The interaction between glycine and GABA postsynaptic effects in the spinal cord neurons of frog Rana temporaria

Patch-clamp study in the whole multipolar cell (presumably motoneuron) was performed, the cells having been mechanically isolated from the spinal cord of the frog Rana ridibunda. It was shown that GABA and glycine, when applied simultaneously, produced a transmembrane current. Its amplitude was lower than the summed amplitude of currents produced in the same neuron by separate applications of GABA and glycine. The investigation of this occlusion showed that the superfusion of the neurons with solution containing 0.2 mM of glycine totally blocked the responses to GABA (5 mM) application, and vice versa. The crossinhibition can lie in the basis of this phenomenon. It could be due to either the existence of a common receptor complex sensitive to both GABA and glycine or to interaction between GABA and glycine receptors.     

Distribution of monoamine-containing neurons in the brain stem of the frog, Rana temporaria

The distribution of monoamine (catecholamine and 5-hydroxytryptamine)-containing nerve cell bodies in the brain stem and hypothalmus of the frog (Rana temporaria) was investigated with the help of the histofluorescence technique of Falck and Hillarp ('62). At the level of the hypothalmus of this amphibian brain, catecholamine-containing nerve cell bodies are found mainly within three areas of the periventricular gray substance, namely the peroptic recess organ, the paraventricular organ and the lateral recess region. On the other hand, most of the 5-hydroxytryptamine (serotonin)-containing nerve cell bodies of the brain stem of Rana temporaria appear to be concentrated within the midbrain tegmentum. This huge mesencephalic nerve cell collection can be subdivided into medial and lateral groups. More caudally, at the level of the isthmic tegmentum, another group of 5-hydroxytryptamine-containing perikarya located close to the midline, within the so-called raphae region, is clearly outlined. The latter group of neurons extends caudally as far as the level of the medulla oblongata. In addition, a small group of catecholamine-containing nerve cell bodies is also found in the ventromedial portion of the rostral midbrain tegmentum, whereas a few other catecholamine type neurons are scattered throughout the lower brain stem of the frog and more especially near the ependymal wall of the fourth ventricle. As a whole, the 5-hydroxytryptamine-containing neuronal systems of the brain stem of Rana temporaria are much more elaborated than the catecholamine neuronal systems of the same structure.     

Effect of photostimulation on the wakefulness-sleep cycle in the common frog Rana temporaria

Effect of daily 30-min photostimulation in the 10 s light: 10 s pause (the total of 5 days) on the time structure of the wakefulness--protosleep cycle (WPC) was studied in the common frog Rana temporaria. Changes were analyzed of EEG wave components in three immobility forms of the type of catalepsy (P-1), catatonia (P-2), and cataplexy (P-3) that form protosleep. The first three photostimulations promoted a gradual increase of the P-1 state to 84.16 +/- 11.6% [the initial value (IV) 22.9 +/- 9.1%] and a decrease of representation of wakefulness to 4.86 +/- 2/1% (IV 13.8 +/- 7.8%), of P-2 to 11.1 +/- 5.3 (IV 53.3 +/- 13.3%), and of P-3 to 2.21 +/- 1.0% (IV 11.1 +/- 5.6%). After 4-5 photostimulations and especially after their complete cessation the percentage of P-1 in the WPC was restored to initial values, whereas the percentage of the frog WPC P-3 considered to be a precursor of the homoiothermal sleep rose to 20 +/- 8.3% after 5 photostimulations and to 38.5 +/- 6.7% the next day. Changes in the frog EEG spectra appeared only after one photostimulation and were characterized by a brief increase of power of alpha-like waves and by inhibition of slow 6-waves. In P-2 the power of the slow delta-waves gradually rose. In P-3 the EEG parameters did not change. In all experimental animals a decrease of the relative thymus and adrenal masses was revealed, which indicates the photostimulation regime used in the work induces stress. The obtained data allow thinking that a certain neurohormonal response to stress has already been formed at the amphibian level and that an important role in this response realization is played by a coordinated interaction of the hypothalamic sleep-regulating system providing protosleep manifestations and of the hypothalamic neurosecretory system triggering the stress-reaction hormonal cascade.     

Effect of apomorphine on the wakefulness--sleep cycle of the common frog Rana temporaria

This work considers effects of introduction into spinal lymphatic sac of dopamine agonist--apomorphine-(APO) at doses of 0.1, 1.0, 2.0 and 4.0 mg/kg body weight on the common frog wakefulness-sleep cycle (WSC). Usually the frog WSC is represented by wakefulness and three types of passive-protective behavior: by immobility states of the type of catalepsy, catatonia, and cataplexy that are characterized by high thresholds of arousal and by different (corresponding to the name) skeletal musculature tones. These immoboloty forms are considered as homologues of mammalian stress-reaction, hibernation, and sleep. Low apomorphine doses produced in WSC a marked decrease of portion of wakefulness and an increase of the immoboloty state of the catalepsy; high doses, on the contrary, initially promoted in CNS an increase of wakefulness and the state of catalepsy by demonstrating thereby its stressogenic action; after this, in WSC these increased the portion of the sleep-like immobility state of the catalepsy type that is considered as a functional homologue of sleep of homoiotherms. In spectra of electrograms of the flog telencephalon the representation of waves of the delta diapason rose. Taking into account that the states of catalepsy and cataplexy in frogs are under control of the anterior hypothalamus, it can be suggested that manifestations of cataplexy (sleep) in frog are due to the low level of dopaminergic activity, whereas manifestations of catalepsy (the homologue of stress reaction) are due to the high dopamine content in the anterioi hypothalamic structures. Comparative analysis of changes in WSC of amphibians and mammals in response to administration of dopamine and its agonists allows thinking that the role of the dopaminergic neurotransmitter system in regulation of the vertebrate WSC is unanimous: the low level of activity of this system facilitates development of sleep (catalepsy), whereas the high level provides reaction of arousal and is actively included in the system providing stress-reaction.     

The hypothalamo-hypophysial system of the frog Rana temporaria

Summary The median eminence (ME) of the adult frog, Rana temporaria, was studied by means of electron microscopy including quantitative electron-microscopic autoradiography. In frogs captured in May and June numerous peptidergic neurosecretory fibres extending via the internal zone to the pars nervosa display large swellings containing few granules, mitochondria, neurotubules and cisternae of the smooth endoplasmic reticulum. In addition, few secretory globules up to 1.5 m in diameter occur in these varicosities. In animals collected during the autumn period many of these neurosecretory swellings filled with neurosecretory granules and polymorphic inclusions resemble Herring bodies. Three types of granule-containing neurosecretory fibres were observed in the external zone (EZ) of the ME of adult R. temporaria. Peptidergic A₁- and A₂-type fibres are characterized by granules 150–220 nm and 100–160 nm in diameter, respectively. Monoaminergic fibres of type B with granules approximately 100 nm in diameter represent 50% of all neurosecretory elements in the EZ of the frog ME; 12% of the total number of granule-bearing axons in the EZ actively taking up radiolabelled 5-hydroxytryptophan are thought to be serotoninergic terminals. Neurosecretory terminals of all types and glial vascular endfeet establish direct contacts with the perivascular space of the primary portal capillaries. Some neurosecretory terminals are separated from the lumen of the third ventricle by a thin cytoplasmic lamella of tanycytes. The possible physiological significance of this structural pattern is discussed.     

Effect of photostimulation on the wakefulness-sleep cycle in the common frog Rana temporaria

Effect of daily 30-min photostimulation in the 10 s light: 10 s pause regime (the total of 5 days) on the time structure of the wakefulness-protosleep cycle (WPC) was studied in the common frog Rana temporaria. Changes of EEG wave components were analyzed in three immobility forms of the types of catalepsy (P-1), catatonia (P-2), and cataplexy (P-3) that form protosleep. The first three photostimulations promoted a gradual increase of the P-1 state to 84.16 ± 11.6% (the initial value (IV) 22.9 ± 9.1%) and a decrease of representation of wakefulness to 4.86 ± 2.1% (IV 13.8 ± 7.8 %), of P-2 to 11.1 ± 5.3 (IV 53.3 ± 13.3 %), and of P-3 to 2.21 ± 1.0% (IV 11.1 ± 5.6%). After 4–5 photostimulations and especially after their complete cessation the percentage of P1 in the WPC was restored to initial values, whereas the percentage of the frog WPC P-3 considered to be a precursor of the homoiothermal sleep rose to 20 ± 8.3% after 5 photostimulations and to 38.5 ± 6.7% the next day. Changes in the frog EEG spectra appeared only after one photostimulation and were characterized by a brief increase of power of α-like waves and by inhibition of slow δ-waves. In P-2 the power of the slow δ-waves gradually rose. In P-3 the EEG parameters did not change. In all experimental animals a decrease of the relative thymus and adrenal masses was revealed, which indicates the stress nature of the photostimulation regime used in the work. The obtained data allow thinking that a certain neurohormonal response to stress has already been formed at the amphibian level and that an important role in this response realization is played by a coordinated interaction of the hypothalamic sleep-regulating system providing protosleep manifestations and of the hypothalamic neurosecretory system triggering hormonal cascade of the stress-reaction.     

Stretch receptors of the lungs in the frog Rana temporaria

In experiments on isolated lungs, studies have been made on the activity of single afferent fibers during simulated expiration and inspiration. Both slowly adapting and rapidly adapting voluminous stretch receptors were found in the frog lungs. The latter type exhibits the activity also during fast simulated expiration. Using acetylcholine and histamine, it was shown that the level of excitability of the receptors investigated depends on functional condition of the plain muscles in the pulmonary wall.     

Interdigitating cells in the thymus of the frog, Rana temporaria

Interdigitating cells (IDC) of the thymic medulla of the frog, Rana temporaria, collected in the summer, were examined by electron microscopy. The most characteristic cytological features of IDC are voluminous electron-lucent cytoplasm and widespread interdigitations and invaginations of the cell membrane. IDC possess an excentrically located nucleus with pronounced nucleoli and a thin rim of a dense chromatine as well as a perinuclear area with characteristic tubulo-vesicular complex. In our material Birbeck granules were absent. Some IDC contain phagocytized material. A few transitional forms between monocytes and IDC were observed. On the basis of these observations it is highly probable that the amphibian IDC belong to the mononuclear phagocyte system.     

Histochemical study of skeletal muscles of the frog, Rana temporaria

Histochemical profiles of muscles were identified based on staining for myosin ATPase activity. They reveal typical arrangement of muscular fibres with a zoned pattern. Tonic fibres have a unique histochemical profile and are mixed with the most oxydative fast fibres to form toxic zones. Muscles show fast profiles in thigh and tonic or mixed profiles in fore-arm.