Inhibitory role of serotonin in manifestations of predatory aggression in the mink and silver fox

The predatory aggression of minks and silver-black foxes were estimated by their attacks on the rats placed in their cage. Intraperitoneal injection of 5-hydroxytryptophan (serotonin precursor) in a dose of 100 mg/kg to foxes and 50 mg/kg to minks, caused a significant blocking of predatory aggression. Estimation of serotonin level in the brain following administration of corresponding doses of 5-HTP inhibiting the predatory aggression, revealed a considerable increase of serotonin content. It may be assumed that serotonin inhibitory mechanisms of predatory aggression are homologous in different species of animals.     

S-100 Modulates Ca2+-Independent Phosphorylation of an Endogenous Protein (Mr= 19K) in Brain

Abstract: A new brain enzyme (tentatively named protein kinase X), which catalyzes protamine phosphorylation modulated by S-100, was reported recently. An endogenous substrate protein (M_r= 19K) for protein kinase × was isolated from brain by means of S-100-Sepharose 4B affinity chromatography. S-100, but not calmodulin, promoted phosphorylation of the 19K M_r protein in a Ca²⁺-independent manner, and this reaction was inhibited by gossypol. The substrate protein, localized in the particulate fraction, was present at a much higher level in brain from adult than neonatal rats (2-day-old), a developmental change similar to that seen for protein kinase X. It is suggested that a protein phosphorylation system modulated by S-100 exists in brain, and that this process may be involved in regulation of certain neural functions.     

NUCLEAR LOCALIZATION OF S-100 PROTEIN

Abstract— S-100 protein has been found in the nuclei isolated from the brain cortex of rabbit. The nuclear S-100 constitutes a small portion (0.55 per cent) of the S-100 present in the cytosol. Most of the large and pale nuclei appear to contain much more S-100 than the small and dark ones. The nuclear membrane is permeable in vitro to S-100 in presence of divalent cations. Three forms of S-100 occur in subnuclear fractions: free S-100, present in the soluble protein fraction; labile-bound S-100, present in the deoxyribonucleoprotein fraction and stable-bound S-100, present in the residual or‘nucleolar’fraction. The localization of the S-100 in those regions of the nucleus that are most active in RNA synthesis provides basic information for further studies on the possible role of this protein on genomic expression in nervous tissue.     

Change in certain forms of aggressive behavior and the concentration of monoamines in the brain during selection of wild rats for taming

Norway rats have been selected during 20 generations by the absence of aggressive reaction to man (tamed rats). From 7 up to 20th generations of selection, different forms of aggressive behaviour (reaction to glove, intermale, shock-induced aggression and predatory aggression) were studied, and the level of noradrenaline, serotonin and its metabolite 5-hydroxyindoleacetic acid was determined in the brain. In the absence of aggressive reaction to glove in tamed rats, the shock-induced aggression considerably decreased while the predatory aggressiveness (mouse-killing behaviour) and intermale aggressiveness did not change. Beginning from 15-16th generation of selection, a higher level of the 5-hydroxyindoleacetic acid in the hypothalamus was established, in the 20th generation an increased content of serotonin was revealed in the hypothalamus and the midbrain. In some generations of selection an increased level of noradrenaline in the hypothalamus in comparison to wild rats was observed. A conclusion is made that the selection of animals by taming unequally influences different kinds of aggressiveness and is accompanied by inherited consolidated reorganization of the monoamine brain systems.     

PURIFICATION AND SOME PROPERTIES OF S-100 PROTEIN FRACTIONS FROM SHEEP AND PIG BRAINS

Abstract— The S-100 protein fraction of pig and sheep brain was purified in 40 per cent yield by a modification of the procedure of M oore (1965), which avoided selective loss of S-100 components. The S-100 fraction of both pig and sheep is a mixture of proteins as indicated by acrylamide gel electrophoresis and N -terminal amino acid analysis. Differences in amino acid composition, electrophoretic heterogenity and N -terminal analysis were found.
One fraction (fraction A) was isolated by DEAE-Sephadex chromatography from pig brain S-100 protein fraction. It was considered to be a single protein since it migrated as a single band on acrylamide gel electrophoresis and showed a single symmetrical peak during ultracentrifugal analysis. Only one N -terminal amino acid was detected in fraction A. The amino acid composition of this fraction showed minor but significant differences from that of the complete S-100 protein fraction from pig brain. The S-100 protein fraction of both species, as well as fraction A, had similar s _{20, w} values and similar molecular weights (about 20,000) as indicated by gel filtration. These results, together with the immunological data obtained by other authors, suggest that the proteins of the S-100 fraction are closely related; the heterogeneity of the S-100 protein fraction may be of the same type as the lactate dehydrogenase isoenzymes.     

The functional role of neurospecific protein S-100 in memory processes]

Elaboration of alimentary conditioned reflex in rats is accompanied by an increase of the level of protein S-100 in the left and right cerebral hemispheres. Amnestic factor M-cholinolytic atropine disturbs the elaborated habit and simultaneously decreases the quantity of protein S-100 up to the level of unlearned animals. The elaboration of conditioned reflex of passive avoidance does not change the content of protein S-100 in the rats brain. Intracisternal injection of antiserum to protein S-100 has an expressed amnestic action. Intracisternal injection of protein S-100 against the background of amnestic action of cholinolytic does not lead to restoration of memory. The cholinolytic and antiserum to protein S-100 mutually potentiate the amnestic effect.     

Development of long-term post-tetanic potentiation and changes in S-100 protein contents in hippocampal slices of rats in different functional states]

Male rats of the strains with low (LE) high excitability (HE) of the nervous system have been used in this study. Half of the animals of each strain were neurotized in accordance with the Hecht's scheme. In the hippocampal slices of the non-neurotized LE rats there was a significant increase of the populational spike amplitude during development of LTP as compared with the opposite group of the animals. The LTP formation in the LE strain of rats caused a decrease in the S-100 protein content in the water-soluble, and an increase in the membrane-bound fraction of the protein. Similar results we have observed with the non-inbred Wistar rats but not with the HE strain of the animals. The levels of the water-soluble S-100 protein fraction were also higher in the hippocampuses and entorenal cortices, but not in the cerebellae of the LE strain, as compared with the HE strain of the rats. No differences have been found in the membrane-bound fraction of S-100 protein.     

Influence of cyclic GMP on rodent aggressive behavior

Dibutyryl cGMP (0 to 100 μg), infused intraventricularly in rats and mice, produced dose-dependent increases in brain cGMP, facilitation of shock-induced rat fighting and predatory cricket-killing, and inhibition of isolation-induced mouse fighting. The changes in rat aggression with 25 μg and in mouse aggression with 50 μg were not related to sedation or motor disturbance, since locomotor activity counts were normal as were brain levels of norepinephrine, dopamine, dihydroxyphenylacetic acid, serotonin, and 5-hydroxyindoleacetic acid. These changes seem to be related to an intracellular action of cGMP and appear to be specific for the guanine cyclic nucleotide.     

WATER-SOLUBLE AND PENTANOL-EXTRACTABLE PROTEINS IN HUMAN BRAIN NORMAL TISSUE AND HUMAN BRAIN TUMOURS, WITH SPECIAL REFERENCE TO S-100 PROTEIN

Disc electrophoretic separation of water-soluble and pentanol-extractable protein from normal human brain and human brain tumours (glioblastoma, neurinoma and medulloblastoma) on 10 per cent polyacrylamide gels showed minor differences between tissues. After disc electrophoresis ependymomal tumour cells contained high concentrations of a rapidly migrating anodic protein fraction which was immunologically distinct from S-100 protein. After electrophoresis of normal brain grey matter in a continuous buffer system, a rapidly migrating anodic protein fraction which was immunologically distinct from S-100 protein was found, and this protein fraction had a similar relative mobility to that of ependymomal tumour cells. This protein fraction was present to a low extent in human normal white matter, but absent from neurinoma and glioblastoma. In a continuous buffer system at least two separable protein fractions, immunologically equivalent to S-100 protein, were observed in normal human brain. The more anodic of these two fractions was shown to be present in relatively high amounts in neurinomas, and may be of Schwann cell origin. Additional S-100 protein could be extracted from residual material remaining after removal of water-soluble proteins; 2.8-10 per cent of the water-soluble S-100 in normal material, and 0.1-0.6 per cent of that present in tumour material, was extractable from the water-insoluble residue by pentanol.     

Identification of S-100 proteins and S-100-binding proteins in a detergent-resistant EDTA/KCl-extractable fraction from bovine brain membranes

The Triton X-100-resistant residue of brain membranes contains appreciable amounts of S-100 proteins. This fraction of S-100 can be solubilized by high concentrations of EDTA plus or minus high concentrations of KCl. Whereas KCl (0.6 M) extracts the detergent-resistant S-100, NaCl (1 M) does not. Endogenous Ca2+ is required and is sufficient for S-100 to remain associated with the detergent-resistant residue. However, 0.6 M KCl extracts a further fraction of Triton X-100-resistant S-100. In contrast, the Triton X-100-extractable fraction of S-100 resists the action of EDTA. These data suggest that Ca2+ regulates the extent of association of S-100 with Triton X-100-resistant components in brain membranes, whereas the association of S-100 with the lipid bilayer of brain membranes and/or with some intrinsic membrane proteins is less Ca2+-regulated. Several S-100-binding proteins are identified in the detergent-resistant residue of brain membranes by an overlay procedure.     

Proteins of the Brain Extracellular Fluid: Evidence for Release of S-100 Protein

Abstract: Extracellular protein fractions were obtained (1) by mild, isotonic irrigation of freshly perfused brain tissue; (2) by collection of proteins released into super-fusing medium by physiologically viable slices of rat hippocampus; and (3) by sampling the CSF of anesthetized rats. Analysis of the S-100 protein content of these fractions gave values of 2.8, 4.2, and 1.8 μg S-100/mg protein, respectively. These values were three- to sixfold higher than the S-100 content of the soluble cytoplasmic protein fractions from the same tissue. This several-fold higher S-100 content of the extracellular protein fractions relative to the intracellular cytoplasmic protein fractions indicates that S-100 is selectively released into the extracellular spaces of the brain. We suggest that the biological function of this CNS protein may involve intercellular transfer.     

Dynamics of neurospecific protein S-100 accumulation in the brain of AKR/J and DBA/2J strain mice in the process of postnatal development

The content of total S-100 protein and its water-soluble fraction was determined in the brain of DBA/2J and AKR/J mice during postnatal development. Reliable differences between the two strains were found in the content of total S-100 protein (from the 27th day after birth on) and its water-soluble fraction (from the 35th day).     

Modulation of brain protein phosphorylation by the S-100 protein

The effects of the nervous system specific protein, S-100, on protein phosphorylation in rat brain is examined. The S-100 protein inhibits the phosphorylation of several soluble brain proteins in a calcium dependent fashion. The most potent effect exhibited by S-100 was on the phosphorylation of a protein having a molecular weight of 73,000. The data suggest that the calcium binding S-100 protein, for which a function has not yet been assigned, may modulate calcium dependent phosphorylation of selected brain proteins.     

Formation of S-100 containing cells of the hypothalamus and adenohypophysis in normal ontogenesis and in protein deficiency

By means of the indirect immunohistochemical method distribution of S-100 containing cells has been studied in sections of the mediobasal hypothalamus (astrocytes) and adenohypophysis (follicular-stellate cells) in newborn, 10- and 21-day-old rats under normal development and under protein insufficiency. For this the animals are given the diet containing 6% of protein (control--25% of protein). S-100 containing cells are revealed in the hypothalamus and adenohypophysis in 10- and 21-day-old animals. In the brain of the newborn rats S-100 immunoreactive cells are not revealed. At the ultrastructural level the diaminobenzidine (DAB) reaction products in the immunoreactive cells are revealed diffusely along the whole cytoplasm of the cells, in nuclei the DAB reaction products are absent. Part of S-100 containing cells is essentially lowered, comparing with the control. In the rat adenohypophysis part of S-100 containing cells from the 10th up to the 21st day also decreases. Unlike the hypothalamus, however, content of cells, immunopositive to S-100 exceeds the analogous index in the control rats of the corresponding age groups.     

S-100 and Other Acidic Proteins Promote Ca2+-Independent Phosphorylation of Protamine Catalyzed by a New Protein Kinase from Brain

Abstract: A new protein kinase modulated by S-100 (tentatively referred to as protein kinase X) was partially purified from pig brain extracts. The activity of protein kinase X, which was independent of Ca²⁺, was demonstrated when protamine (free base), but not protamine sulfate and other proteins (including histone), was used as substrate. The enzyme activity, found to distribute in both soluble and particulate fractions and to occur at the highest level in brain compared with other tissues (heart, kidney, liver, skeletal muscle, spleen, and testis) of rats, was also modulated by other acidic proteins (calmodulin, troponin C, and stimulatory modulator) in a Ca²⁺-independent manner. S-100 and other acidic proteins appeared to function as "substrate modifiers" by interacting with protamine (a highly basic protein), but not with the enzyme, thus rendering protamine in the complex a superior phosphate acceptor. The two isoforms of S-100 (i.e., a and b) were equally effective. Although the enzyme was not inhibited by many agents (trifluoperazine, melittin, cytotoxin I, polymyxin B, and spermine) shown to inhibit markedly phospholipid/Ca²⁺- or calmodulin/Ca²⁺-stimulated protein kinase, gossypol was found to inhibit specifically protein kinase X. The present findings suggest that S-100, a major acidic protein specific to nervous system, may promote phosphorylation by protein kinase X of certain neural proteins resembling protamine or containing protamine-like domains, in addition to its presumed role of a low-affinity Ca²⁺-binding protein.     

Immunocytochemical study of the distribution of S-100 protein in the parathyroid gland of rats and guinea pigs

The distribution of S-100 protein in the parathyroid cells of normal and hypercalcaemic rats and guinea pigs was investigated. Previous studies had shown that the applied antibodies detect only the beta subunit of S-100 protein. S-100 protein was found in all parathyroid cells of rats aged between 1 and 720 days. In adult guinea pigs, S-100 protein was detectable in only a small proportion of parathyroid cells. The level of S-100 protein in individual cells exhibited considerable variation, particularly in guinea pig. Hypercalcaemia did not affect the distribution of S-100 protein in the parathyroid cells of either rats or guinea pigs. In both species, the presence of small groups of parathyroid cells in the central fragments of thyroid lobes was often noted.     

The relationship between different types of genetically defined aggressive behavior

Aggressive behavior is not a unitary trait, and different stimuli/situations elicit different kinds of aggressive behavior. According to numerous data the genotype plays a significant role in the expression of aggressive behavior. However, it remains unclear how genetic predisposition to one kind of aggression is linked with other kinds of aggressive behavior, especially pathological aggression (infanticide). Here, we report on our investigation of the expression of defensive, offensive, predatory and asocial aggression in wild rats selectively bred for 85 generations for either a high level or a lack of aggression towards humans. We found that those rats genetically predisposed to a high level of defensive aggression showed decreased social behavior and increased pathological aggressive behavior towards juvenile males. The highly aggressive rates showed a reduced latency time of attack and an increased latency time of the first social contact. Rats genetically predisposed to defensive aggression demonstrated increased predatory aggression—latency time of muricide was shorter in highly aggressive than in tame animals. At the same time, both lines of rats did not differ significantly in intermale aggression. We conclude that the data indicate a close relation between defensive, predatory and pathological aggressive behavior that allows us to suggest that similar genetic mechanisms underlie these types of aggressive behavior.     

Effect of endogenous oligopeptides and brain-specific proteins on aggressive behavior in the rat

In experiments on non-bred males of white rats, the effect was studied on their aggressive behaviour of intraventricular injections of brain-specific proteins of S-100 group, gamma-globuline fraction from the serum of rabbits immunized by proteines S-100 (gamma S-100) and non-immunized rabbits (gamma-SNK) as well as of angiotensin, bradikinin and saline. S-100 lowered intermales aggressivity and that connected with pain, and had phasic inhibitory effects on rats emotional reactivity. gamma S-100 increased the aggressivity connected with pain, did not affect the intermales aggressivity and phasically raised (as well as gamma-SNK) the emotional reactivity. gamma-SNK, angiotensin and bradikinin did not change these kinds of aggressivity. None of the administered agents influenced the level of rats predetary aggressivity.     

Appearance of a brain-specific antigen (S-100 protein) in the developing rat brain

Abstract— Thelevel of the S-100 protein, a brain-specific antigen, wasdetermined by quantitative complement fixation in the brain stem and cerebrum of the rat during postnatal maturation. The content was minimal at birth in the brain stem and rose to its adult value by day 25. Although S-100 protein could not be detected in the cerebrum of the 2-day-old rat, adult values were also present by the 25th day of age. Neither single dose X-irradiation with 750 rd to the head at 2 days of age or single dose X-irradiation at 11 days of age affected the adult level of S-100 protein in the brain stem or cerebrum. Similarly, hypophysectomy at 20 days of age had no effect on the subsequent levels of S-100 protein.     

Immunocytochemical study of the distribution of S-100 protein in the parathyroid gland of rats and guinea pigs

Summary The distribution of S-100 protein in the parathyroid cells of normal and hypercalcaemic rats and guinea pigs was investigated. Previous studies had shown that the applied antibodies detect only the subunit of S-100 protein. S-100 protein was found in all parathyroid cells of rats aged between 1 and 720 days. In adult guinea pigs, S-100 protein was detectable in only a small proportion of parathyroid cells. The level of S-100 protein in individual cells exhibited considerable variation, particularly in guinea pigs. Hypercalcaemia did not affect the distribution of S-100 protein in the parathyroid cells of either rats or guinea pigs. In both species, the presence of small groups of parathyroid cells in the central fragments of thyroid lobes was often noted.