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1. Compensatory Changes in Mauthner Neurons in Goldfish Induced by Sensory Stimulation and Application of β-Amyloid

Author

I. B. Mikheyeva, G. Z. Mikhailova, Ye. N. Bezgina, N. R. Tiras, and N. A. Pen’kova

Subjects
0301 basic medicine, Sensory stimulation therapy, Chemistry, General Neuroscience, Dystrophy, Dendrite, law.invention, Synapse, 03 medical and health sciences, 030104 developmental biology, 0302 clinical medicine, Mauthner cell, medicine.anatomical_structure, nervous system, law, Ultrastructure, medicine, Neuron, Electron microscope, Neuroscience, 030217 neurology & neurosurgery
Abstract

Objectives. To study the structure and formation of Mauthner neuron dendrites in goldfish exposed to neurotoxic β-amyloid fragment 25–35 and prolonged sensory stimulation influencing the afferent inputs to these neurons. Materials and methods. Goldfish Mauthner neurons were studied by light and electron microscopy. Individual dendrites were identified, their volumes were determined, and synapse structure was assessed using virtual 3D images of Mauthner neurons obtained from serial sections of thickness 3 μm. The functional status of Mauthner neurons was evaluated indirectly from the motor lateralization of the fish. Results. Mauthner neurons responded to application of β-amyloid combined with subsequent prolonged sensory stimulation with decreases in the volume of the ventral dendrites, damage to their ultrastructure, and degeneration of a proportion of synapses. Degeneration of more active neurons was more significant than that of less active cells. Newly formed medial dendrites had greater volume and less damaged synapse ultrastructure than ventral dendrites. There were no differences in the sizes of specialized junctions between synapses of the same type on ventral and medial synapses. Conclusions. Medial dendrite formation is a compensatory reaction to dystrophy of the ventral dendrite due to the experimental treatment.

Published
2019
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2. Changes in the Dendrite Morphology of Mauthner Neurons in Goldfish under the Conditions of Monocular Deprivation and Sensory Stimulation

Author

N. N. Kashirskaya, R. Sh. Shtanchaev, E. N. Bezgina, N. A. Pen’kova, G. Z. Mikhailova, and N. R. Tiras

Subjects
0301 basic medicine, Sensory stimulation therapy, 030102 biochemistry & molecular biology, Chemistry, Biophysics, Stimulation, Dendrite, Synaptic vesicle, 03 medical and health sciences, Monocular deprivation, 030104 developmental biology, Mauthner cell, medicine.anatomical_structure, nervous system, medicine, Soma, Neuron, Neuroscience
Abstract

—The effects of sensory stimulation on the model of paired Mauthner neurons of monocularly deprived goldfish have been studied by light- and electron microscopy. Three-dimensional reconstruction was performed using serial semi-thin sections in order to determine the volumes of soma and dendrites for the right and left Mauthner neurons. These data suggested that long-term stimulation of some fish caused a decrease in the volume of the lateral dendrites of neurons contralateral with respect to the side of the enucleated eye. As a result, the morphological homeostasis in the dendrites of Mauthner neurons, which was observed in the control fish, was disturbed after the effect of stimulation upon this group of fish. The main mechanism of this effect of stimulation, according to ultrastructural analysis, is the compaction of the cytoskeleton in the lateral dendrite of a neuron and a reduction in the number of synaptic vesicles in the region of afferent synapses. In contrast, stimulation of the remaining fish induced the resistance of the contralateral Mauthner neuron to prolonged stimulation, as well as the hypertrophy of its lateral and shortening of the ventral dendrites. These results suggest that the homeostasis of the dendrites of Mauthner neurons essentially depends on the state of the visual inputs, the load on which increased as a result of the doubled impact.

Published
2019
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3. Dopamine Improves Resistance of Dendrites of Mauthner Neurons to Destruction Induced by Sensory Stimulation and Application of Β-Amyloid

Author

N. R. Tiras, G. Z. Mikhailova, I. B. Mikheeva, N. A. Pen’kova, and S. S. Khutsyan

Subjects
Neurons, Sensory stimulation therapy, Amyloid beta-Peptides, Chemistry, Dopamine, General Medicine, Dendrites, General Biochemistry, Genetics and Molecular Biology, law.invention, Mauthner cell, β amyloid, law, Afferent, Goldfish, Biophysics, medicine, Animals, Electron microscope, medicine.drug
Abstract

Mauthner neurons in goldfish fry were studied by the methods of light and electron microscopy. The structure and volume of individual dendrites as well as the structure of axodendritic synapses were examined using virtual images of neurons formed from serial 3-μ sections. In short-time (5 h) experiments with application of dopamine, β-amyloid fragment (25-35), and long-term sensory stimulation affecting afferent inputs to Mauthner neurons, the dendrites were larger than the same dendrites under the same conditions without dopamine application. Application of dopamine induced no pathological changes in the structure of axodendritic chemical and electric synapses containing desmosome-like contacts.

Published
2019

4. Changes in Motor Asymmetry of the Goldfish Related to Adaptation to Vestibular Stimulation and Applications of Beta-Amyloid on Mauthner Cells

Author

N. R. Tiras, G. A. Alilova, N. A. Pen’kova, Ye. N. Besgina, and D. A. Moshkov

Subjects
Vestibular system, Physiology, General Neuroscience, Gap junction, Stimulation, Dendrite, Anatomy, Biology, medicine.anatomical_structure, Mauthner cell, Excitatory postsynaptic potential, medicine, Soma, Neuron, Neuroscience
Abstract

We examined effects resulting from application of aggregated beta-amyloid on Mauthner neurons (MNs) of ambidextral goldfishes and long-lasting rotatory stimulation on lateral motor behavior of such fishes; these individuals were preliminarily adapted to repetitive rotatory stimulation. Using 3D histological reconstruction of the above cells, we measured the volumes of the right and left MNs and examined the ultrastructure of specialized synaptic compartments in excitatory synapses localized on the surface of the soma, lateral dendrite, and ventral dendrite of these cells. In the course of the experiments, control fishes remain ambidextrals, and the mean volumes of the right and left MNs in these individuals were close to each other. In a fish of this group, dimensions of the active zones (AZs) of chemical synapses localized on the lateral dendrite were considerably greater in the right neuron, while those in synapses on the lateral dendrite were smaller in the left neuron. Experimental fishes subjected to the above-mentioned procedures demonstrated clearly expressed motor lateralization; the mean volumes of their right and left MNs were, however, practically equal to each other. Ultrastructural analysis of peculiarities of MNs of such a fish showed that dimensions of the AZs in chemical synapses on the soma and lateral dendrite of the left MN, which became much less active functionally, significantly exceeded the analogous indices in synapses of the same localization on the right, more active, MN. In mixed synapses, the mean dimensions of gap junctions in control and experimental individuals were similar to each other independently of localization of such synapses. Interrelations between functional asymmetry of MNs manifested in lateralization of motor behavior of the fishes and dimensions of synaptic structures on these cells are discussed.

Published
2015
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5. Ultrastructure of Afferent Synapses on the Ventral Dendrites of Mauthner Neurons During Adaptation of Goldfish to Optokinetic Stimulation

Author

E. N. Bezgina, R. Sh. Shtanchaev, I. B. Mikheeva, N. A. Kokanova, N. R. Tiras, G. Z. Mikhailova, and D. A. Moshkov

Subjects
Neurotransmitter secretion, medicine.anatomical_structure, Mauthner cell, Chemistry, General Neuroscience, Ultrastructure, Excitatory postsynaptic potential, medicine, Dendrite, Stimulation, Sensory system, Inhibitory postsynaptic potential, Neuroscience
Abstract

Morphometric methods were used to study the ultrastructure of afferent synapses on the ventral dendrites of Mauthner neurons (MN) during adaptation of goldfish to prolonged, fatiguing, sensory (visual) stimulation inducing increased resistance of MN. The extent of active zones (AZ) in synapses located on the MN ventral dendrite was found to decrease significantly, by 23%, after adaptation. The extent of the AZ of excitatory visual synapses decreased by 29% as compared with controls, with a simultaneous 71% increase in the extent of desmosome-like contacts (DLC) bordering AZ. There was also a 19% reduction in the extent of AZ of inhibitory synapses after adaptation, which is consistent with the important role of inhibitory processes in sensory pathways during memory formation. Considering the actin nature of DLC, it can be suggested that adaptation to visual stimulation is based on a synaptic mechanism of regulation of neurotransmitter secretion by actin.

Published
2014
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6. Morphofunctional and Ultrastructural Consequences of Application of Beta-Amyloid on Goldfish Mauthner Neurons

Author

N. A. Kokanova, G. Z. Mikhailova, D. A. Moshkov, Ye. N. Bezgina N. R. Tiras, and R. Sh. Shtanchayev

Subjects
Mauthner cell, Vacuolization, Amyloid, Physiology, Cytoplasm, General Neuroscience, Biophysics, Ultrastructure, Dystrophy, Sensory system, Biology, Cytoskeleton, Neuroscience
Abstract

We studied the correlation between functional activity and 3D structure of Mauthner neurons (MNs) of the goldfish in the norm, after isolated application of an aggregated fragment of beta-amyloid 25-35 (Aβ25-35), and a combination of such application with optokinetic stimulation of the fish. It was shown that the clear correlation between the structure and function of MNs observed in the control is strongly disturbed after the action of beta-amyloid aggregates. According to the data of ultrastructural analysis, destruction of the cytoskeleton, vacuolization of the MN cytoplasm, and depletion of the vesicular apparatus of afferent synapses are the main events responsible for such effect of Aβ25-35. Fatiguing sensory optokinetic stimulation of fishes applied against the background of action of Aβ25-35 induces dystrophy of the ventral MN dendrites and the formation, near the latter, of earlier absent hypertrophied medial dendrites; these dendrites were comparable in their dimension with the main MN dendrites in control fishes. The data obtained allow us to suppose that a traumatic mechanical influence of the beta-amyloid aggregates on neurons and their processes is an important factor in the development of amyloidosis-related neurodegenerative diseases, and destruction of the cytoskeleton is one of the key phenomena from this aspect.

Published
2014
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7. Visual input controls the functional activity of goldfish Mauthner neuron through the reciprocal synaptic mechanism

Author

I. B. Mikheeva, G. Z. Mikhailova, Pavlik Ll, Elena N. Bezgina, D. A. Moshkov, N. R. Tiras, Rashid S. Shtanchaev, and Nadezhda A. Kokanova

Subjects
Serotonin, Stimulation, Dendrite, Motor Activity, Serotonergic, Synaptic Transmission, Mauthner cell, Microscopy, Electron, Transmission, Goldfish, medicine, Animals, Vision, Ocular, Mirror neuron, Neurons, Afferent Pathways, Behavior, Animal, Chemistry, General Neuroscience, General Medicine, Adaptation, Physiological, Immunohistochemistry, medicine.anatomical_structure, nervous system, Synapses, Excitatory postsynaptic potential, Neuron, Neuroscience, Photic Stimulation
Abstract

Goldfish are known to exhibit motor asymmetry due to functional asymmetry of their Mauthner neurons that induce the turns to the right or left during free swimming. It has been previously found that if the less active neuron is subjected to prolonged aimed visual stimulation via its ventral dendrite, the motor asymmetry of goldfish is inverted, testifying that this neuron becomes functionally dominant, while the size of the ventral dendrite under these conditions is reduced 2-3 times compared to its counterpart in mirror neuron. Earlier it has been also revealed that training optokinetic stimulation induces adaptation, a substantial resistance of both fish motor asymmetry and morphofunctional state of Mauthner neurons against prolonged optokinetic stimulation. The aim of this work was to study the cellular mechanisms of the effect of an unusual visual afferent input on goldfish motor asymmetry and Mauthner neuron function in norm and under adaptation. It was shown that serotonin applied onto Mauthner neurons greatly reduces their activity whereas its antagonist ondansetron increases it. Against the background of visual stimulation, serotonin strengthens functional asymmetry between neurons whereas ondansetron smoothes it. Taken together these data suggest the involvement of serotonergic excitatory synaptic transmission in the regulation of Mauthner neurons by vision. Ultrastructural study of the ventral dendrites after prolonged optokinetic stimulation has revealed depletions of numeral axo-axonal synapses with specific morphology, identified by means of immunogold label as serotonergic ones. These latter in turn are situated mainly on shaft boutons, which according to specific ultrastructural features are assigned to axo-dendritic inhibitory synapses. Thus, the excitatory serotonergic synapses seem to affect Mauthner neuron indirectly through inhibitory synapses. Further, it was morphometrically established that adaptation is accompanied by the significant decrease of active zones dimensions in both serotonergic and inhibitory synapses. Finally, it was determined in model experiments that the interaction of globular actin with glycine, a main inhibitory neurotransmitter supposedly directly and chronically affecting the ventral dendrite, results in actin filaments formation. It is assumed that glycine-induced cytosolic actin polymerization is a cause of reduction in the ventral dendrite size under stimulation. Thus, it was established that a rather small group of synapses situated on an individual dendrite of the neuron determines the execution of the important form of animal behavior.

Published
2013
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8. Induction of Morphological Resistance of Neurons to β-Amyloid

Author

R. Sh. Shtanchaev, and D. A. Moshkov, N. A. Kokanova, G. Z. Mikhailova, and N. R. Tiras

Subjects
Vestibular system, Chemistry, General Neuroscience, Amyloidosis, Sensory system, medicine.disease, Mauthner cell, β amyloid, Dopamine, medicine, Biophysics, Neuroscience, Electron microscopic, Function (biology), medicine.drug
Abstract

The effects of training with adaptive vestibular stimulation on the function and three-dimensional structure of Mauthner neurons (MN) were studied in goldfish with experimental amyloidosis induced by application of aggregated β-amyloid protein (Aβ25–35). In comparison with controls, adapted MN acquired significant resistance to Aβ25–35. Considering the key role of dopamine in the adaptation of MN to sensory stimuli, its actions on the development of an amyloidosis model were studied; the results showed that application of dopamine to MN, like increases in the dopamine concentration induced by L-DOPA, was followed by protection of MN structure and function from the pathogenic actions of Aβ25–35. Electron microscopic studies showed that the protective action of dopamine on neurons can be explained in terms of its ability to dissociate β-amyloid polymers into short inactive fragments.

Published
2013
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9. Dopamine as a possible substance for oncotherapy and for quantitative valuation of cytosolic G-Actin

Author

E. N. Bezgina, E. Y. Parnyshkova, Ivan M. Vikhlyantsev, L. L. Pavlik, D. A. Moshkov, L. I. Kazakova, and N. R. Tiras

Subjects
Cell, Biophysics, Histology, Biology, Stain, Cell biology, Cytosol, medicine.anatomical_structure, Dopamine, medicine, Ultrastructure, Viability assay, Actin, medicine.drug
Abstract

Viability, histology and ultrastructure of normal cells and cells of different degrees of malignancy after interaction with dopamine as well as the ability of these cells and isolated G-actin in model experiments to stain by Falck technique were studied. It is shown that dopamine, virtually having no effect on the viability of the “normal” non-tumorigenic transformed cells, noticeably reduces cell viability of slightly tumorigenic cells, causes a significant reduction in viability of attachable cancerous cells and a very significant decrease in cell viability of cancerous cells growing in suspension. The intensity of fluorescence of the cytosol in cells treated with dopamine, has been very high and varied in different cultures, and that of isolated actin directly depended on its concentration. Common to all cell morphological feature of damage from the action of dopamine and the putative substrate of fluorescence was actodopamine filaments network strands (identified on the structure and size), which appears in the cytosol loci, where they were absent in control. The data show that dopamine can be used as an oncotherapeutic remedy and diagnostic tool interacting with G-actin as a cellular target.

Published
2012
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10. Ultrastructure of Mauthner Neurons in Optokinetic Stimulation and Enucleation of the Eye

Author

E. N. Bezgina, I. B. Mikheeva, R. Sh. Shtanchaev, D. A. Moshkov, E. E. Grigorieva, N. Yu. Tsaplina, G. Z. Mikhailova, and N. R. Tiras

Subjects
Chemistry, General Neuroscience, medicine.medical_treatment, Dendrite, Enucleation of the eye, Mauthner cell, medicine.anatomical_structure, Ultrastructure, medicine, Excitatory postsynaptic potential, Functional activity, Cytoskeleton, Neuroscience, Optokinetic stimulation
Abstract

Previous studies have shown that contralateral (to the preferred turning side) optokinetic stimulation and ipsilateral enucleation of the eye lead to significant (by a factor of 2–4) decreases in the volume of the ventral dendrite (VD) in one of the two Mauthner neurons (MN) of the goldfish, which becomes functionally more active. We report here our studies of MN ultrastructure after these unilateral influences from the visual system. In both cases, the whole length of the shrunken VD showed emptying of synapses and compaction of its cytoskeleton as compared with the cytoskeleton of the VD of the contralateral MN and the cytoskeleton of the lateral dendrites and bodies of both neurons. It is suggested that emptied synapses are part of the excitatory visual input and that the control of the functional activity of MN via VD involves both cytoskeletal and synaptic mechanisms.

Published
2012
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11. Correlation between the Sizes of Individual Parts of Mauthner Neurons in Goldfish and Their Integral Function after Enucleation of the Eye

Author

N. R. Tiras, G. Z. Mikhailova, R. Sh. Shtanchaev, D. A. Moshkov, and E. E. Grigorieva

Subjects
Correlation, chemistry.chemical_compound, Mauthner cell, Chemistry, General Neuroscience, medicine.medical_treatment, medicine, Adaptive change, Sensory system, Enucleation of the eye, Neurotransmitter, Neuroscience, Motor asymmetry
Abstract

Three-dimensional reconstruction was used to study the structural correlates of significant increases in the activity of Mauthner neurons (MN) deafferented after unilateral enucleation of the eye evidenced by an irreversible shift in motor asymmetry in goldfish towards the “blind” side. The results showed that in some cases, the dominance of the MN correlated significantly with a decrease in the volume of its ventral dendrite, while in others, it correlated with an increase in the sizes of the body and the lateral dendrite. Both structural signs appeared to result from local redistribution of the neurotransmitter balance due to the tension of the undamaged sensory inputs. Overall, the results demonstrated that prolonged adaptive changes in the behavior of the fish may be regulated by specific morphological rearrangements of MN at the level of individual dendrites acting via feedforward and feedback mechanisms.

Published
2011
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12. Changes in the Motor Asymmetry and Structure of Mauthner Neurons of the Goldfish Resulting from Unilateral Visual Deprivation

Author

E. E. Grigorieva, D. A. Moshkov, N. R. Tiras, R. Sh. Shtanchayev, and G. Z. Mikhailova

Subjects
Physiology, General Neuroscience, medicine.medical_treatment, Enucleation, Inversion (evolutionary biology), Dendrite, Enucleation of the eye, Anatomy, Biology, chemistry.chemical_compound, medicine.anatomical_structure, Mauthner cell, Sinistral and dextral, chemistry, medicine, Neuron, Neurotransmitter
Abstract

We studied the effects of unilateral enucleation of the eye on the motor asymmetry of goldfish fries and morphometric characteristics of their Mauthner neurons, MNs (data of 3D reconstruction using serial slices). Enucleation of the right or left eye in ambidextral fishes resulted in stable preference of turnings during swimming toward the side of visual deafferentation and in a shift of the initial motor asymmetry coefficient (MAC) by 25%, on average. Ipsilateral enucleation of the eye in dextral and sinistral fishes intensified the initial motor asymmetry by 20%. Contralateral enucleation of the eye in dextral and sinistral fishes induced inversion of the motor asymmetry with a decrease in the MAC by 50%, on average. All operated fishes stably (within 3 months or more) preferred to turn toward the side of the enucleated eye. Morphological measurements showed that the size of the ventral dendrite of the MN contralateral with respect to the side of enucleation noticeably decreased. At the same time, this neuron (according to a shift in the motor asymmetry of the fish) became the functionally dominant unit. These data agree with the earlier supposition on a reciprocal relation between the level of functional activity of the MN and the size of its ventral dendrite. Selective changes in the dimension of the ventral dendrite of the MN receiving visual inputs probably resulted from the action of some endogenous trophic factor. The effect of this factor was enhanced after enucleation of the eye and the corresponding dysfunction of the contralateral visual input. A specific local change in the balance of neurotransmitter influences upon the MN ventral dendrite can play the role of such a factor. From the neurophysiological aspect, a decrease in the size of the ventral MN dendrite is a primary link in the chain of events resulting in modification of behavior; it leads to intensification of the integral functional activity of the MN and a shift of the motor asymmetry of the fish compensating, in such a way, the effect of unilateral visual deprivation.

Published
2010
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13. Effects induced by an actin-polymerizing peptide in goldfish mauthner neurons

Author

D. A. Moshkov, G. Z. Mikhailova, and N. R. Tiras

Subjects
Actin remodeling of neurons, Mauthner cell, Physiology, Cytoplasm, General Neuroscience, Ultrastructure, Biophysics, Long-term potentiation, Stimulation, Biology, Actin cytoskeleton, Neuroscience, Actin
Abstract

In goldfishes, we studied (i) manifestations of functional activity of Mauthner neurons (MNs) reflected in motor behavior and (ii) changes in 3-D morphometry (ratio of volumes) and ultrastructure of MNs after applications of an actin-polymerizing peptide obtained from scorpion venom and after vestibular rotational stimulations (trainings) inducing natural modification of functions of the MNs (adaptation). In MNs subjected to application of the peptide, the increase in the functional resistance and morphological stability caused by long-lasting stimulation directly depended on the dose of the applied peptide or on the effectiveness of trainings, whereas in intact and control MNs such stimulation resulted in significant decreases in the activity and volumes of these cells. At the ultrastructure level, both applications of the peptide and trainings caused the formation of extensive bundles of actin filaments (“stress-fibers”) in the cytoplasm of MNs and led to an increase in the dimension of desmosome-like contacts (DLCs) in afferent synapses. At chemical synapses, the effect looked like a reciprocal decrease in the length of the active zones (a structural sign of long-term depression, LTD), while at mixed synapses this was manifested in an increase in the number of fibrillar bridges in the gaps of DLCs (a structural sign of long-term potentiation, LTP). The data obtained allow us to hypothesize that LTD of the efficacy of transmission through chemical synapses is involved in the formation of the adaptation state of the MNs and that polymerization of actin in the cytoplasm and DLCs underlies the mechanism of LTD and adaptation. The development of ultrastructural manifestations of LTP at mixed synapses after polymerization of actin by the peptide, which is related to a reciprocal increase in the efficacy of “mixed” afferent inputs, explains the maintenance of a high integral level of activity of the MNs, despite a drop in the functional activity of “ chemical” afferent inputs. Therefore, the actin cytoskeleton plays a clearly significant role in the maintenance of the balance of excitation at the neuronal level.

Published
2006
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14. Morphofunctional effects of applications of glutamate and dopamine on the goldfish Mauthner neurons

Author

E. N. Bezgina, D. A. Moshkov, L. L. Pavlik, V. S. Shubina, Udal'tsov Sn, N. R. Tiras, and G. Z. Mikhailova

Subjects
biology, Physiology, General Neuroscience, Arp2/3 complex, Actin remodeling, macromolecular substances, Actin cytoskeleton, Filamentous actin, Cell biology, Actin remodeling of neurons, Mauthner cell, biology.protein, Cytoskeleton, Actin
Abstract

In the goldfish, we studied the effects of intramedullar applications of glutamate (Glu), dopamine (DA), and of long-lasting rotational stimulation on the functional activity, dimensional characteristics, and ultrastructure of Mauthner neurons (MNs). Applications of Glu, especially when combined with rotational stimulation, were found to result in suppression of the function of MNs, in a decrease in their dimensions and lengths of desmosome-like contacts (DLCs, whose structure is determined by filamentous actin) in afferent mixed and chemical synapses, and in destruction of actin microfilaments in the cytoskeleton of MNs. Applications of DA, vice versa, induced an increase in the resistance to the effects of long-lasting stimulation and stabilized the dimensions of MNs; the length of DLCs increased in afferent synapses of both the above types, and the number of fibrillar actin bridges in the DLC cleft of mixed synapses also increased. Bundles of the actin filaments, which were preserved after stimulation, appeared in the cytoskeleton of MNs. Testing of the action of neurotransmitters on actin preparations in vitro showed that Glu entirely depolymerizes filamentous actin, while DA, vice versa, polymerizes monomeric actin. Thus, the Glu-and DA-induced reactions are similar in their types and are of a reciprocal nature both in the actin cytoskeleton of MNs in situ and in purified actin in vitro; these effects correlate with suppression of the functional state of MNs under the influence of Glu and with stabilization of this state under the influence of DA. These results agree with the concept on the roles of depolymerization and polymerization of actin in changes of the morphofunctional state of MNs and show that actin of the cytoskeleton of MNs is a cellular target for the actions of Glu and DA. The similarity between the effects of tested neurotransmitters on actin in MNs in situ and in cell-free preparations in vitro allows us to hypothesize that these transmitters can penetrate into the neuron.

Published
2006
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15. Morphological parameters of mauthner neurons of goldfishes with modified asymmetry of motor behavior

Author

N. R. Tiras, V. D. Pavlik, G. Z. Mikhailova, E. E. Grigorieva, I. M. Santalova, and D. A. Moshkov

Subjects
Structural asymmetry, Physiology, General Neuroscience, media_common.quotation_subject, Motor behavior, Anatomy, Asymmetry, medicine.anatomical_structure, Mauthner cell, medicine, Soma, Axon, Psychology, Motor asymmetry, media_common, Initial segment
Abstract

We examined the morphological peculiarities of Mauthner neurons, MNs, in goldfishes with a phenotypically different or an experimentally modified preference to perform rightward vs leftward turnings in the course of motor behavior; this preference was characterized by values of the motor asymmetry coefficient (MAC). 3D reconstruction of MNs was performed based on several histological sections; volumes of the soma, lateral and ventral dendrites (LD and VD, respectively), initial segment of the axon, as well as full volumes of the right and left neurons, were calculated. Differences between the above parameters were expressed as structural asymmetry coefficients (SACs). It was shown that clear orientation asymmetry of motor behavior of the fish is accompanied by differences in the dimensions of MNs and their compartments; MNs localized contralaterally with respect to the preferred turning side were considerably bigger than ipsilateral neurons. Experimental influences inducing inversion of the motor asymmetry of fishes inverted structural asymmetry of their MNs. In fishes with no phenotypical preference of the turning side and in individuals whose motor asymmetry was smoothed due to experimental influences (rotational stimulations), structural asymmetry of the MNs was also smoothed. Changes of the structural proportions developed, as a rule, due to decreases in the dimensions of one or both MNs and their compartments. The MAC value was in direct correlation with the value of SAC of the MNs and with values of this coefficient for the soma and the sum soma + LD. At the same time, reciprocal relations were found for the MAC and structural asymmetry of the VD; the decrease in the volume of VD was related to an increase in the preference of the contralateral turning side by the fish, and vice versa. In general, the results of our study demonstrate that both morphological and functional peculiarities of MNs correlate to a significant extent with such a form of motor behavior of fishes as realization of spontaneous turnings.

Published
2006
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16. Rotational stimulation-related changes of the motor asymmetry in the goldfish

Author

G. Z. Mikhailova, D. A. Moshkov, E. E. Grigor’yeva, and N. R. Tiras

Subjects
Vestibular system, Physiology, General Neuroscience, media_common.quotation_subject, Stimulation, Anatomy, Asymmetry, Sinistral and dextral, Mauthner cell, sense organs, Clockwise, Psychology, Neuroscience, Motor asymmetry, Medulla, media_common
Abstract

We studied changes in the motor asymmetry of the goldfish induced by single-session long-lasting vestibular stimulations (clockwise and counter clockwise rotations around the rostro-caudal body axis) and repetitive everyday short sessions of such stimulation (training); the latter mode led to the development of adaptation (resistance to fatigue). Rotational stimulation of different durations and directions elicited effects of different patterns and intensities. Such stimulation enhanced or, vice versa, smoothed the motor asymmetry in “dextral” and “ sinistral” fishes, up to full symmetry or even a change of the preferred turning direction. Adaptation to unilateral rotational stimulation allows an experimenter to selectively and gradually induce the resistivity of the left-or right-ward asymmetry to fatigue effects. Earlier, we found that the motor asymmetry in the goldfish, which is determined by the functional asymmetry of the brain, correlates with the morphological asymmetry of Mauthner neurons localized in the medulla in a mirror manner and playing a crucial role in the control of turnings in the course of locomotion (swimming). Experimental rotational stimulation-induced gradual modification of the motor asymmetry in the goldfish can serve as a physiological model for more detailed studies of the structural base of the functional brain asymmetry and some mechanisms of adaptation on the level of single neurons.

Published
2005
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17. Ultrastructural Changes in the Mixed Synapses of Mauthner Neurons Related to Long-Term Potentiation and Natural Modification of the Motor Function

Author

L. L. Pavlik, Dzeban Da, D. A. Moshkov, I. B. Mikheeva, and N. R. Tiras

Subjects
Vestibular system, Nervous system, Physiology, General Neuroscience, Long-term potentiation, Stimulation, Biology, Coupling (electronics), medicine.anatomical_structure, Mauthner cell, nervous system, medicine, Neuronal memory allocation, Neuroscience, Actin
Abstract

We examined changes in the ultrastructure of afferent mixed synapses on the membrane of Mauthner neurons (M cells) of the goldfish, which were related to two functional states, long-term potentiation (LTP) of the electrotonic response (a model form of the memory trace) and adaptation (resistivity to fatigue resulting from long-lasting motor training and considered a natural form of the memory trace manifested on the neuronal level). LTP was induced in medullary slices using high-frequency electrical stimulation of the afferent input. Adaptation was produced using natural vestibular stimulation (everyday motor training, which modified motor behavior of the fish and function of the M cell). It was supposed that if the LTP phenomenon is involved in the formation of natural memory, both the adaptation and the LTP states should be accompanied by similar specific structural modifications. Indeed, it was found that in both cases the number of fibrillar bridges in the gaps of desmosome-like contacts (DLC) in the mixed synapses on the M cell surface demonstrated an about twofold increase. These bridges are known to include actin filaments, which function as conductors of cationic signals; thus, the LTP-related increase in the density of bridges corresponds to increased efficacy of electrotonic coupling via mixed synapses. Such a structural correlate of LTP, which probably has the same functional significance in mixed synapses of the “adapted” M cells, allows us to suppose that LTP is a natural property of the nervous system. The LTP-type intensification of the relay function of mixed synapses, which corresponds to adaptation, is probably a compensatory rearrangement allowing M cells to maintain some balance of the synaptic influences and, at the same time, to remain in a stable and plastic state; this is necessary for stable functioning under changing environmental conditions.

Published
2003
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18. [Untitled]

Author

D. A. Moshkov, Mukhtasimova Nf, I. B. Mikheeva, L. L. Pavlik, Dzeban Da, and N. R. Tiras

Subjects
Mauthner cell, medicine.anatomical_structure, Desmosome, General Neuroscience, Afferent, medicine, Biology, Neuroscience
Published
2002
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20. Central asian black scorpion venom protects Mauthner neurons from damage due to prolonged stimulation

Author

V. N. Pashkov, N. R. Tiras, D. A. Moshkov, Grishin Ev, and I. B. Mikheeva

Subjects
Neurons, Medulla Oblongata, Behavior, Animal, General Neuroscience, Scorpion, Scorpion Venoms, Venom, Biology, Electric Stimulation, Microscopy, Electron, Mauthner cell, Goldfish, biology.animal, Synapses, Animals, Prolonged stimulation, Vestibule, Labyrinth, Neuroscience
Published
1999
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21. Ultrastructural changes in afferent mixed synapses in conditions of long-term potentiation of electrotonic responses on mauthner neurons in incubated fragments of the goldfish medulla oblongata

Author

D. A. Moshkov, Mukhtasimova Nf, L. L. Pavlik, I. D. Pakhotina, and N. R. Tiras

Subjects
Neurons, Medulla Oblongata, General Neuroscience, Long-Term Potentiation, Long-term potentiation, In Vitro Techniques, Biology, Synaptic Transmission, Electric Stimulation, Electrophysiology, Microscopy, Electron, Mauthner cell, Goldfish, Afferent, Synapses, Medulla oblongata, Ultrastructure, Animals, Neuroscience
Published
1999
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22. Ultrastructure of Mauthner Cells in Fish Adapted to Long-Duration Vestibular Stimulation and the Effect of Ethanol

Author

N. R. Tiras, Georgy V. Zherdev, and D. A. Moshkov

Subjects
Motor Activity, Biology, Article, lcsh:RC321-571, Myelin, chemistry.chemical_compound, Mauthner cell, Goldfish, medicine, Animals, Cytoskeleton, lcsh:Neurosciences. Biological psychiatry. Neuropsychiatry, Short duration, Vestibular system, Medulla Oblongata, Ethanol, Desmosomes, Adaptation, Physiological, Actins, Microscopy, Electron, medicine.anatomical_structure, Neurology, chemistry, Synapses, Medulla oblongata, Biophysics, Ultrastructure, Vestibule, Labyrinth, Neurology (clinical), Neuroscience
Abstract

Adaptation or resistance of fish Mauthner cells (M-cells) to long duration (2 h) vestibular stimulation (LDS)was produced by daily brief and gradually increasing vestibular stimulation (training). The LDS resistance was accompanied by an increase in the number of desmosome-like junctions in the afferent axosomatic synapses. F-actin, the main component of desmosome-like contacts, has been suggested to be responsible for the increased resistance of M-cells to LDS. The purpose of the present study was to investigate the capacity of M-cells to adapt to LDS under the influence of ethanol, which alters the content of F-actin in cells. The experiments were carried out in goldfish fry. Vestibular stimulation (training and LDS) was performed in special drums that were rotated in two planes. The training time was increased from 1 min on day 1 to 30 min on day 30. For ethanol exposure, fish were immersed daily in a 2% ethanol solution for 20 min. To assess the level of resistance to LDS, motor activity indicating the functional state of M-cells was evaluated before and after LDS. The results show that exposure to ethanol reduces the resistance to LDS in both untrained and trained fish. Electron microscopic data demonstrated some structural changes in the synaptic endings located on M-cell soma in ethanol-exposed fish. Wrapping of boutons by cytoplasmic out- growths and myelin- like structures was observed. Morphometric analysis revealed that exposure to ethanol without training decreases the number of desmosome-like contacts, probably due to ethanol-induced depolymerization of cytoskeletal actin. Ethanol exposure also partly suppressed the increase in the number of desmosome-like contacts that occurs as a result of training. In ethanol-treated trained fish, however, a concomitant increase in the length of desmosome-like contacts was observed. As training alone leads to the formation of additional desmosome-like contacts of standard length, it is possible that although a sufficient amount of such structures cannot be formed in the M-cells of ethanol-exposed trained fish, the existing contacts can be elongated. Thus, possibly changes of the actin state are involved in the adaptation of M-cells to LDS.

Published
1999
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24. [Induction of neuron morphological resistance to beta-amyloid]

Author

N A, Kokanova, G Z, Mikhaĭlova, R Sh, Shtanchaev, N R, Tiras, and D A, Moshkov

Subjects
Levodopa, Neurons, Amyloid beta-Peptides, Polymers, Dopamine, Goldfish, Animals, Brain, Amyloidosis, Vestibule, Labyrinth, Adaptation, Physiological, Peptide Fragments
Abstract

The effect of training adaptive vestibular stimulations on goldfish Mauthner neurons (MN) function and three-dimensional morphology was studied in experimental amyloidosis caused by application of aggregated beta-amyloid protein (Abeta25-35). It was found that as compared with control, adapted (trained) MN gained significant resistance to Abeta25-35. Taking into consideration the key role of dopamine in MN adaptation to sensory stimulations, its effect on the development of model amyloidosis was studied. It was shown that the application of dopamine onto MN as well as the increase of its concentration in brain by means of L-dopa protected MN structure and function against pathogenic influence of Abeta25-35. Using electron microscopy it was shown that dopamine protective action on neurons was due to its ability to dissociate polymer amyloid molecules into short inactive fragments.

Published
2012

25. [Ultrastructure of Mauthner neurons after optokinetic stimulation and eye enucleation]

Author

I B, Mikheeva, N Iu, Tsaplina, E E, Grigor'eva, E N, Bezgina, R Sh, Shtanchaev, G Z, Mikhaĭlova, N R, Tiras, and D A, Moshkov

Subjects
Motor Neurons, Behavior, Animal, Goldfish, Animals, Dendrites, Motor Activity, Eye Enucleation, Functional Laterality, Photic Stimulation, Swimming
Abstract

It was previously shown that the contralateral (relative to preferred side of turns) optokinetic stimulation and ipsilateral eye enucleation cause a significant, 2- to 4-fold reduction of the ventral dendrite (VD) volume in one of two goldfish Mauthner neurons (MN) that becomes more active functionally. In this study, we investigated the MN ultrastructure after mentioned unilateral visual effects. In both cases, devastation of the afferent synapses was detected along the full length of the reduced VD, with simultaneous compaction of its cytoskeleton, in contrast to those of VD of the contralateral MN and of lateral dendrites and cell bodies of both neurons. It is suggested that the depleted synapses belong to the excitatory visual afferent input, and both cytoskeletal and synaptic mechanisms are involved in the regulation of MN functional activity through VD.

Published
2011

26. [Correlation between the sizes of the individual parts of goldfish Mauthner neuron and its integral function after eye enucleation]

Author

E E, Grigor'eva, R Sh, Shtanchaev, G Z, Mikhaĭlova, N R, Tiras, and D A, Moshkov

Subjects
Behavior, Animal, Goldfish, Animals, Dendrites, Organ Size, Eye, Eye Enucleation
Abstract

Using the method of 3D reconstruction, the structural correlates of significantly increased functional activity of denervated Mauthner neuron (MN) were studied after the unilateral eye enucleation, that resulted in the irreversible shift of the goldfish motor asymmetry to a "blind" side. It was established that in some cases the functional dominance of MN was significantly correlated with the reduction of the volume of its ventral dendrite, while in the other cases it was correlated with the increase in sizes of its soma and the lateral dendrite. Both structural features, probably, were caused by local redistribution of the neurotransmitters due to the stress of sensory inputs that remained undamaged. Thus, it was demonstrated that the prolonged adaptive changes in goldfish behavior could be regulated by means of specific morphological reorganizations of MN at the level of their individual dendrites by the principle of feedback or feedforward mechanisms.

Published
2011

27. Morphofunctional changes in goldfish Mauthner neurons after application of beta-amyloid

Author

E. N. Bezgina, N. R. Tiras, R. Sh. Shtanchaev, N. A. Kokanova, D. A. Moshkov, and G. Z. Mikhailova

Subjects
Motor Neurons, Structural asymmetry, Peptide fragment, Amyloid beta-Peptides, General Neuroscience, Amyloidosis, Movement, Dystrophy, Biology, medicine.disease, Fibril, Functional Laterality, Peptide Fragments, Muscle hypertrophy, Mauthner cell, β amyloid, Goldfish, Biophysics, medicine, Animals, Neuroscience
Abstract

The effects of applying aggregated beta-amyloid peptide fragment 25-35 on the three-dimensional structure and volume of Mauthner neurons (MN) and on motor asymmetry were assessed in goldfish using reconstructions based on serial histological sections. These experiments showed that the motor asymmetry of the fish was stable in the intact state and in controls and correlated tightly with structural asymmetry of neurons. beta-Amyloid produced large changes or inversion in motor asymmetry, which did not coincide with or even contradicted the structural asymmetry of MN. This occurred as a result of marked dystrophy or, conversely, hypertrophy of individual neurons and their individual dendrites, with changes in their proportions. It is suggested that the harmful action of beta-amyloid on MN structure and the discordant ("incorrect") behavior of the fish may result from mechanical deformation evoked by its tape-like fibrils. Overall, the results lead to the conclusion that MN provide a suitable system for studying the structural aspects of amyloidosis.

Published
2009

28. The structure of mixed synapses in Mauthner neurons during exposure to substances altering gap junction conductivity

Author

L. L. Pavlik, D. A. Moshkov, Udal'tsov Sn, E. N. Bezgina, N. R. Tiras, and I. B. Mikheeva

Subjects
Ecdysone, Chlorpromazine, Dopamine, chemistry.chemical_compound, Mauthner cell, Microscopy, Electron, Transmission, Goldfish, medicine, Animals, Actin, Neurons, Chemistry, General Neuroscience, Gap junction, Electric Conductivity, Gap Junctions, Desmosomes, In vitro, Mechanism of action, Biochemistry, Synapses, Ultrastructure, Biophysics, Dopamine Antagonists, medicine.symptom, medicine.drug
Abstract

The aim of the present work was to study the effects of dopamine, ecdysone, and chlorpromazine, substances which alter the conductivity of gap junctions (GJ), on the ultrastructure of mixed synapses in goldfish Mauthner neurons. These studies showed that dopamine, which increased the electrical conductivity of mixed synapses, appeared to target desmosome-like contacts (DLC). Hypertrophy of DLC, along with increases in the numbers of bridges within their clefts, showed that the mechanism by which dopamine increased electrical conductivity involved neuronal actin. This was indicated by the transformation of isolated monomeric muscle actin into polymerized actin in the presence of dopamine. Conversely, GJ were degraded by dopamine. Ecdysone, which also increased GJ conductivity, altered GJ structure, increasing the numbers of GJ at the attachment zone and decreasing the sectional length, but had virtually no effect on DLC structure. Ecdysone also showed no interaction with DLC in in vitro conditions. The mechanism of action of ecdysone is thus associated primarily with GJ function. Chlorpromazine, which decreased GJ conductivity, partially or completely degraded the fibrillar juxtamembrane material of DLC, preventing actin polymerization, with corresponding in vitro effects, but produced no changes in GJ. The mechanism of its action therefore appears to be based on changes in the state of neuronal actin.

Published
2005

29. Involvement of actin in the electrotonic conductivity of mixed synapses in Mauthner neurons in the goldfish

Author

Mukhtasimova Nf, D. A. Moshkov, N. R. Tiras, L. L. Pavlik, Dzeban Da, and P. I. Pakhotin

Subjects
Phalloidin, Phalloidine, Polymers, Long-Term Potentiation, Neural Conduction, Stimulation, macromolecular substances, Stimulus (physiology), Biology, Conductivity, Synaptic Transmission, Metencephalon, Actin remodeling of neurons, chemistry.chemical_compound, Mauthner cell, Goldfish, Animals, Actin, Neurons, General Neuroscience, Desmosomes, Mycotoxins, Actins, Electric Stimulation, chemistry, Synapses, Biophysics, Ultrastructure, sense organs, Neuroscience
Abstract

The effects of phalloidin, a preperation which highly specifically and selectively polymerizes actin and which binds to actin, on the electrotonic conductivity and structure of mixed synapses were studied in goldfish Mauthner neurons (MN). These experiments showed that paired subthreshold electrical stimulation of the afferent input in the presence of phalloidin led to increases in the amplitude of MN responses to the second stimulus by an average of 80%. In controls, this amplitude increased by only 10% and only when suprathreshold stimuli were used, while subthreshold stimuli were ineffective. We regard these results as demonstrating increases in the conductivity of mixed synapses, this being induced by polymerization of actin. At the ultrastructural level, application of phalloidin to MN and their mixed synapses induced increases in the sizes and numbers of actin-containing desmosome-like contacts, and in the numbers of fibrillar bridges in the clefts of these contacts. Use of colloidal gold as a label for phalloidin demonstrated that bridges were made of actin. The interdependent morphofunctional changes seen in mixed synapses provide grounds for suggesting a role for actin in the conduction of the electrotonic signal through mixed synapses. The structural substrate for this process may be provided by bridges in the clefts of desmosome-like contacts.

Published
2004

30. Morphofunctional changes in adapted Mauthner neurons in goldfish after prolonged orthodromic stimulation of the auditory nerve in vitro

Author

P. I. Pakhotin, I. B. Mikheeva, N. R. Tiras, and D. A. Moshkov

Subjects
Neurons, Medulla Oblongata, Rotation, Chemistry, General Neuroscience, Stimulation, Neural Inhibition, Anatomy, Adaptation, Physiological, In vitro, Electric Stimulation, Mauthner cell, Goldfish, Animals, Vestibule, Labyrinth, Orthodromic, Neuroscience, Cochlear Nerve, Evoked Potentials
Published
2004

31. Correlation between the sizes of Mauthner neurons and the preference of goldfish to turn to the right or left

Author

G. Z. Mikhailova, V. D. Pavlik, D. A. Moshkov, and N. R. Tiras

Subjects
media_common.quotation_subject, Movement, Statistics as Topic, Biology, Axon hillock, Asymmetry, Correlation, Turn (biochemistry), Mauthner cell, Goldfish, medicine, Image Processing, Computer-Assisted, Animals, Dominance, Cerebral, media_common, Cell Size, Motor Neurons, Medulla Oblongata, Behavior, Animal, General Neuroscience, Anatomy, medicine.anatomical_structure, nervous system, Water channel, Medulla oblongata, Neuron
Abstract

Three-dimensional computer reconstruction working from serial histological sections was used to study the morphology of the right and left Mauthner neurons (MN) in goldfish fry showing marked preferences to turn stably to the right or left in a narrow water channel or showing no asymmetry in their choice of side during turns. Visually, fish with left-sided motor asymmetry had larger MN on the right side, while fish with right-sided motor asymmetry had larger MN on the left side. Fish with symmetrical turns to the right and left showed no differences in MN size. Quantitative assessment of the MN of fish with preferences for turns to one side or the other revealed significant differences in the sizes of the somatic part, the axon hillock, and the axons of neurons located on the contralateral side of the medulla oblongata. Analysis of the statistical relationships between the functional (motor) asymmetry of fish and the morphological asymmetry of the somatic parts of MN in the same fish revealed a stable correlation (0.69) between these measures. Given that MN initiate unilateral turns of the body in free movement, the data obtained here lead to the conclusion that the larger neuron is more frequently activated in natural conditions as compared with the smaller, contralateral, neuron.

Published
2004

32. [Effect of polypeptides from scorpion venom on morpho-functional changes of the incubated Mauthner neurons in goldfish]

Author

N R, Tiras, S N, Udal'tsov, I B, Mikheeva, P I, Pakhotin, and D A, Moshkov

Subjects
Microscopy, Electron, Goldfish, Animals, Brain, Scorpion Venoms, Neurons, Afferent, Rabbits, Muscle, Skeletal, Peptides, Evoked Potentials, Actins, Electric Stimulation
Abstract

Using the electron microscopical method of negative staining it was shown that one of the fractions obtained from scorpion venom directly interacts with monomeric chromatographically pure actin causing its polymerization and transformation from globular into fibrillar form. The effect of long-term orthodromic stimulation on evoked electric activity and on the ultrastructure of Mauthner neurons (MN) in the goldfish hindbrain slices incubated in vitro was studied after the application of this venom fraction. The peptides of this fraction were shown to stabilize the amplitude of MN evoked electric responses to fatigue and to protect the ultrastructure of afferent chemical synapses and MN themselves from stimulation-induced injuries. Increase in morpho-functional resistivity is accompanied by the stabilization of specialized synaptic structures--actin-containing desmosome-like junctions. These data suggest the direct effect of peptides from scorpion venom fraction on actin component of MN cytoskeleton and show the perspective for their application as pharmacological tools capable of penetration into the living cells that may be used for investigation of the role of actin in the mechanisms of adaptation and memory.

Published
2003

33. [Involvement of actin in electrotonic conductivity in the mixed synapses of goldfish Mauthner neurons]

Author

L L, Pavlik, N R, Tiras, N F, Mukhtasimova, P I, Pakhotin, D A, Dzeban, and D A, Moshkov

Subjects
Phalloidine, Goldfish, Synapses, Electric Conductivity, Neural Conduction, Animals, Desmosomes, Neurons, Afferent, Evoked Potentials, Actins, Electric Stimulation
Abstract

The effect of highly specific and selective actin-polymerizing and labelling agent, phalloidin, on electrotonic conductivity and structure of the mixed synapses of goldfish Mauthner neurons (MN) was studied. It was shown that the paired subthreshold electrostimulation of afferent input against a background of phalloidin application resulted in the average 80% increase of the amplitude of MN response to the second stimulus. In control group it increased by only 10% and was observed only after suprathreshold stimulation, while subthreshold stimuli were ineffective. We interpret these data as the manifestation of increased conductivity of the mixed synapses, induced by actin polymerization. At the ultrastructural level, phalloidin application at MN and their mixed synapses increased the size and number of actin-containing desmosome-like junctions, as well as the number of fibrillar bridges crossing their cleft. Using the phalloidin-colloid gold marker, the actin nature of these bridges was demonstrated. Interdependent morpho-functional changes found in the mixed synapses, provide the indication of actin involvement in the conduction of electrotonic signal through the mixed synapse. The bridges crossing the cleft of desmosome-like junction could be the structural substrate of this process.

Published
2003

35. [Structural differences between the desmosome-like contacts in the chemical and afferent synapses of Mauthner neurons in the goldfish]

Author

D A, Moshkov, N R, Tiras, L L, Pavlik, D A, Dzeban, I B, Mikheeva, and N F, Mukhtasimova

Subjects
Neurons, Afferent Pathways, Goldfish, Synapses, Neural Conduction, Animals, Gap Junctions
Abstract

Comparative ultrastructural investigation of the desmosome-like contacts at chemical and mixed afferent synapses of the goldfish Mauthner neurons was carried out. It was revealed that these contacts at mixed synapses differed from those at chemical ones by thin transverse fibrillar bridges which cross the gap and connect two adjoining membranes of the junction. We suppose that these crossbridges together with gap junctional connexons may serve as a substrate for electronic coupling at mixed synapses demonstrated earlier.

Published
2001

36. [Desmosome-like contacts of Mauthner neurons as targets of scorpion venom]

Author

I B, Mikheeva, N R, Tiras, D A, Moshkov, V I, Pashkov, and E V, Grishin

Subjects
Medulla Oblongata, Microscopy, Electron, Goldfish, Animals, Scorpion Venoms, Desmosomes, Neurons, Afferent, In Vitro Techniques
Abstract

Desmosome-like contacts (DLC) in afferent chemical synapses of the Mauthner cells (MC) were investigated after application of low and high molecular mass peptide fractions 6 and 9, correspondingly, from the Central Asiatic black scorpion Orthochirus scrobiculosus. Besides, the DLC were examined in condition of a training induced morpho-functional stability of the MC (adaptation) mediated by transformation of actin monomers into polymers. In addition, the structure of DLC was studied after cytochalasin application which disrupts F-actin. Fraction 6 was shown to increase the length of DLC and osmiophily of fibrous material. Similar changes in DLC were caused by adaptation. Fraction 9 decreased the osmiophily of the fibrous material, made DLC asymmetric, but did not influence their length. Similar changes in DLC were seen also after cytochalasin D application. Taking into account our previous data on the role of F-actin in the MC functioning, which were obtained following specific pharmacological treatments, the similarity of ultrastructural changes in DLC after both adaptation and fraction 6 application, on the one hand, and after both cytochalasin D and fraction 9 application, on the other one, enabled us to suggest that these fractions may contain peptides able to exert influence of the actin cytoskeleton.

Published
2000

38. [Experimentally induced actin depolymerization disrupts the adaptive state of a neuron]

Author

L L, Pavlik, N R, Tiras, and D A, Moshkov

Subjects
Neurons, Cytochalasin D, Goldfish, Physical Stimulation, Pons, Animals, DNA, Vestibule, Labyrinth, Adaptation, Physiological, Actins, Nucleic Acid Synthesis Inhibitors
Abstract

The state of filament actin in Mauthner neuron (MN) of gold-fish adapted to long-term natural stimulation was investigated after introduction of actin-depolymerizing cytochalasin D. Cytochalasin was demonstrated to cause almost complete disappearance of long actin bundles that were characteristic for the cytoplasm of adapted fish and were absent from MN of intact fish. Polymeric actin supporting the cytoskeleton integrity was suggested to be involved in mechanisms underlying the increase of MN resistance extreme loads.

Published
1998

39. In vitro long-term potentiation of electrotonic responses of goldfish mauthner cells is accompanied by ultrastructural changes at afferent mixed synapses

Author

D. A. Moshkov, Pavlik Ll, Mukhtasimova Nf, N. R. Tiras, and I. D. Pakhotina

Subjects
Medulla Oblongata, Neuronal Plasticity, General Neuroscience, Long-Term Potentiation, Gap junction, Electric Conductivity, Long-term potentiation, Stimulation, Neurotransmission, Biology, In Vitro Techniques, Electric Stimulation, Membrane Potentials, Synapse, Electrophysiology, Mauthner cell, Goldfish, Synapses, Medulla oblongata, Biophysics, Animals, Neurons, Afferent, Neuroscience
Abstract

The potentiated afferent mixed synapses of the Mauthner cells of fry and adult goldfish in stumps of the medulla oblongata incubated long-term in vitro were studied by electrophysiological and electron microscopic methods. It was shown that brief high-frequency stimulation of posterior branches of the eighth nerve induced a long-term potentiation of electrotonic transmission at large and small mixed club endings. It was about 135% upon subthreshold stimulation and about 200% upon suprathreshold stimulation. The ultrastructural analysis of ultrathin sections of potentiated mixed synaptic endings revealed an increase in the dimensions of desmosome-like contacts which was proportional to the degree of potentiation, about 135% or 200%, depending on the type of stimulation. The dimensions of gap junctions remained unchanged. The dimensions of active zones at potentiated synapses were reduced two-fold as compared with their unpotentiated counterparts, irrespective of the type of stimulation. Considering that desmosome-like contacts consist predominantly of F-actin, a molecule which possesses electroconductivity, it can be assumed that this cytoskeletal protein is involved in the process of potentiation. The increase in the synapse electrical conductivity can be mediated either directly, by shunting the synaptic junction with polymer actin filaments in the region of desmosome-like contacts, or indirectly, via the interaction of actin with gap junction connections situated nearby.

Published
1998

40. [Central Asiatic black scorpion venom protect Mauthner neurons from the damaging action of prolonged stimulation]

Author

N R, Tiras, I B, Mikheeva, D A, Moshkov, V N, Pashkov, and E V, Grishin

Subjects
Neurons, Goldfish, Neurotoxins, Animals, Scorpion Venoms, Stimulation, Chemical
Abstract

The effect of long-term natural stimulation resulting in prolonged fatigue and structural disorders as well as the black scorpion poison influence on these processes were studied in gold fish Mauthner neurons (MN). The poison previously applied to MN significantly protects their function and structure from the stimulatory effect and subsequently allows the neurons to recover more fast. Appearance of numerous desmosome-like (actin-containing) contacts and proliferation of subsurface cisterns, the accumulators of calcium ions was noted immediately after the poison action and stimulation and one day later in afferent synapse ultrastructure. The poison interaction with neuronal actin, mediated by alteration of calcium-accumulating systems is probably one of the mechanisms of its protective effect.

Published
1998

41. [Ultrastructural changes in afferent mixed synapses in long-term potentiation of electrotonic responses in Mauthner neurons of goldfish medulla oblongata]

Author

D A, Moshkov, N R, Tiras, L L, Pavlik, N F, Mukhttasimova, and I D, Pakhorina

Subjects
Neurons, Afferent Pathways, Brain Mapping, Medulla Oblongata, Goldfish, Long-Term Potentiation, Synapses, Neural Conduction, Animals, Gap Junctions
Abstract

Ultrastructural synaptic features of long-term potentiation (double increase of amplitude) of electrotonic responses of the goldfish Mauthner neurons (MN) in conditions of prolonged in vitro incubation of medulla oblongata fragments were studied. Potentiation was induced by tetanization of the 8th nerve posterior roots, axonal terminals of which end on distal segments of MN lateral dendrite as piniform mixed synapses and increase their electrotonic conductivity. It was established that potentiated synapses vary from control ones in 1) greater length of synaptic contact; 20 greater (30% higher) ratio of desmosome like structures (DLS); 3) greater area of the DLS individual and total sections (two-fold increase); 4) two-fold decrease of total active zone square. Gap junction (GJ) parameters did not change. Taking an account of the proven actin origin of DLS, reports on actin filaments electron conductivity, close localization of DLS and GJ in the synaptic contact and correlative increase of synapse electric conductivity and DLS parameters. DLS contribution to electrotonic transmission is suggested, direct or mediated by actin interaction with nearby localized GJ connexons.

Published
1998

42. [The ultrastructure of Mauthner's neurons in the surviving medulla oblongata of goldfish]

Author

D A, Moshkov, N R, Tiras, L L, Pavlik, and N F, Mukhtasimova

Subjects
Neurons, Medulla Oblongata, Microscopy, Electron, Time Factors, Goldfish, Cytological Techniques, Long-Term Potentiation, Animals
Abstract

Ultrastructure of Mauthner neurons (MN) was studied in fragments of myelencephalon incubated for 0.5-1.5 hours obtained from immature gold fish. Incubation terms increase along with destruction extent and reorganization of cytoplasmic organelles and nucleus with structure of MN afferent synaptic apparatus less disturbed. Specialized synaptic contacts-active zones, cleft contacts and desmosome-like structure are well retained. The data obtained indicate MN viability during the incubation terms studied, which allows to use surviving grafts with MN as a model for studying ultrastructural bases of certain functional changes of neurons and other neurobiological problems.

Published
1996

43. [The structure of the reticulum of Mauthner's neurons in tadpoles of the clawed toad grown under increased gravitational force]

Author

D A, Moshkov, L N, Savel'eva, N R, Tiras, and E N, Kalistratova

Subjects
Neurons, Microscopy, Electron, Xenopus laevis, Larva, Animals, Endoplasmic Reticulum, Gravitation
Abstract

The ultrastructure of the Mauthner cells (M-cells) and the behaviour of Xenopus laevis tadpoles, reared from eggs under increased gravity (2.9 g) which changes the activity of an afferent vestibular input, were investigated. Besides, a study was made of tadpoles after the hindbrain ablation at earlier embryonal stages which significantly altered the microenvironment of M-cells. It is shown that experimental treatments enhance the proliferation of endoplasmic reticulum and its derivatives, so called subsurface cisterns, in the subsynaptic areas. Some structural changes of the synaptic active zones and the cytoskeleton of M-cells were also noticed. It is assumed that the development of the endoplasmic reticulum promotes an intense removal of calcium ions from subsynaptic areas. The plasticity of the endoplasmic reticulum together with other ultrastructural changes apparently stipulate the adaptation of neurons to changed conditions of functioning.

Published
1992

44. Alterations in the cytoskeleton of the goldfish Mauthner cells under various pharmacological treatments

Author

N R, Tiras, L L, Pavlik, and D A, Moshkov

Subjects
Neurons, Acoustic Stimulation, Microinjections, Goldfish, Animals, Brain, Fluorescent Antibody Technique, Vestibule, Labyrinth, Actins, Cytoskeleton
Abstract

The ultrastructural changes in the cytoskeleton of the goldfish Mauthner cells (M-cells) at various functional states induced by intracerebral microinjections of biologically active substances were studied. Under the action of kainic acid, a structural analog of the excitatory neurotransmitter of glutamate, the density of the cytoplasmic matrix increased. Cytotoxin II from the cobra toxin, which blocks acetylcholine transmission, had an opposite effect upon the M-cell cytoskeleton. Simultaneously, in some areas of the neural cytoplasm strands of an electron-dense material of various shapes appeared. They had an unique structure which did not resemble any known cytoskeleton element. The molecular composition of the strands is unknown, but similar strands appeared after injections of phalloidin or cytochalasin B, both disturbing the microfilamental component of the cytoskeleton. Decoration with myosin subfragment-1 revealed actin in intact M-cells which was organized as crossing loose filaments and bundles of parallel fibers. The morphology of the fiber bundles resembles the helical part of the strands appearing after the treatment with phalloidin, cytochalasin B, or cytotoxin II. It is suggested that the cytoplasmic matrix of M-cells is a dynamic system which responds to the functional changes by thickening or loosening of its cytoskeletal elements or by formation of new structures.

Published
1991

45. Morphofunctional Changes in Incubated Mauthner Neurons in Goldfish Treated with Peptides from Scorpion Venom.

Author

N. R. Tiras, I. B. Mikheeva, P. I. Pakhotin, D. A. Moshkov, and S. N. Udal'tsov

Abstract

Electron microscopy with negative contrast showed that direct interaction of one of the peptide fractions of scorpion venom with monomeric chromatographically pure actin led to polymerization of actin, transforming it from the globular form to the fibrillar form. The effects of prolonged orthodromic stimulation on the evoked electrical activity and ultrastructure of Mauthner neurons (MN) were studied in incubated slices of goldfish medulla oblongata in the presence of this actin-polymerizing venom fraction. Peptides in this fraction were found to stabilize the amplitude of the electrical response of MN to exhaustion and to protect the ultrastructure of afferent chemical synapses and the neurons themselves from damage induced by stimulation. Enhancements in morphofunctional resistance were accompanied by stabilization of actin-containing specialized synaptic structures – desmosome-like contacts. The data obtained here provide evidence that peptides of this fraction of scorpion venom have direct actions on the actin component of the MN cytoskeleton and demonstrate potential for its use as a pharmacological tool able to penetrate living cells with value for studying the role of actin in the mechanisms of adaptation and memory. [ABSTRACT FROM AUTHOR]

Published
2004

46. Involvement of Actin in the Electrotonic Conductivity of Mixed Synapses in Mauthner Neurons in the Goldfish.

Author

L. L. Pavlik, N. R. Tiras, N. F. Mukhtasimova, P. I. Pakhotin, D. A. Dzeban, and D. A. Moshkov

Abstract

The effects of phalloidin, a preperation which highly specifically and selectively polymerizes actin and which binds to actin, on the electrotonic conductivity and structure of mixed synapses were studied in goldfish Mauthner neurons (MN). These experiments showed that paired subthreshold electrical stimulation of the afferent input in the presence of phalloidin led to increases in the amplitude of MN responses to the second stimulus by an average of 80%. In controls, this amplitude increased by only 10% and only when suprathreshold stimuli were used, while subthreshold stimuli were ineffective. We regard these results as demonstrating increases in the conductivity of mixed synapses, this being induced by polymerization of actin. At the ultrastructural level, application of phalloidin to MN and their mixed synapses induced increases in the sizes and numbers of actin-containing desmosome-like contacts, and in the numbers of fibrillar bridges in the clefts of these contacts. Use of colloidal gold as a label for phalloidin demonstrated that bridges were made of actin. The interdependent morphofunctional changes seen in mixed synapses provide grounds for suggesting a role for actin in the conduction of the electrotonic signal through mixed synapses. The structural substrate for this process may be provided by bridges in the clefts of desmosome-like contacts. [ABSTRACT FROM AUTHOR]

Published
2004

48. Phalloidin changes the synaptic contact ultrastructure

Author

D. A. Moshkov, M. E. Saxon, and N. R. Tiras

Subjects
Phalloidine, Chemistry, Phalloidin, Fishes, General Medicine, Molecular biology, Synaptic contact, Microscopy, Electron, chemistry.chemical_compound, Synapses, Ultrastructure, Animals, Oligopeptides, Locomotion, Swimming, Ecology, Evolution, Behavior and Systematics
Abstract

1. Shallenberger, R.S., Acree, T.E.: Nature 216, 480 (1967) 2. Blanksma, J.J., Petri, E.M.: Rec. Trav. Chim. 66, 365 (1947) 3. Wieser, H., et al.: Z. Lebensm. Unters.Forsch. 164, 277 (1977) 4. Mazur, R.H., Schlatter, J.M., Goldkamp, H.A.: J. Am. Chem. Soc. 91, 2684 (1969) 5. De Nardo, M., et al. : Farmaco (Pavia) 31, 906 (1976) 6. Lapidus, M., Sweeney, M. : J. Med. Chem. 16, 163 (1973) 7. Petersen, S., Mtiller, E.: Chem. Ber. 81, 31 (1948)

Published
1980
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49. [Synapses with a different synaptic contact structure in the cerebellar cortex]

Author

N R, Tiras, E N, Bezgina, and D A, Moshkov

Subjects
Cerebellar Cortex, Microscopy, Electron, Purkinje Cells, Guinea Pigs, Synapses, Animals, Neural Inhibition, Cell Communication, Dendrites, Axons, Rats
Abstract

The ultrastructure of cerebellar axosomatic (inhibitory) and axo-dendritic (excitatory) synapses were studied on the Purkinje cells and in the lower molecular layer of guinea-pigs and rats, respectively. It was shown that synaptic contacts of excitatory and inhibitory synapses differed in the existence of desmosome-like structures near the active zones. The classification of synaptic functions according to the ultrastructure of specialized contacts, earlier developed to identify neurons of lower vertebrates, is supposed to be applicable to the nervous system of higher vertebrates.

Published
1988

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