigation. When combined with alcohol or given alone, psychomotor impairment was not detected. Abuse, dependence, and withdrawal symptoms have not been reported. The frequency of adverse effects is low, and the most common effects are headaches, dizziness, nervousness, and lightheadness. Buspirone should be added to drug formularies and could represent a significant addition in psychopharmacology.

Isolation from subcellular preparation of a mediator of hypoglycaemic hGH peptides

This study demonstrated the release into the incubation medium of a cellular mediator from isolated fat adipocytes and hepatocytes after treatment with the hypoglycaemic fragment of human growth hormone, hGH 6-13. The activity of the putative mediator observed in the cell "ghosts" of both liver and rat cells suggests that the active component is likely to be derived from plasma membranes and has an ubiquitous cellular distribution. The hGH fragment-induced release of the mediator from plasma membranes depends upon the physiological status of the animals. Liver plasma membranes of starved rats yield significantly higher levels of the cellular mediator in response to treatment with hGH 6-13. The studies of the physiological factors influencing the release of the material from cellular systems clearly enhance the production of adequate amounts of the cellular mediator for molecular characterization. The precise chemical nature and the physiological role of the hGH cellular mediator are currently unknown.

Electrically coupled but chemically isolated synapses: dendritic spines and calcium in a rule for synaptic modification

An influential model of learning assumes synaptic enhancement occurs when there is pre- and post-synaptic conjunction of neuronal activity, as proposed by Hebb (1949) and studied in the form of long-term potentiation (LTP). There is evidence that LTP has a post-synaptic locus of control and is triggered by an elevation of intracellular calcium ion concentration, [Ca2+]i. Since synapses which undergo LTP are usually situated on dendritic spines, three effects of spine morphology on this system should be considered: (i) synapses on spines are chemically isolated by the barrier to Ca2+ diffusion due to the spine neck dimensions; (ii) the resistance of the spine neck permits a given synaptic current to bring about greater depolarization (of the spine head membrane) than the same current into a dendrite; while (iii) the spine neck resistance does not significantly attenuate current flow (in the dendrite to spine direction) because of the relatively high impedance of the spine head, and this permits electrical coupling via the dendritic tree. The specificity of LTP to activated synapses on depolarized cells has recently been attributed to special properties of the receptor-linked channel specifically activated by N-methyl-D-aspartate (NMDA). This admits calcium and other ions only when there is both depolarization and receptor activation. However, consideration of point (ii) suggests that, for spines with high resistance necks, the current through a synapse on the spine head will cause sufficient depolarization to unblock the NMDA channel. Thus, the properties of the NMDA channel do not account for the requirement for conjunction of pre- and post-synaptic activity, if these channels are located on the spine head. This suggests that additional mechanisms are required to explain why it is necessary to depolarize the post-synaptic cell in order to induce LTP. As an alternative, it is postulated that there exist voltage-sensitive calcium channels (VSCCs) on the spine head membrane, of a type which require greater membrane depolarization for activation. To generate the greater depolarization required, both pre- and post-synaptic activation would be necessary. If so, the role of dendritic or somatically located NMDA channels may be to "prime" neurons for LTP by enchancing voltage-dependent responses. A corollary is that spine resistance may regulate the threshold number of synapses required to produce LTP. It is predicted that, on spines with very high neck resistance (say, greater than 600 M omega), synaptic current alone may produce sufficient depolarization to activate VSCCs.(ABSTRACT TRUNCATED AT 400 WORDS)