Endothelial Cell-Astrocyte Interactions

Peer Reviewedhttp://deepblue.lib.umich.edu/bitstream/2027.42/75690/1/j.1749-6632.1988.tb51417.x.pd

The systemic and local acute phase response following acute brain injury

It is not known whether acute brain injury results in a systemic acute phase response (APR) or whether an APR influences outcome after an insult to the CNS. The present study sought to establish whether brain injury elicits a systemic or local APR. The expression of acute phase protein (APP) mRNA in liver and brain tissues was measured by Taqman reverse transcriptase-polymerase chain reaction after an excitotoxic lesion in the striatum or challenge with a proinflammatory cytokine. N-methyl-d-aspartate (NMDA)–induced brain lesion did not elicit a systemic APR. In contrast, proinflammatory challenge with mouse recombinant interleukin-1beta (mrIL-1beta) resulted in a significant hepatic APP mRNA expression within 6 hours. Thus, an inflammatory challenge that results in a meningitis leads to a hepatic APR, whereas acute brain injury alone, with no evidence of a meningitis, does not produce an APR. This is surprising because NMDA leads to an increase in endogenous IL-1beta synthesis. This suggests that the brain has an endogenous antiinflammatory mechanism, which protects against the spread of inflammation after an acute injury. In the brain, both excitotoxic lesions and proinflammatory challenge resulted in a profound parenchymal upregulation of APP mRNA after 6 and 12 hours in the injected hemisphere. These results suggest that the local APR may play a role as an antiinflammatory mechanism. These findings indicate a potentially pivotal role for peripheral and local APP production on outcome after brain injury

Effect of zinc supplementation on the immune status of healthy older individuals aged 55–70 years : the ZENITH Study

Aging is associated with alterations in the immune system, effects which may be exacerbated by inadequate zinc (Zn) status. We examined the relationship between Zn status and markers of immunity and the effect of supplementation with 15 mg or 30 mg Zn/d for 6 months on immune status in healthy individuals. Zn status was assessed by dietary intake and biochemical indices. Immune status was assessed by multiple flow cytometric methods. At baseline, Zn concentration was positively associated with lymphocyte subpopulation counts and T-lymphocyte activation. Zn supplementation of 30 mg/d significantly lowered B-lymphocyte count, albeit at month 3 only. Lower doses of Zn (15 mg Zn/d) significantly increased the ratio of CD4 to CD8 T lymphocytes at month 6. Overall, these findings suggest that total Zn intake (diet plus supplementation) of up to 40 mg Zn/d do not have significant long-term effects on immune status in apparently healthy persons aged 55&ndash;70 years.<br /

Immune response in deep cervical lymph nodes and spleen in the mouse after antigen deposition in different intracerebral sites

Brain interstitial and cerebrospinal fluid drainage into the lymphatics was studied by injections of 5 microliters of packed sheep red blood cells (SRBC) injected into the caudate nucleus, the occipital lobe, and the lateral ventricle of the brain in mice. The number of plaque-forming cells (PFC) was determined in the deep cervical lymph nodes, the axillary lymph nodes, and the spleen, and the number of PFC was compared with the response in the same tissues after intravenous immunization with 0.1 ml 10% SRBC. The weight of the deep cervical lymph nodes increased 3.0 times on day 3 after injection in the brain parenchyma compared with the weight of these nodes after intravenous immunization. The antigen-specific response peaked on day 5, 392 +/- 37 PFC/10(6) for IgG in the deep cervical lymph nodes after antigen deposition in the caudate nucleus, whereas only a minor peak in the antigen-specific response was obtained after intraventricular antigen deposition, 127 +/- 79 PFC x 10(6) for IgG on day 6. There were no increased PFC in any of the lymph nodes after intravenous immunization. The experiments show an antigen-specific response in the deep cervical lymph nodes after intracerebral antigen deposition, whereas antigens deposited in the lateral ventricles drain preferentially to the blood, with a high response in the spleen