Immunoreactivity of synapses on primary afferent axons and sensory neurons in lamprey spinal cord (<Emphasis Type="Italic">Lampetra fluviatilis</Emphasis>)

The ultrastructure and immunospecificity of synapses on primary afferents and dorsal sensory cells (DCs) were studied in lamprey (Lampetra fluviatilis) spinal cords. Using the postembedding immunogold method with a combination of antibodies—polyclonal antibodies to glutamate and monoclonal antibodies to gamma-aminobutyric acid (GABA)—the presence of GABA-positive on the primary afferent axons and GABA-and glutamate-immunopositive synapses on the DC somatic membranes have been shown. Thus, it is obvious that sensory information in the lamprey is controlled by both presynaptic inhibition via synapses on the primary afferent axons and by direct synaptic influence on the body of the sensory neuron.     

Role of group-II and -III metabotropic glutamate receptors in the modulation of miniature synaptic activity in frog spinal-cord motoneurons

Results of the present work demonstrate the pronounced modulating effects mediated by group-II and-III metabotropic glutamate receptors (mGluRs) on miniature postsynaptic potentials (mPSPs) of frog spinal motoneurons. The character of the effects of the group-II and-III mGluRs ligands, i.e., changes in the mPSPs frequency and the absence of significant changes in their amplitude, indicates the presynaptic mechanism of the modulation due to a change of the process of transmitter release. The application of ethylglutamate (EGLU) and methylaminophosphobutyrate (MAP4), which are selective antagonists of group-II and-III mGluRs, increased frequency of mPSPs by an average of 52.8 ± 30.2% (in four out of six motoneurons) and by 54.7 ± 23.7% (in all 7 motoneurons), respectively. The application of group-III mGluRs agonist L-aminophosphobutyrate (L-AP4) decreased the mPSP frequency by 21.8 ± 5.2% in three out of five motoneurons. The efficiency of the use of an antagonist and the comparatively low efficiency of the agonist suggest that presynaptic mGluRs are tonically activated during motoneuronal synapses. The absence of a group-II mGluR antagonist effect in some motoneurons appears to be explained by the specific localization of group-II mGluRs in the preterminal area distant from the transmitter release site. The modulation of pharmacologically isolated inhibitory miniature activity and its glycine and GABAergic fractions due to the group-III mGluRs-mediated heteroreceptor was investigated. The MAP4 application was shown to increase the glycine-mediated mIPSPs frequency to a greater degree than the GABA-mediated mIPSPs frequency, as their modulations were equal to an average of 97.6 ± 20.7% (n = 7) and 54.6 ± 20.8% (n = 5), respectively. This difference might possibly be due to the segregation of the postsynaptic glycine and GABA_A receptors. The study of the convergence of the modulating effects of the presynaptic mGluRs and metabotropic GABA_B receptors has shown that, under the condition of the blockage of the tonically active GABA_B receptor by phaclofen, the application of the group-III mGluR agonist L-AP4 produces the typical effect, which was completely eliminated by subsequent application of the group-III mGluRs antagonist MAP4. This result agrees with the point of view regarding the independence of effects mediated by GABA_B receptors and group-III mGluRse.     

Analysis of Combined Action of Antagonists of Excitatory and Inhibitory Amino Acids on Motoneuron Postsynaptic Potentials of the Frog Rana ridibunda

The effect of blockers of excitatory and inhibitory amino acid receptors on postsynaptic potentials (PSP) evoked by activation of three synaptic inputs of the lumbar motoneuron (stimulation of the dorsal root, reticular formation, ventral and lateral columns) was studied on preparation of the isolated spinal cord of the frog Rana ridibunda. It has been shown that sensitivity of PSP to antagonists differs in different motoneurons, in the same motoneuron at activation of different inputs, and in the same input in different PSP components. It has been found that many descendent (DC) PSPs resistant to kynurenate or CNQX [1] were inhibited by blockers of inhibitory receptors. In this case the early component of DC-PSP varied considerably by amplitude and changed its polarity from positive to negative on the background of a low transmembrane depolarizing current. These changes were absent under conditions of replacement of chlorine ion by sulfate in the perfusion solution or treatment of the spinal cord with a blocker of inhibitory amino acids. All this allows suggesting that these DC-PSPs or their components were inhibitory. A part of PSPs resistant to kynurenate and CNQX were also resistant to the blockers of inhibitory amino acids (strychnine, picrotoxin, and bicuculline). In some cases, as a result of treatment with convulsants, the same blockers of excitatory receptors inhibited the initially resistant PSPs.     

Immunocytochemical research on mediators of centrifugal visual neurons in lampreys (Lampetra fluviatilis)]

The aim of this study has been to investigate different neuroactive substances in the lamprey centrifugal visual neurons (CVN) by combining axonal tracing methods and immunocytochemistry. The CVN somata are immunonegative to antibodies recognizing FMRF-amide, LH-RH, 5 HT and TH, but immunopositive to an anti-GABA antiserum (GABA+) in a proportion of 40%. In the retina, the GABA+ axon terminals mainly synapse upon GABA+ and GABA- amacrine cell bodies and dendrites, and on dendrites of GABA- ganglion cells.     

Principles of organization and evolution of systems of regulation of functions

Evolution of living organisms is closely connected with evolution of structure of the system of regulations and its mechanisms. The functional ground of regulations is chemical signalization. As early as in unicellular organisms there is a set of signal mechanisms providing their life activity and orientation in space and time. Subsequent evolution of ways of chemical signalization followed the way of development of delivery pathways of chemical signal and development of mechanisms of its regulation. The mechanism of chemical regulation of the signal interaction is discussed by the example of the specialized system of transduction of signal from neuron to neuron, of effect of hormone on the epithelial cell and modulation of this effect. These mechanisms are considered as the most important ways of the fine and precise adaptation of chemical signalization underlying functioning of physiological systems and organs of the living organism     

Synaptic and electotonic contacts on primary afferent axons in the lamprey <Emphasis Type="Italic">Lampetra fluviatilis</Emphasis> spinal cord

Distribution of GABA and glycine immunoreactivity was studied in synapses on primary afferent axons of the lamprey Lampetra fluviatilis spinal cord using a double labelling technique. Approximately 25% of synapses exhibit GABA immunoreactivity, while more than 70% are immunoreactive to both neurotransmitters. As in other vertebrates, axo-axonal contacts represent three-component synaptic complexes, the so-called triads, where the immunoreactive terminal make synaptic contact simultaneously with the afferent axon and the dendrite contacting this afferent. Contact zones with gap junction-like cell membrane specializations were found between adjacent afferents suggesting the presence of electrotonic interaction between them. This interaction appears to serve for the synchronization of the afferent flow and represents a structural correlate of the mechanism of rapid interneuronal communication between functionally uniform neurons, which is an important element in the organization of coordinated locomotor acts. Besides, our studies provide evidence that afferent–afferent interaction may be mediated not only electrotonically but also with the aid of chemical synapses. This finding suggests that glutamate-induced depolarization of primary afferents results not only from autoreception but also from the direct effect of glutamate on the afferent’s cell membrane.     

Role of long-term potentiation in mechanism of the conditioned learning

The review analyzes the fundamental problem of study of the neuronal mechanisms underlying processes of learning and memory. As a neuronal model of these phenomena there was considered one of the cellular phenomena that has characteristics similar with those in the process of “memorizing”—such as the long-term potentiation (LTP). LTP is easily reproduced in certain synapses of the central nervous system, specifically in synapses of hippocampus and amygdala. As the behavioral model of learning, there was used the conditioned learning, in frames of which production of the context-dependent/independent conditioned reaction was considered. Analysis of literature data showed that various stages of LTP produced on synapses of hippocampus or amygdala can be comparable with certain phases of the process of learning. Based on the exposed material the authors conclude that plastic changes of synapses of hippocampus and amygdala can represent the morphological substrate of some kinds of learning and memory.