[Mechanisms of reproductive behavior in humans: olfactory markers of males' attractiveness].

The present work represents a pilot study in the area of olfactory communication in humans. On the basis of experiments, it is demonstrated that women are able to detect, by means of smell, a number of morphological and psychological characteristics of men. The samples of sweat from 29 young men were collected, as well as anthropometry measurements (interpupillary distance, height and width of the lower jaw, and so forth) and behavioral characteristics (personality questionnaire NEO, risk-taking questionnaire, Sandra Bem masculinity and femininity indices, a self-rating on aggression Buss-Perry questionnaire). Data on hormonal status of all males were collected (testosterone and cortisol). It is demonstrated that women are able to detect both morphological (masculinity, physical health) and psychological characteristics (aggression, risk taking, neuroticism, extraversion, cooperation, etc.). The smell of men rating high on cortisol is estimated as the least attractive. On the contrary, the sweat of men with combination of high level of testosterone and low level of cortisol is considered the most attractive. Females rating of male's smell differed depending on a phase of a monthly cycle. The data obtained are discussed in the light of evolutionary basis of permanent partner choice.

[Level of neuroactive steroids in the brain, and gender-related differences in formation and decrease of conditioned reflex in rats].

We investigated gender-related differences in dynamics of the brain sexual steroids during learning and the decrease of conditioned reflex in the modeling experiment. It was revealed that, before training to conditioned reflexes, females manifested a greater anxiety than males. Significant differences between males and females in formation of the conditioned reflex of passive avoidance were not revealed, whereas the conditioned response decrease were by 2-3 days faster in male rats than in females. It was revealed that there was an increase of testosterone content in various structures of the brain, especially in hippocampus and frontal cortex with its constant level in the blood plasma in learning conditioned response of passive avoidance in male adult rats. Also an increased estradiol concentration was found in females' amygdale, while increased value of estradiol was detected in hippocampus and the singular cortex in decrease of the conditioned response of passive avoidance. In blood plasma, the testosterone level was not changed, and the estradiol concentration was reduced significantly after the decreased conditioned reflex. Different dynamics of changes in the levels of sex steroids in the brain and the blood plasma can indicate a probability of their formation in nervous tissue. The correlation analysis confirms the conception about selective involvement of the brain's testosterone and estradiol in the specific structures in realization ofthe learning and memory processes in adult male and female rats.

[Sex-related peculiarities of conditioned reflex activity and dynamics of sex steroids in the brain].

Sexual peculiarities of dynamics of brain sex steroids in the process of learning and extinction of the conditioned reflex of passive avoidance have been studied in model experiment. Prior to learning of conditioned reflex, females were found to be distinguished by manifestation of anxiety and fear as compared with males. At formation of the conditioned reflex, no significant sex differences were detected between males and females, whereas extinction of the conditioned reaction of passive avoidance in rat males occurred by 2-3 days faster than in females. At learning of conditioned reaction of passive avoidance, in sexually mature rat males there was revealed an increase of the testosterone content in various brain structures, especially in hippocampus and frontal cortex, while its level in blood plasma remained unchanged. Also shown was an elevation of estradiol concentration in female amygdale, whereas at extinction of the conditioned reaction of passive avoidance, a rise of estradiol values was noted in hippocampus and cingular cortex. At the same time the testosterone level in blood plasma did not change, whereas the estradiol concentration decreased statistically significantly after extinction of the conditioned reflex. Different dynamics of changes of the sex steroid levels in brain and blood plasma can indicate a probability of their formation in the nervous tissue. The performed correlation analysis confirms the concept of selective involvement of testosterone and estradiol of specific brain structures in realization of the process of learning and memory in sexually mature rat males and females.

Transplantation of cultured astrocytes attenuates degenerative changes in rats with kainic acid-induced brain damage.

Viability of astrocyte grafts introduced into CA1 pyramidal layer of the left dorsal hippocampus after injection of kainic acid into this brain region and the effects of these grafts on the hippocampus and amygdala were studied on Wistar rats. In rats with astrocyte grafts the degree of destruction in fields CA1-CA2 of the dorsal and ventral hippocampus, fields CA3-CA4 of the ventral hippocampus, and central and basolateral amygdala was lower compared to animals with kainic acid-induced hippocampal damage and control rats; destructions in the dentate fascia were absent. Our results suggest that astrocyte grafts stimulate neurogenesis in the mature brain of recipient rats with kainic acid-induced brain damage.

Development of neuronal ganglion xenografts from gastropoda in rat brain.

Survival of neuronal ganglia from newborn snail (Helix aspera L.) in the brain of adult rats was studied. Snail ganglion survived in the brain of warm-blooded animals for 6 months without inducing immune conflict. At early stages (5 days) after transplantation, xenografts increased in size and were several times larger than native ganglia from 10-day-old snails, thereafter (on days 28 and 180) they became smaller still surpassing the sizes of ganglia from snail of the corresponding age. Rapid enlargement of the xenograft was due to cell reactive processes in the ganglion. Deep penetration of large vessels from xenografts to rat brain was observed.

Comparison of reactive processes in the rat brain elicited by xenotransplantation of nervous tissues of chicken or pulmonate snail.

It is known that a histocompatibility system is not developed to the same extent in lower invertebrates as in vertebrate animals. We assumed that the xenografts from the newborn invertebrate nervous system would not exert destructive effects on the brain of the vertebrate recipient even without immunosuppressive therapy. In search of brain xenografts (XG) capable to survive in the brain of a recipient without intensive immunosuppression, we transplanted ganglia of terrestrial snails into the rat brain. We compared effects of transplantation of the XG taken from anterior brain of the 18-day embryo chicken (XGC) and from ganglia of a newborn terrestrial pulmonate snail (Helix aspersa L., XGSn). Part of the XGSn were stained by vital fluorescent dyes Bisbenzimid or Fast Blue before grafting. The XGSn were implanted into the neocortex parenchyma in each hemisphere. Rat brains with the XGC were examined 5 days after, and brains with the XGSn - 5 and 28 days after the transplantation. Nonstained sections with the XGSn labeled with fluorescent dyes prior to transplantation were investigated in fluorescent microscope and stained later with tionin and cresyl-violet. Quantitative videoimage analysis of lymphocyte aggregations, reactive gliosis, morphology of the XG areas, and implantation trace was performed. It was found that the XGSn transplantation did not elicit in the rat brain an intensive immunological conflict 5 and 28 days after transplantation. In contrast, the XGC rapidly elicited a strong immune response resulting in massive obliterations in the rat brain and were rejected in 5 days. Labeled snail glia and vessels were observed in the stained XGSn 28 days after transplantation by fluorescence imaging. Putative snail vessels grew into the rat brain from the place of snail tissue transplantation serving the humoral integration of the XG and the host brain. Migration of molluscan glial cells was observed in the brain of recipients.

The use of neural transplantation for suppression of seizure activity in genetically epilepsy-prone rats.

The possibility of correcting seizure activity with neural transplantation was studied in Wistar rats with audiogenic seizures and in Krushinskii-Molodkina rats with high level of audiogenic seizures. In Wistar rats seizures were absent during 24 weeks after combined bilateral transplantation of striatal and cerebellar tissue from newborn rats into the parietal cortex. The same transplantation performed in Krushinskii--Molodkina rats increased the latency of audiogenic seizures. In some rats the intensity of seizures decreased, but they did not completely disappeared. Suppression of seizure activity in Krushinskii-Molodkina rats was observed after transplantation of striatal and cerebellar tissue simultaneously into the parietal cortex and inferior colliculi.

[The effect of neural transplantation on audiogenic seizures in rats of different genetic strains]. / Vliianie neirotransplantatsii na audiogennye sudorogi u krys raznykh geneticheskikh linii.

The effects of neurotransplantation on development of audiogenic seizures (AS) were studied in Krushinskii-Molodkina (KM) rats genetically predisposed to AS and in Wistar rats especially selected for AS. Within 24 weeks after bilateral combined transplantation of the newborn striatum and cerebellum into the parietal cortex, the AS didn't develop in Wistar rats in 74% of tests. In control Wistar rats with cortical grafts or saline injections into the parietal cortex there were no significant changes in the AS development. In the experimental KM rats the grafting led to the 4-5-times increase in the AS latency. In 50% of rats it decreased the AS severity by 1-2. In the control KM rats these parameters didn't change. It was concluded that it was possible to suppress or decrease the AS development by the transplantation of the newborn striatal and cerebellar tissue into the cortex of rats predisposed to this kind of seizures.

[The behavior of embryonic nerve cells transplanted into the brain]. / Povedenie émbrional'nykh nervnykh kletok pri transplantatsii v mozg.

Small solid pieces of 3H-thymidine labeled rat neocortex at day 20 of embryonic development were transplanted homotopically into the cortex of adult rats. Transplanted cells migrated from the site of implantation into cortical layers 2-4 of the host to the distance of about 1 mm. No labeled neurons was found in cortical layers 5-6 (the target site during their normal migration). Migration of glial cells was similar to that of astrocytes moving from the suspension grafts. In some cases, similar distribution of migrating donor cells around the implantation site was observed despite the fact that a solid grafted tissue was absent.

Influence of neurotransplantation on rats' behavior with different conditions of reinforcement.

Recently, we have reported a marked rat lateralization in the T-maze choice. Embryonic rat tissue from neocortex, hippocampus, hypothalamus and amygdala was transplanted into intact rat brains in various combinations: 1) neocortex and hypothalamus (Neo + Hyp); 2) hippocampus and amygdala (Hipp + Amyg); 3) neocortex and hippocampus (Neo + Hipp); and 4) hypothalamus and amygdala (Hyp + Amyg). Once under conditions in which reinforcement was equally qualitative and equally probable, rats in all groups chose the T-maze arm contralateral to the side of implantation. In a second set of experiments, rats were presented a choice between quality and probability of reinforcement. The right arm of the T-maze contained a cup of water 33% of the time (high-quality but low-probability reinforcement). The left sleeve contained a solution of 0.15% quinine in water 100% of the time (low quality but high probability of reinforcement). Rats that received Neo + Hyp transplants chose the T-maze arm that always contained a drink cup with water significantly more often than they chose the arm that always contained the drink cup with quinine solution. Rats that received Hipp + Amyg transplants chose the arm containing the drink cup with quinine solution much more often than the arm that sometimes contained a cup of water. Rats with transplanted Neo + Hyp generally were more active than rats with transplanted Hipp + Amyg. These data suggest that the behavior of rats can be affected by selective transplantation of different brain tissue.

Influence of brain embryonic tissue transplantation (early period) on rat's reactions of avoiding zoosocial and artificial stimuli.

The effect of the influence of brain tissue transplantation on behavior avoidance as zoosocial and artificial stimuli was examined in rats after unilateral transplantation of embryonic tissue to the cortex parietal region. Pieces of neocortex and hippocampus (NC + HC) were introduced to one group of twenty rats. Pieces of amygdala and hypothalamus (AM + HT) were introduced to twenty other animals composing a second group. Ten intact animals served as a control group. In the group receiving transplants of AM + HT, by one week after surgery the number of animals avoiding zoosocial stimulus was significantly increased. In the group receiving transplants of NC + HC, by one week after transplantation, a considerable increase in the time of avoiding artificial aversive stimuli was observed for most of the animals.