Involvement of brain dopaminergic structures in neuroimmunomodulation

Bilateral electrolytic destruction of the brain areas containing dopamine (DA) cell bodies (nuclei A9 and A10) as well as terminal regions of the nigrostriatal and mesolimbic DAergic systems (nuclei caudatus and accumbens) resulted in a considerable decrease in the intensity of the immune response in rats immunized with sheep red blood cells (SRBC). Administration of SRBC (5 x 10(8) i.p.) to rats produced a marked rise in activity of central DAergic system at early stage of the immune response formation. The most pronounced elevation in the concentration of DA and its metabolites, measured by the method of high performance liquid chromatography with electrochemical detection, was observed in the terminal regions of the nigrostriatal and mesolimbic DAergic systems (nuclei caudatus and accumbens), hypothalamus, hippocampus, amygdala within 20 min following antigen inoculation. By 60 min after immunization DA metabolism has been retained at a high level in all brain regions examined. The concentration of DA returned to control level in the amygdala and hypothalamus 24 hours after antigen administration and had a tendency to reach control values in the rest of the structures. The present results indicate that nigrostriatal and mesolimbic DAergic systems and DAergic structures of the hypothalamus are involved in the mechanisms of neuroimmunomodulation.

Modulation of the immune response by changing neuromediator systems activity under stress

The possible correction of the immune response affecting the mechanisms of neuroimmunomodulation in the animal model of immobilization stress is considered. Immobilization (3 h on the back) of CBA mice caused a suppression of the immune response. The number of plaque-forming cell (PFC) on the 4th day as well as rosette-forming cell (RFC) number on the 5th day of the immune reaction to sheep red blood cells (SRBC) were found to be reduced as compared to the control. Immunoinhibition in the stressed mice was reversed by the depletion of the cerebral serotonin (5-HT) with p-chlorophenylalanine (PCPA) 2 days before immobilization at a dose of 500 mg/kg. Activation of postsynaptic D-1 and D-2 dopamine (DA) receptors with apomorphine administered 30 min before stress attenuated stress-induced immunosuppression as well. Thus, the immunosuppression elicited by a stressor can be modified by drugs influencing the 5-HT and DAergic systems. It is suggested that the stress-provoked alterations of the immune response can be a consequence of changing neurochemical pattern of the brain and the disturbances of the mechanisms of psychoneuroimunomodulation.

Involvement of delta-opioid receptors in immunosuppression

The present experiments demonstrate that: (1) activation of delta-opioid receptors by a highly selective agonist DSLET leads to immunosuppression, whereas the blockade of these receptors by enkephalin analog ICI 174864 produces immunostimulation; (2) the immunomodulating effect of delta-opioid receptors is mediated by central mechanisms involving the hypothalamus-hypophysis complex; (3) the postsynaptic 5-HT (serotonin) receptors of 5-HT-2 type are involved in the immunoinhibitory action of DSLET. On the other hand, the immunostimulating effect of ICI 174864 is realized with the participation of D-2 postsynaptic DA (dopamine) receptors. It has also been shown that thymus is implicated in the immunostimulating influence of ICI 174864. The data obtained are explained as a result of the interaction of the neuromediator and opioid peptidergic systems in neuroimmunomodulation.

Brain neuromediator systems in the immune response control: pharmacological analysis of pre- and postsynaptic mechanisms

The involvement of the dopaminergic (DAergic), GABAergic and serotoninergic (5-HTergic) synaptic mechanisms in neuroimmunomodulation are considered. It is shown that the central DA- and GABAergic systems exert a stimulatory influence on the immune reactivity. Activation of postsynaptic DA receptors with apomorphine and (+)(3-hydroxyphenyl)-N-n-propylpiperidine [(+)-3-PPP] at high doses, D2 receptor activation with quinpirole, as well as DA reuptake blockade with amantadine and bupropion, resulted in an increase in the immune response. The intensity of the immune response was also increased during activation of the GABAergic system with the GABA agonist muscimol or the benzodiazepine agonists diazepam and tazepam. On the other hand, decreases in the activity of either system by different drugs inhibiting DAergic and GABAergic neurotransmission (antagonists of DA postsynaptic receptors haloperidol at 1.0 mg/kg and (-)-3-PPP at 6.8 mg/kg, agonists of DA autoreceptors apomorphine at 0.02 mg/kg, (-)- and (+)-3-PPP at 1.7 and 3.4 mg/kg, antagonist of GABA receptors bicuculline, blocker of chloride channels picrotoxin, blockers of benzodiazepine receptors Ro 15-1788 and Ro 15-3505) produce suppression of the immune response. The 5-HTergic system is involved in the inhibitory mechanism of neuroimmunomodulation. 5-HT reuptake blockade with 4-(5,6-dimethyl-R-benzophuranil)-piperidine (CGP-6085A) and sertraline led to immunosuppression.

Immune responses in male mice with aggressive and submissive behavior patterns: strain differences

Immune responses in two strains of male mice with aggressive and submissive behavior patterns was studied. In aggressive CBA males immunized on the 10th day of agonistic confrontations with submissive partners, greater numbers of plaque-forming cells (PFC) and rosette-forming cells (RFC) were noted compared to control mice. Unlike the CBA strain, both PFC and RFC levels in aggressive C57BL males did not increase, but both PFC and RFC numbers decreased in submissive animals.

Participation of a GABA-ergic system in the processes of neuroimmunomodulation

Participation of a GABA-ergic system in neuroimmunomodulation was established through the use of a large number of chemical compounds which selectively modulate the activity of the GABA-BD-receptor-ionophore complex. Activation of the GABA-receptors with muscimol or activation of the BD-receptors with diazepam or tazepam had stimulatory effects upon immunogenesis. A decrease in the GABA-BD-receptor-ionophore complex activity led to a suppression of the immune response. The effect was achieved with: a blockade of the complex with bicuculline--a competitive inhibitor of the GABA-receptors: administration of a specific antagonist of the BD-receptors flumazenil or Ro 15-3505: or with blockade of chloride channels with picrotoxin. Activation of the GABA-ergic system causes an increase in bone marrow content of T-helper cells marked by L3T4. The immunomodulatory action of the GABA-ergic system is of central origin and can occur only when the hypothalamo-pituitary system is intact. Section of the pituitary stalk prevents accumulation of the T-helper cells in the bone marrow. The result show that the influence of GABA-ergic system on immunogenesis requires participation of both dopaminergic and serotoninergic systems.

Participation of serotoninergic system in neuroimmunomodulation: intraimmune mechanisms and the pathways providing an inhibitory effect

Exogenous serotonin administration as well as its precursor 5-oxytryptophan, blockade of the ferment inactivation by MAO inhibition, impairment of the monoamine binding, in other words, all the ways of elevation of active serotonin level, result in the inhibition of the immune response. On the contrary, exclusion of the serotoninergic system by the nuclei raphe lesion and the blockade of the synthesis ferments by p-chlorphenylalanine and p-chloramphetamine stimulates it. The present analysis permits us to conclude that the nuclei raphe serotoninergic system provides an inhibitory mechanism of the immune response modulation, that is realized via the hypothalamus-hypophysis-adrenals axis. Immune response modulation by the extraimmune control system is possible only be means of the mechanisms that are present in the immunocompetent system. Investigation of the cellular basis of physiological mechanisms of serotoninergic regulation of the immune process made it possible to determine alterations in the correlation of functionally different cell populations in animals with elevated serotonin level. An inhibitory action which serotonin produces upon the immunogenesis, is based on the attenuation of suppressor cell function, an earlier than under the normal immune response development emergence of suppressor in the population of cell organs, and their longer presence, that is to some extent connected with the redistribution of cell populations in the immunocompetent organs. After serotonin administration only the antigen-nonspecific immunosuppression is activated. In evolutionary terms the mechanisms of nonspecific suppression have been formed earlier than those of specific ones (Calkins & Stutman, 1978; Mijawaki, Seki, Kubo & Tanigushi, 1979). It is quite reasonable that extraimmune modulation, and psychoneuroimmunomodulation by monoamine systems in particular, can be performed by means of this ancient antigen-nonspecific mechanism of the immune response regulation. In this case, the modulation of immunological reactivity should correspond to these endogenous and environmental influences. Thus, activation of the nonspecific suppression induced through the serotoninergic system can be considered as the universal mechanism which on the one hand completes control of the immune homeostasis and on the other may be the precondition of the development of pathological states caused by the reduction of immunological status.

Monoamines as immunomodulators: importance of suppressors and helpers of the bone marrow

The intraimmune pathways and mechanisms of action of the serotoninergic and dopaminergic systems in exerting a modulating effect upon immunogenesis are presented. Experiments were carried out in mice immunized with sheep red blood cells (1 X 10(7); 5 X 10(6)). Participation of the hypothalamic-pituitary complex in the monoaminergic mechanisms of stimulation and inhibition of rosette formation was revealed. Dissection of the pituitary stalk prevented stimulation of rosette formation by apomorphine (1 mg/kg i.p) and bupropion (20 mg/kg) and the reduction of the immune response by haloperidol (1 mg/kg), 5-hydroxytryptophan (300 mg/kg) and serotonin (50 mg/kg). The results of syngeneic cellular transfer of different immunocompetent organs showed that serotonin injection induced an increase in B-suppressor activity of bone marrow cells, reaching maximal value in the inductive period (day 3 of the immune response). B-Lymphocyte suppression in donors not treated with serotonin peaked on day 5 of the immune response. Stimulation of the immune response under activation of the dopaminergic system after apomorphine administration was provided by an increase in T-helper activity in the bone marrow cells, mainly with respect to IgM-response. The suppressive activity of bone marrow T cells on IgM- and IgG-immune responses was increased in nonimmunized donors treated with serotonin or haloperidol. The mechanisms of neurochemical multichannel immunomodulation by means of redistribution of cellular populations resulting in an increase in suppressors or helpers in bone marrow are discussed.

5-Hydroxytryptophan effect on the development of the immune response: IgM and IgG antibodies and rosette formation in primary and secondary responses

In animals immunized with bovine serum albumin, 5-hydroxytryptophan prolonged the latent period of the IgM and IgG primary responses, decreased response intensity, delayed the response peak and suppressed IgG immunological memory. In 5-hydroxytryptophan-treated mice, the number of rosette-forming cells (RFC) in the lymph node and spleen decreased during the primary and secondary responses. This effect was due to the decreased number of IgG RFC and to the later involvement of IgM RFC in the immune response. The absence of the secondary response was related to unprimed IgG memory cells. 5-hydroxytryptophan does not inhibit the primary and secondary responses after the connections between the hypothalamus and pituitary have been disrupted. The participation of the n.raphe-hypothalaminc-pituitary system in immuno-regulation and the putative mechanism underlying serotonin effect on the immune response are discussed.