Is the Cerebellum Involved in the Nervous Control of the Immune System Function?

BACKGROUND: According to the views of psychoneuroendocrinoimmunology, many interactions exist between nervous, endocrine and immune system the purpose of which is to achieve adaptive measures restoring an internal equilibrium (homeostasis) following stress conditions. The center where these interactions converge is the hypothalamus. This is a center of the autonomic nervous system that controls the visceral systems, including the immune system, through both the nervous and neuroendocrine mechanisms. The nervous mechanisms are based on nervous circuits that bidirectionally connect hypothalamic neurons and neurons of the sympathetic and parasympathetic system; the neuroendocrine mechanisms are based on the release by neurosecretory hypothalamic neurons of hormones that target the endocrine cells and on the feedback effects of the hormones secreted by these endocrine cells on the same hypothalamic neurons. Moreover, the hypothalamus is an important subcortical center of the limbic system that controls through nervous and neuroendocrine mechanisms the areas of the cerebral cortex where the psychic functions controlling mood, emotions, anxiety and instinctive behaviors take place. Accordingly, various studies conducted in the last decades have indicated that hypothalamic diseases may be associated with immune and/or psychic disorders. OBJECTIVE: Various researches have reported that the hypothalamus is controlled by the cerebellum through a feedback nervous circuit, namely the hypothalamocerebellar circuit, which bi-directionally connects regions of the hypothalamus, including the immunoregulatory ones, and related regions of the cerebellum. An objective of the present review was to analyze the anatomical bases of the nervous and neuroendocrine mechanisms for the control of the immune system and, in particular, of the interaction between hypothalamus and cerebellum to achieve the immunoregulatory function. CONCLUSION: Since the hypothalamus represents the link through which the immune functions may influence the psychic functions and vice versa, the cerebellum, controlling several regions of the hypothalamus, could be considered as a primary player in the regulation of the multiple functional interactions postulated by psychoneuroendocrinoimmunology.

Choline and Choline alphoscerate Do Not Modulate Inflammatory Processes in the Rat Brain.

Choline is involved in relevant neurochemical processes. In particular, it is the precursor and metabolite of acetylcholine (ACh). Choline is an essential component of different membrane phospholipids that are involved in intraneuronal signal transduction. On the other hand, cholinergic precursors are involved in ACh release and carry out a neuroprotective effect based on an anti-inflammatory action. Based on these findings, the present study was designed to evaluate the effects of choline and choline precursor (Choline alphoscerate, GPC) in the modulation of inflammatory processes in the rat brain. Male Wistar rats were intraperitoneally treated with 87 mg of choline chloride/kg/day (65 mg/kg/day of choline), and at choline-equivalent doses of GPC (150 mg/kg/day) and vehicle for two weeks. The brains were dissected and used for immunochemical and immunohistochemical analysis. Inflammatory cytokines (Interleukin-1ß, IL-1ß; Interleukin-6 , IL-6 and Tumor Necrosis Factor-α, TNF-α) and endothelial adhesion molecules (Intercellular Adhesion Molecule, ICAM-1 and Vascular cell Adhesion Molecule, VCAM-1) were studied in the frontal cortex, hippocampus, and cerebellum. The results clearly demonstrated that treatment with choline or GPC did not affect the expression of the inflammatory markers in the different cerebral areas evaluated. Therefore, choline and GPC did not stimulate the inflammatory processes that we assessed in this study.

Expression of T cell receptor beta locus in central nervous system neurons.

MHC class I proteins are cell-surface ligands that bind to T cell receptors and other immunoreceptors and act to regulate the activation state of immune cells. Recent work has shown that MHC class I genes and CD3zeta, an obligate component of T cell receptors, are expressed in neurons, are regulated by neuronal activity, and function in neuronal development and plasticity. A search for additional neuronally expressed T cell receptor components has revealed that the T cell antigen receptor beta (TCRbeta) locus is expressed in neurons of the murine central nervous system and that this expression is dynamically regulated over development. In neonates, expression is most abundant in various thalamic nuclei. At later ages and in adults, thalamic expression fades and cortical expression is robust, particularly in layer 6. In T cells, protein-encoding transcripts are produced only after recombination of the TCRbeta genomic locus, which joins variable, diversity, and joining regions, a process that creates much of the diversity of the immune system. We detect no genomic recombination in neurons. Rather, transcripts begin in regions upstream of several joining regions, and are spliced to constant region segments. One of the transcripts encodes a hypothetical 207-aa, 23-kDa protein, which includes the TCRbeta J2.7 region, and the entire C region. These observations suggest that TCRbeta may function in neurons.

Changes in immunoreactivity to anti-cGnRH-I and -II are associated with photostimulated sexual status in male quail.

In sexually active males exposed to long-day (LD) photoperiod, perikarya in the olfactory bulb, lobus parolfactorius, n. accumbens, and preoptic region were immunoreactive (ir) to an antiserum against gonadotropin-releasing hormone (anti-cGnRH-I), and a cluster of ir-perikarya was found in the caudal-most septal area. Ir-perikarya in these brain areas of sexually inactive short-day (SD) males were located within more discrete areas than those in LD brain, which were more scattered in appearance. Absolute cell numbers were similar between LD and SD brains. Ir-fibers in LD brains were mostly in the external median eminence, along the lateral ventricle to septum (especially in and about the n. accumbens), in the septal-preoptic area, along the third ventricle, and at the n. commissure palli. There were fewer ir-fibers in SD brain. Many small dark ring-like ir-structures were found in the hyperstriatum, hippocampus, and n. taeniae. Interpreted as being ir-terminals on non-ir perikarya, these were not observed in SD males. cGnRH-II ir-perikarya were observed in only two areas regardless of reproductive status: (1) ventral to the substantia grisea centralis and caudal to the oculomotor complex, and (2) scattered in and about the lateral hypothalamus. Ir-fibers occurred in the habenular area, hyperstriatum, hippocampus, parahippocampal area, cortex piriformis, and n. taeniae. cGnRH-II ir-fibers occurred in the external median eminence but were less intensely stained than cGnRH-I ir-fibers. These fibers in SD males were similar except in the diencephalon, where scattered swellings were observed. Thus, the appearance and distribution of anti-cGnRH-I and -II ir-structures change with the sexual status of male quail, but changes in immunoreactivity to anti-cGnRH-I appear to be more widespread.

Effects of vagotomy on lipopolysaccharide-induced brain interleukin-1beta protein in rats.

The production of interleukin-1beta (IL-1beta) in brain is thought to be a critical step in the induction of central manifestations of the acute phase response, and the vagus nerve has been implicated in immune-to-brain communication. Thus, this study examined the effects of intraperitoneal (i.p.) injections of lipopolysaccharide (LPS) on brain IL-1beta protein levels in control and subdiaphragmatically vagotomized rats. In the first experiment, vagotomized and sham-operated male Sprague-Dawley rats were injected i.p. with one of three doses (10, 50, 100 microg/kg) of LPS or vehicle (sterile, pyrogen-free saline) and sacrificed 2 h after the injection. In the second experiment, vagotomized and sham-operated rats were injected i.p. with 100 microg/kg LPS or vehicle and sacrificed 1 h after the injection. The i.p. injection of LPS dose-dependently increased IL-1beta protein levels in the hypothalamus, hippocampus, dorsal vagal complex, cerebellum, posterior cortex, and pituitary 2 h after the injection. Brain and pituitary IL-1beta levels were also significantly increased 1 h after the injection of 100 microg/kg LPS. There were no significant differences in brain IL-1beta levels between sham-operated and vagotomized rats at either the 2 h or 1 h time points. The current data are consistent with previous studies showing increases in brain IL-1beta after peripheral injections of LPS, and support the notion that brain IL-1beta is a mediator in the illness-induction pathway. Furthermore, these data indicate that, at the doses and times tested, subdiaphragmatic vagal afferents are not crucial for LPS-induced brain IL-1beta protein.

Immunohistochemical localization of calretinin in the rat hindbrain.

The localization of calretinin in the rat hindbrain was examined immunohistochemically with antiserum against calretinin purified from the guinea pig brain. Calretinin immunoreactivity was found within neuronal elements. The distribution of calretinin-immunoreactive cell bodies and fibers is presented in schematic drawings and summarized in a table. Major calretinin-immunoreactive neurons were found in the lateral and medial geniculate nuclei, substantia nigra, ventral tegmental area, interpeduncular nucleus, periaqueductal gray, mesencephalic trigeminal nucleus, superior and inferior colliculi, pontine nuclei, parabrachial nucleus, dorsal and laterodorsal tegmental nuclei, cochlear nuclei, vestibular nuclei, medullary reticular nuclei, nucleus of the solitary tract, area postrema, substantia gelatinosa of the spinal trigeminal nucleus, and cerebellum. These results show that distinct calretinin-immunoreactive neurons are widely distributed in the rat hindbrain.

A monoclonal antibody to limbic system neurons.

A monoclonal antibody produced against hippocampal cell membranes labeled the surface of neurons in the rat limbic system. With a few exceptions, all nonlimbic components were unstained. This specific distribution of immunopositive neurons provides strong evidence of molecular specificity among functionally related neurons in the mammalian brain and supports the concept of a limbic system.

[Effect of D,L-dopa on the content of protein antigens in rat brain structures]. / Vliianie D,L-DOFA na soderzhanie belkov-antigenov v nekotorykh strukturakh mozga krys.

Cross immunoelectrophoresis was used to study the effect of administering the noradrenaline precursor D,L-DOPA on the content of water-soluble antigens in the hypothalamus, cerebellum and frontal cortex of rats. The content of 3 out of the 10 antigens under study significantly increased in the hypothalamus and that of 2 in the cerebellum after intraperitoneal injection of D,L-DOPA. The content of these antigens was greater in the structures with a high noradrenaline level.

Distribution of Thy-1 in human brain: immunofluorescence and absorption analyses with a monoclonal antibody.

A monoclonal antibody to human Thy-1 has been used to study the anatomical localization of Thy-1 in human brain and to quantitate the relative amounts of Thy-1 in different brain subregions. Quantitative absorption analyses using homogenates of carefully dissected brain subregions, together with an [125I]anti-immunoglobulin binding assay using brain homogenate as target, established that Thy-1 was present in large amounts throughout human brain, but the grey matter of cerebrum (cortical grey matter, caudate nucleus, putamen and thalamus) had 5-10 times as much Thy-1 as white matter. Grey matter of cerebellum (cerebellar cortex and dentate nucleus) also had higher amounts of Thy-1 than white matter, but the total amount of Thy-1 in cerebellum was less than in the cerebrum. Immunofluorescence studies gave interesting results and demonstrated in particular: (a) the outlining of some neuronal cell bodies and their processes (particularly the Purkinje cells of the cerebellar cortex) by spots of fluorescence; (b) staining of what appeared to be cell bodies of satellite cells in areas of grey matter; (c) granular staining in grey but not white matter; (d) staining of what appeared to be fibre tracts in the basal ganglia and thalamus, the tracts appearing duller than the surrounding grey matter of the nuclei; (e) staining of only some fibres in sciatic nerve; and (f) absence of staining of the adrenal gland.

[Changes in protein synthesis in different brain regions following experimental neurosensitization]. / Izmenenie sinteza belkov v raznykh otdelakh mozga krys pri éksperimental'noi neirosensibilizatsii.

Protein resynthesis was studied in CNS structures of rats sensitized with antigens from different regions of the allogenous brain. There was an activation of 35S-methionine incorporation into brain proteins in accordance with the immunization antigen used, and in proteins from other structures. Radiomethionine distribution in brain tissue remained unchanged. Potential mechanisms of protein resynthesis alteration during neurosensitization are discussed.

[Changes in the state of the blood-brain barrier in rats following experimental neurosensitization]. / Izmenenie sostoianiia gematoéntsefalicheskogo bar'era u krys pri éksperimental'noi neirosensibilizatsii.

The accumulation and distribution of phosphorus radioisotope was studied in different brain areas of rats. These rats were desensitized by antigens of a whole homologous brain and its separate structures. A certain general tendency towards an accumulation of the brain phosphorus was detected after neurosensitization. Besides, in sensitization by separate structures (brain cortex, cerebellum) the most pronounced changes were in the hematoencephalic barrier (HEB) of the corresponding brain areas are less pronounced in other structures. The paper contains data concerning the function of HEB in animals immunized by the medulla oblongata. The found changes in the barrier mechanisms of the HEB in neurosensitization may be one of the pathogenetical mechanisms of certain diseases accompanied by neuroautoimmune processes.

Significance of brain-reactive antibodies in serum of aged mice.

The possible role of damaged neurons as an antigenic stimulant in the formation of brain reactive antibodies (BRA) has been studied. When neurons of the ventral horn of the spinal cord were damaged by axonal injury, the damaged cells showed no evidence of antigen-antibody reaction within 12 weeks, nor could BRA be demonstrated in the blood during that time in young mice. The possible migration of radio-labeled gamma-globulin across the blood-brain-barrier (BBB) has also been investigated in young mice. Only a very low rate of migration has been observed across the BBB and this might account for the scattered loss of nerve cells in the brains of old animals.