Sustained hypertension increases the density of AMPA receptor subunit, GluR1, in baroreceptive regions of the nucleus tractus solitarii of the rat.

AMPA-type glutamate receptors in the nucleus tractus solitarii (NTS) are necessary for the baroreceptor reflex, a primary mechanism for homeostatic regulation of blood pressure. Within NTS, the GluR1 subunit of the AMPA receptor is found primarily in dendritic spines. We previously showed that both GluR1 and dendritic spine density are increased in NTS of spontaneously hypertensive rats (SHRs). We hypothesize that both receptor and synaptic plasticity are induced by a sustained elevation in arterial pressure. To test the general nature of this hypothesis, we examined whether similar changes in GluR1 density are found in a renovascular model of hypertension, the DOCA-salt rat, and if these changes are preventable by normalizing blood pressure with hydralazine, a peripherally acting vasodilator. Using immunoperoxidase detection, GluR1 appears as small puncta at the light microscopic level, and is found in dendritic spines at the ultrastructural level. Following the development of hypertension, GluR1 spine and puncta counts were significantly greater in DOCA-salt rats than controls. Hydralazine treatment (4-5 weeks) prevented the development of hypertension in DOCA-salt rats and reduced blood pressure of SHRs to normotensive levels. The density of GluR1 puncta in the NTS was significantly reduced by hydralazine treatment in the SHR model. These results show that hypertension alters dendritic spines containing AMPA-type glutamate receptors within NTS, suggesting that adjustments in GluR1 expression within NTS are part of the synaptic adaptations to the hypertensive state.

Hyperalgesia in an animal model of multiple sclerosis.

Many individuals with multiple sclerosis (MS) experience clinically significant pain, yet the underlying neural mechanisms for MS pain are not understood. Experimental autoimmune encephalomyelitis (EAE) is a well-studied disease in rodents that mimics many clinical and pathological features of MS, including central nervous system inflammation and demyelination. To determine whether EAE is an appropriate model for MS-related pain, nociceptive responses in both male and female SJL mice were measured before and after immunization with myelin proteolipid protein peptide 139-151 (PLP(139-151)) in complete Freund's adjuvant to induce 'active' EAE. To determine if changes in nociception were due to direct effects of encephalitogenic T cells, nociceptive responses in female SJL mice were measured following the transfer of activated, PLP(139-151) specific T cells to induce 'passive' EAE. Both forepaw and tail withdrawal latencies to a radiant heat stimulus were measured. In both active and passive EAE, there was an initial increase in tail withdrawal latency (hypoalgesia) that peaked several days prior to the peak in motor deficits during the acute disease phase. During the chronic disease phase, tail withdrawal latencies decreased and were significantly faster than control latencies for up to 38 days post-immunization. This hyperalgesia was seen in both sexes and in both active and passive EAE models. Forepaw withdrawal latencies remained within 1-2 s of baseline latencies for the entire testing period, indicating that the hypoalgesia and hyperalgesia were most pronounced in clinically affected body regions. These results suggest that both active and passive EAE are useful models of MS-related pain.

Endogenous CD4+BV8S2- T cells from TG BV8S2+ donors confer complete protection against spontaneous experimental encephalomyelitis (Sp-EAE) in TCR transgenic, RAG-/- mice.

To investigate regulatory mechanisms which naturally prevent autoimmune diseases, we adopted the genetically restricted immunodeficient (RAG-1(-/-)) myelin basic protein (MBP)-specific T cell receptor (TCR) double transgenic (T/R-) mouse model of spontaneous experimental autoimmune encephalomyelitis (Sp-EAE). Sp-EAE can be prevented after transfer of CD4+splenocytes from naïve immunocompetent mice. RAG-1+ double transgenic (T/R+) mice do not develop Sp-EAE due to the presence of a very small population (about 2%) of non-Tg TCR specificities. In this study, CD4+BV8S2+ T cells that predominate in T/R+ mice, and three additional populations, CD4+BV8S2-, CD4-CD8-BV8S2+, and CD4-CD8+BV8S2+ T cells that expanded in T/R+ mice after immunization with MBP-Ac1-11 peptide, were studied for their ability to prevent Sp-EAE in T/R- mice. Only the CD4+BV8S2- T cell population conferred complete protection against Sp-EAE, similar to unfractionated splenocytes from non-Tg donors, whereas CD4-CD8-BV8S2+ and CD4+BV8S2+ T cells conferred partial protection. In contrast, CD4-CD8+BV8S2+ T cells had no significant protective effects. The highly protective CD4+BV8S2- subpopulation was CD25+, contained non-clonotypic T cells, and uniquely expressed the CCR4 chemokine receptor. Protected recipient T/R- mice had marked increases in CD4+CD25+ Treg-like cells, retention of the pathogenic T cell phenotype in the spleen, and markedly reduced inflammation in CNS tissue. Partially protective CD4+BV8S2+ and CD4- CD8-BV8S2+ subpopulations appeared to be mainly clonotypic T cells with altered functional properties. These three Sp-EAE protective T cell subpopulations possessed distinctive properties and induced a variety of effects in T/R- recipients, thus implicating differing mechanisms of protection.

Estrogen inhibits systemic T cell expression of TNF-alpha and recruitment of TNF-alpha(+) T cells and macrophages into the CNS of mice developing experimental encephalomyelitis.

Estrogen treatment has been found to have suppressive activity in several models of autoimmunity. To investigate the mechanism of 17 beta-estradiol (E2) suppression of experimental autoimmune encephalomyelitis, we evaluated E2 effects on TNF-alpha expression in the central nervous system (CNS) and spleen of C57BL/6 mice immunized with MOG 35-55/CFA. Kinetic analysis demonstrated that E2 treatment drastically decreased the recruitment of total inflammatory cells as well as TNF-alpha(+) macrophages and T cells into the CNS at disease onset. In contrast, E2 had only moderate effects on the relatively high constitutive TNF-alpha expression by resident CNS microglial cells. E2 treatment also had profound inhibitory effects on expression of TNF-alpha by splenic CD4(+) T cells, including those responsive to MOG 35-55 peptide. We propose that the mechanism of E2 protection may involve both systemic inhibition of TNF-alpha expression and local (CNS) recruitment of inflammatory cells, with modest effects on TNF-alpha expression by resident CNS microglial cells.

Inhibitory effects of incomplete Freund's adjuvant on experimental autoimmune encephalomyelitis.

Freund's incomplete adjuvant (IFA), an aqueous/oil emulsion that is widely used in combination with antigenic proteins and peptides to induce tolerance, is considered to be immunologically inert. However, sporadic reports indicate that IFA may itself have inhibitory properties on induction of adjuvant induced arthritis and spontaneous diabetes. In the current study, the effects of IFA/saline were evaluated on the induction of experimental autoimmune encephalomyelitis (EAE) in three different strains of mice. IFA/saline given i.p. in two doses of > 100 microl 10 days apart were found to inhibit EAE induction to varying degrees in all three strains of mice in a dose dependent fashion. The IFA/saline injections inhibited both mitogen and antigen-induced T cell proliferation, induced elevated secretion of IFN-gamma and IL-10 by neuroantigen specific T cells, and reduced expression of cytokines, chemokines, and chemokine receptors of CNS-infiltrating mononuclear cells. These data demonstrate for the first time a direct inhibitory effect of IFA/saline on EAE, and re-emphasize the need to properly control experiments using IFA to induce antigen-specific tolerance.