Substance P in the central mechanism of the rabbit feeding response evoked by stimulation of the lateral hypothalamus

The effects of substance P on the central mechanisms of food motivation elicited by electrical stimulation of the lateral hypothalamus were studied in chronic experiments on rabbits. Intravenous injection of substance P (30 micrograms/kg) brought about a dramatic reduction in the excitability of the "food center" in the hypothalamus, which returned to normal 45-60 minutes after injection. Higher concentrations of substance P provoked food behavior inversion up to the replacement of food motivation by avoidance behavior. Intravenous injections of substance P disturbed the relationships between the hippocamp, midbrain reticular formation and hypothalamus seen in health. This manifested in complete cessation of the inhibitory effects of the dorsal hippocamp and facilitating influences of the midbrain reticular formation on the excitability of the hypothalamic "food center". It is assumed that disorders of the central mechanisms of food motivation may arise from the effects produced by substance P directly on the central nervous system or on the brain via changes in the hormonal balance and responses of the autonomous nervous system.     

Substance P and the ethanol-evoked changes in the independent motivated behavioral reactions of rabbits

Ethanol (0.5 g/kg) administered intravenously led to alterations in central mechanisms of feeding and escape, elicited by threshold electrical stimulation either of lateral or of ventromedial hypothalamic centers of the rabbit. Subsequent intravenous injection of substance P (30 mcg/kg) restored the excitability of the ventromedial hypothalamus and facilitatory effects on this motivational center of the midbrain reticular formation. The restoration of both inhibitory influences of the dorsal hippocampus and facilitatory ones of the midbrain reticular formation on the excitability of the lateral hypothalamus was also observed after SP administration. Data obtained suggest that oligopeptides could be used to increase the tolerance to ethanol or to cure the negative acute effects of alcohol in motivated behaviours.     

Substance P in the central mechanisms of the escape reaction

The role of substance P in the central mechanisms of escape reaction elicited by electrical stimulation of the ventromedial hypothalamus was investigated in chronic experiments on rabbits. Intravenous injection of substance P (30 micrograms/kg) led to a short-term (less than 10 min) increase in the threshold of stimulation of the ventromedial hypothalamus and to more stable (up to 1.5 h) disorders of the hippocampal-hypothalamic relations. After substance P injection the inhibitory effects of the dorsal hippocampus but not the facilitating influences of the midbrain reticular formation on excitability of the hypothalamic motivation center were found to be lacking. Disorders of the central mechanisms of escape reaction after substance P injection correlated with new patterns of the main EEG rhythms in different areas of the brain cortex in response to the ascending excitations of the limbic-midbrain structures. Interpreting the mechanisms of substance P involvement in escape reaction the authors point to the ability of the given peptide to interact with different transmitter systems of the brain and opiate receptors and to alter the brain blood circulation.     

Effect of substance P on catecholamine levels in the hypothalamus and midbrain in the rat during immobilization stress

Single intraperitoneal injection of substance P in a dose of 125 mcg/kg induced a significant increase of noradrenaline and dopamine level in the hypothalamus and the midbrain of intact rats. Under conditions of immobilization emotional stress, the substance P eliminated the stress induced decrease of hypothalamic noradrenaline and increase of its level in the midbrain; in other words the substance P normalized the noradrenaline level. Modulatory effect of a single injection of the substance P had a long-term character and was synchronized with an earlier found increase of resistability of rats to chronic emotional stress.     

An analysis of the neuronal processes in the activating brain systems of the rat during the acquisition of an instrumental defense reflex

In chronic experiment, a defensive conditioned reflex was elaborated in rats with electrodes implanted in the reticular oral pons nucleus, cortico-medial group of amygdalar nuclei, ventromedial hypothalamic nucleus and central grey substance of the midbrain. Synchronization of the activity of neuronal groups of emotiogenic formations in the studied brain structures, became enhanced at formation of the conditioned reflex. A dependence was revealed of the level of correlation of limbic neuronal groups activity on functional state of the reticular formation, as well as neurochemical correlation mechanisms. The increase (decrease) of coefficients of correlation of the activity of neuronal ensembles of limbic structures was accompanied by a change of evoked potentials parameters recorded in them.     

Enhancement of the resistance of the escape reaction to ethanol after substance P]

An ability of substance P (30 micrograms/kg intravenously) to prevent deleterious effects of ethanol (E) (0.5 g/kg intravenously) on central mechanisms of escape reaction elicited by threshold electrical stimulation of the ventromedial hypothalamus was investigated in chronic experiments upon rabbits. Substance P was found to prevent E effects on excitability of the ventromedial hypothalamus (VMH) and on facilitatory influences of the midbrain reticular formation on this emotional centre which were observed in intact animals. Inhibitory effects of the dorsal hippocampus on the VMH could not be evaluated due to its alterations in response to previous substance P administration. The authors suggest that substance P can be considered to be a possible endogenous factor to increase a tolerance of emotional behavioural reactions of an organism to alcohol.     

Differentiation of efferent projections of the medial (cuneiform nucleus) and lateral regions of the reticular formation in cat midbrain

Efferent connections of medial (nucleus cuneiformis) and lateral regions of the midbrain reticular formation (MRF) were investigated using an anterograde autoradiographic technique in cats. Efferent fibers from the MRF ascend to the globus pallidus, substantia innominata, hypothalamus, subthalamus, and nonspecific associative and relay nuclei of the thalamus. Descending pathways to the conclusion that the cuneiform nucleus is more of a nonspecific structure than an association auditory center. The lateral reticular region had numerous projections to the lateral geniculate body and, together with the parabigeminal nucleus, forms the midbrain visual complex.I. P. Pavlov Institute of Physiology, Academy of Sciences of the USSR, Leningrad. Translated from Neirofiziologiya, Vol. 17, No. 5, pp. 646–652, September–October, 1985.     

Role of the reticular formation of the midbrain in the process of formation of background activity of cortex neurons

In strict experimental conditions the basic activity of optic-cortex neurons in the rabbit was depressed after transverse section at the level of the rostral part of the reticular formation of the midbrain. Electrolytic destruction or functional blockage of the midbrain reticular formation (nucleus reticularis tegmenti) produces a decrease in frequency and magnitude in the grouping indexes of the cortex-neuron pulses that manifest the activity in these conditions. Destruction of specific nuclei in the optic pathway (those of the lateral geniculate body and the corpora bigemina) made no substantial change in the nature of the cortex-neuron pulses. Comparison of the parameters of pulsation activity of the same cortex neurons, as recorded before and after functional exclusion of the midbrain reticular formation, revealed that the increase in grouping of these pulses after the reticular formation was blocked induced changes in the intervals between groups of pulses, while the frequency of pulses within the groups remained constant. On the basis of the data obtained we may assume that the midbrain reticular formation plays an important role in generation of the background activity of cortex neurons, being a triggering mechanism that sets off a group of pulses. Distribution of pulses within the group is apparently due to the activity of cortex mechanisms only.A. A. Bogomolets Institute of Physiology, Academy of Sciences of the Ukrainian SSR, Kiev. Translated from Neirofiziologiya, Vol. 2, No. 1, pp. 43–51, January–February, 1970.     

Substance P and effects of ethanol on the central mechanisms of the escape reaction in rabbits

Substance P (SP) effects on the central mechanisms of escape reaction, elicited by threshold electrical stimulation of the ventromedial hypothalamus were investigated in rabbits pretreated with ethanol (0.5 g/kg). SP (30 micrograms/kg) was demonstrated to normalize in 71.4% of cases the excitability of the ventromedial hypothalamus which was decreased by ethanol and restored in 83.3% of cases the facilitatory effects of the midbrain reticular formation in escape reactions. However, SP was ineffective in the restoration of the inhibitory effects of the dorsal hippocamp on the excitability of the ventromedial hypothalamus that was obvious in intact animals. Partial normalizing effect of SP on escape reaction in rabbits after previous ethanol administration can be accounted for by the fact that both undecapeptide and ethanol are similar in their realization of central effects such as an interaction with the same brain neurotransmitters, interference with neuronal enzyme processes and reactions with opiate receptors.     

Electrical activity of the cortex and subcortical structures during the development of hypoxia due to blood loss

Previous experiments on dogs showed that in several cases, along with the development of hypoxia, polymorphous delta-waves changed into synchronous oscillations, also of delta range, the so-called standard slow complexes (SSC). The new experimental data showed discharges of neuronal pool during SSC to be present in the caudate nucleus, lateral and medial thalamus, hypothalamus, hypocampus, n. amygdale, and mesencephalic reticular formation. The most frequent neuronal pulse activity was connected with the second half of the SSC negative phase (P is less than 0.01). Discharge flashes of the neuronal pool during the SSC indicated that SSC reflected the physiological processes occurring in these structures.     

Effects of pralidoxime applied locally into the midbrain reticular formation on the hippocampal theta rhythm induced by acetylcholinesterase inhibition

After local administration into the midbrain reticular formation of an acetylcholinesterase reactivator--Pralidoxime, a significant decrease of intensity of hippocampal theta rhythm induced by previous inhibition of acetylcholinesterase by DFP was observed already after 10 min. This result suggests that cholinergic structures are localized in midbrain reticular formation and that they play a role in the origin of hippocampal theta rhythm.     

Decreased Release of D-Aspartate in the Guinea Pig Spinal Cord After Lesions of the Red Nucleus

This study attempts to determine if fibers that project from the guinea pig red nucleus to the spinal cord use L-glutamate and/or L-aspartate as transmitters. Unilateral injections of kainic acid were placed stereotaxically in the red nucleus to destroy the cells of origin of the rubrospinal tract. Six days after the injection, Nissl-stained sections through the lesion site showed that the majority of neurons in the red nucleus ipsilateral to the kainic acid injection were destroyed. In addition, the lesioned area included parts of the surrounding midbrain reticular formation. Silver-impregnated, transverse sections of the cervical spinal cord revealed the presence of degenerating fibers contralaterally in laminae IV-VII of the gray matter. Ipsilaterally, very sparse degeneration was evident in laminae VII and VIII of the gray matter. Two to six days after surgery, the electrically evoked, Ca2(+)-dependent release of both D-[3H]aspartate, a marker for glutamatergic/aspartatergic neurons, and gamma-amino[14C]-butyric acid ([14C]GABA) was measured in dissected quadrants of the spinal cervical enlargement. Lesions centered on the red nucleus depressed the release of D-[3H]aspartate by 25-45% in dorsal and ventral quadrants of the cervical enlargement contralaterally. The release of [14C]GABA was depressed by 27% in contralateral ventral quadrants. To assess the contribution of rubro- versus reticulospinal fibers to the deficits in amino acid release, unilateral injections of kainic acid were placed stereotaxically in the midbrain reticular formation lateral to the red nucleus. Nissl-stained sections through the midbrain revealed the presence of extensive neuronal loss in the midbrain and rostral pontine reticular formation, whereas neurons in the red nucleus remained undamaged. In the spinal cord, degenerating axons were present ipsilaterally in laminae VII and VIII of the gray matter. Some fiber degeneration was also evident contralaterally in laminae V and VI of the gray matter. This lesion did not affect the release of either D-[3H]aspartate or [14C]GABA in the spinal cord. The substantial decrements in D-[3H]aspartate release following red nucleus lesions suggests that the synaptic endings of rubrospinal fibers mediate the release of D-[3H]aspartate in the spinal cord. Therefore, these fibers may be glutamatergic and/or aspartatergic. Because other evidence suggests that rubrospinal neurons are probably not GABAergic, the depression of [14C]GABA release probably reflects changes in the activity of spinal interneurons following the loss of rubrospinal input.     

Changes in the substance P content of the blood and hypothalamus during experimental emotional stress

A study was made of the content of substance P in the blood and hypothalamus of Wistar rat brain in acute and chronic emotional stress and after intraperitoneal injection of substance P in a dose of 250 mg/kg. A possibility was demonstrated of inducing long-term changes in the content of substance P in the hypothalamus after a single injection. Exposure to a single 24-hour stress was followed by an increase in the substance P content in the hypothalamus.     

Adaptive changes in the evoked electrical activity of the rat brain while training it in a controlled experiment]

A programmed change of a certain phase of cortical EP to a photic flash was reinforced in an unrestrained chronically operated animal (a rat) in the course of an operant controlled experiment. A painful subcutaneous stimulation or stimulation of the emotionally positive zone of the lateral hypothalamus was used as a reinforcing agent. It has been shown that painful stimulation is a more effective reinforcing agent than brain stimulation. Synchronous recordings pointed to a distinct correlation of activity in some structures (field CA1 of the hippocampus) with that of the visual cortex, while in others the EP form characteristically changed at different stages of learning (thalamic reticular nucleus), and in still others, there were no EP changes (midbrain reticular formation) at any stage of learning.     

Neuroendocrine mechanisms of participation of the raphe nuclei in the development of hypertensive reactions in emotional stress

The experiments on cats and rabbits have studied electroencephalographic, endocrine and blood pressure responses to stress (5-hour immobilization with electrical foot shock) before and after coagulation of the midbrain nuclei raphe. Blood pressure and adrenal responses in advanced (4-hour) stress were elevated in intact animals, the responses attenuating after coagulation of the nuclei raphe. Background bioelectrical activity of the midbrain reticular formation and hypothalamus was found to be activated in the operated animals. Stress was followed by the reduction in bioelectrical changes of the above subcortical structures with the parallel development of "burst" activity in the dorsal hippocamp.     

Cytoarchitectonic subdivisions in the subtectal midbrain of the lizard Gallotia galloti

Contemporary study of molecular patterning in the vertebrate midbrain is handicapped by the lack of a complete topological map of the diverse neuronal complexes differentiated in this domain. The relatively less deformed reptilian midbrain was chosen for resolving this fundamental issue in a way that can be extrapolated to other tetrapods. The organization of midbrain centers was mapped topologically in terms of longitudinal columns and cellular strata on transverse, Nissl-stained sections in the lizard Gallotia galloti. Four columns extend along the whole length of the midbrain. In dorsoventral order: 1) the dorsal band contains the optic tectum, surrounded by three ventricularly prominent subdivisions, named griseum tectale, intermediate area and torus semicircularis, in rostrocaudal order; 2) a subjacent region is named here the lateral band, which forms the ventral margin of the alar plate and also shows three rostrocaudal divisions; 3) the basal band forms the basal plate or tegmentum proper; it appears subdivided into medial and lateral parts: the medial part contains the oculomotor and accessory efferent neurons and the medial basal part of the reticular formation, which includes the red nucleus rostrally; the lateral part contains the lateral basal reticular formation, and includes the substantia nigra caudally; 4) the median band contains the ventral tegmental area, representing the mesencephalic floor plate. The alar regions (dorsal and lateral) show an overall cellular stratification into periventricular, central and superficial strata, with characteristic cytoarchitecture for each part. The lateral band contains two well developed superficial nuclei, one of which is commonly misidentified as an isthmic formation. The basal longitudinal subdivisions are simpler and basically consist of periventricular and central strata.     

Effect of ethanol on central mechanisms of alimentary and defensive motivation in the rabbit

A single intravenous administration of ethanol (0.5 g/kg) to rabbits had different effects on the excitability of feeding and defensive motivational centers of the lateral and ventromedial hypothalamus. Ethanol abolished both inhibitory effects of the dorsal hippocampus and facilitatory action of the midbrain reticular formation on alimentary and defensive motivations. It elicited new power distributions of the main rhythms of general electrical cortical activity in the background and under stimulation of limbic-midbrain structures. Analysis of the activity of organello-specific enzymes in limbic-midbrain neurones revealed disturbances of cellular energetic processes caused by ethanol.     

Peptide immunoreactive neurons in the amygdala and the bed nucleus of the stria terminalis project to the midbrain central gray in the rat.

The central nucleus of the amygdala, bed nucleus of the stria terminalis, and central gray are important components of the neural circuitry responsible for autonomic and behavioral responses to threatening or stressful stimuli. Neurons of the amygdala and bed nucleus of the stria terminalis that project to the midbrain central gray were tested for the presence of peptide immunoreactivity. To accomplish this aim, a combined immunohistochemical and retrograde tracing technique was used. Maximal retrograde labeling was observed in the amygdala and bed nucleus of the stria terminalis after injections of retrograde tracer into the caudal ventrolateral midbrain central gray. The majority of the retrogradely labeled neurons in the amygdala were located in the medial central nucleus, although many neurons were also observed in the lateral subdivision of the central nucleus. Most of the retrogradely labeled neurons in the BST were located in the ventral and posterior lateral subdivisions, although cells were also observed in most other subdivisions. Retrogradely labeled neurotensin, corticotropin releasing factor (CRF), and somatostatin neurons were mainly observed in the lateral central nucleus and the dorsal lateral BST. Retrogradely labeled substance P-immunoreactive cells were found in the medial central nucleus and the posterior and ventral lateral BST. Enkephalin-immunoreactive retrogradely labeled cells were not observed in the amygdala or bed nucleus of the stria terminalis. A few cells in the hypothalamus (paraventricular and lateral hypothalamic nuclei) that project to the central gray also contained CRF and neurotensin immunoreactivity. The results suggest the amygdala and the bed nucleus of the stria terminalis are a major forebrain source of CRF, neurotensin, somatostatin, and substance P terminals in the midbrain central gray.     

The effect of adrenoblockers on the neurons of the lateral hypothalamus under the action of pentagastrin]

To test the hypothesis of interaction pentagastrin (PG) noradrenaline (NA) in central neurochemical mechanisms of food motivation, we studied the activity of single neurons in lateral hypothalamus (LH) after s.c. PG injection. Following PG injection microiontophoresis (MIF) of propranolol prazosin was made. PG-induced changes were similar to neuronal activity in rabbits LH after 24-hour food deprivation in 59%. Propranolol-induced changes were following firing pattern in the process of food uptake in 68%. Prazosin MIF induced firing pattern of neuronal activity of saturated rabbits in 60%.     

Quantitative and qualitative automatic evaluation of afterdischarges in the study of antiepileptic drugs

An automatic analysis of bioelectrical activity in some structures of the rabbit's brain was performed after i.v. administration of diazepam, phenytoin or phenobarbital. It was found that diazepam raised the ratio of fast activity in the afterdischarges pattern but paralelly decreased the total energy involved in the production of after-discharges in the cortex and midbrain reticular formation. Phenobarbital caused a significant shift in frequencies, increasing the ratio of slow activities (in the exception of hippocampus) and decreased the power spectra of afterdischarges in all structures (in the exception of midbrain reticular formation). Phenytoin, similarly to phenobarbital, decreased the ratio of fast activities. This effect was significant only in thalamus and midbrain reticular formation. At the same time it increased the total power of signal from hippocampus and midbrain reticular formation.