The regional distribution and inducibility of cytokines in the normal brain is still a matter of controversy. As an attempt to clarify this issue, we studied the constitutive and induced expression of interleukin (IL)-1beta, IL-6, tumor necrosis factor (TNF)-alpha, and interferon (IFN)-gamma mRNAs in the brain, pituitary, and spleen of mice using qualitative and semiquantitative reverse-transcription polymerase chain reaction. The contribution of nonbrain cells to the cytokine transcripts detected was considered. With the exception of IFN-gamma mRNA, transcripts for the other cytokines were found to be constitutively present in the brain. Following i.p. injection of lipopolysaccharide (LPS) at a dose below those described to disrupt the blood-brain barrier (BBB), cytokine mRNA expression was increased in the spleen, the pituitary, and the brain. In the brain, the onset of transcription varied from 45 min (IL-1beta, TNF-alpha) to 4 hr (IFN-gamma), and the peak of mRNA accumulation was observed at different times depending on the cytokine and the brain region studied. IL-1 and IL-6 were highly expressed in the hypothalamus and hippocampus, while TNF-alpha expression was more marked in the thalamus-striatum. The cortex was the region in which cytokines were less inducible. The inducible expression of cytokine mRNAs in the brain was paralleled by stimulation of the hypothalamus-pituitary-adrenal axis. These results show the capacity of brain cells to synthesize different cytokine mRNAs in vivo and define the kinetics of their expression in several brain areas and in the periphery in parallel to the activation of a neuroendocrine pathway by endotoxin.
The levels of the antioxidants ascorbic acid, cysteine, reduced glutathione and a-tocopherol, of the free-radical marker uric acid and of the amino acids tyrosine and tryptophan were measured by means of high-pressure liquid chromatography in plaques, adjacent white matter and distant white matter from patients with multiple sclerosis, and in central nervous system tissue from patients without neurological diseases. Cholesterol and DNA were also determined, to check demyelination and cellularity. Uric acid was increased and glutathione correspondingly decreased in plaques; α-tocopherol was lowest in plaques and highest in distant white matter in all cases. Ascorbic acid, cysteine, tyrosine and tryptophan were not significantly changed in any tissue. The results provide evidence supporting the involvement of free radicals in multiple sclerosis.
Ascorbic acid, cysteine, glutathione and uric acid were determined by reverse-phase high-pressure liquid chromatography (HPLC) in 46 breast tissue samples [neoplastic (C) and non-neoplastic (N) from the same patient]. Cholesterol, alpha-tocopherol and gamma-tocopherol were quantified in 64 similar samples by extraction into heptane followed by direct-phase HPLC. DNA was measured in all samples and the percentages of epithelium, fat and connective tissue were estimated in sections adjacent to the sample. Results confirm previous findings that ascorbic acid and glutathione, expressed as mumol/g DNA, were greatly increased in the epithelium of neoplastic tissue. Similar increases in cysteine could be accounted for by the presence of inflammatory cells. Although values of alpha- and gamma-tocopherol correlated with the percentage of fat in both types of tissue, these compounds were also present in the epithelium. Because of the varying amounts of fat in the samples, no significant difference could be found between N and C values. Cholesterol correlated with fat in N and epithelium in C. Consideration of 10 cases with equal amounts of fat in C and N tissue suggests that cholesterol is reduced in C in the epithelial cells.
Processes relevant for an appropriate immune response such as immune cell traffic and recirculation require a tight control of blood supply to lymphoid organs. Interactions between endogenous cytokines and sympathetic nerve fibers in lymphoid organs can contribute to this control. The results reported in this paper show that 1) administration of low doses of lipopolysaccharide (LPS), an endotoxin derived from gram-negative bacteria, causes an increase in splenic blood flow (SBF); 2) this increase is mediated by the production of endogenous interleukin-1 (IL-1); 3) the effect of LPS on SBF requires an intact splenic sympathetic innervation; 4) the LPS-induced increase in SBF is exerted at the postganglionic level; 5) the endotoxin inhibits the vasoconstriction induced by the in vivo stimulation of the splenic nerve but does not affect the vasoconstriction induced by norepinephrine (NE); and 6) although IL-1 and LPS stimulate general sympathetic activity as reflected by increased peripheral vascular resistance, they do not increase NE concentration in splenic dialysates. Together these in vivo results indicate that endogenous IL-1 affects blood supply to the spleen by inhibiting the sympathetic vasoconstrictor tonus at a postganglionic, prejunctional level. This effect is expected to be relevant for immune cell recirculation, homing, and traffic as well as antigen trapping in the spleen, an organ specialized in the control of these processes during immune responses.
It is still unclear how the retinotectal map of the chick is formed during development. In particular, it is not yet known whether or not the organization of fibres plays a role in the formation of this map. In order to contribute to the solution of this problem, we analysed the representation of the retinal topography at closely spaced intervals along the fibre pathway. We injected HRP into various sites of the tectal surface and traced the labelled fibre bundles back to the retina. The retinal topography was reconstructed at ten different levels, i.e. in the retina, the optic nerve head, the middle of the optic nerve, the chiasm (three levels), the optic tract (three levels), and the optic tectum. We obtained the following results: (1) The labelled fibre bundles as well as the fields of labelled retinal ganglion cells were always well delimited and coherent. (2) The reconstructions show that transformations of the retinal topography occur in the fibre pathway. The first and most important transformation is found in the optic nerve head where the retinal image is mirrored across an axis extending from dorsotemporal to ventronasal retina. In addition, the retinal representation is split in its temporal periphery. Thus, central and centrotemporal fibres are no longer in the centre of the image but close to the dorsal border of the nerve. Peripheral fibres are found along the medial, ventral and lateral circumference of the nerve. In the optic tract a second transformation occurs. The retinal topography is rotated clockwise by about 90 degrees and flattened to a band. The flattening is accompanied by a segregation of fibre bundles so that eventually central and centrotemporal retinal fibres are located centrally, ventral fibres dorsally and dorsal retinal fibres ventrally in the tract. By these two transformations an organization of fibres is produced in the optic tract which can be projected onto the tectal surface without major changes given that dorsal and ventral fibres remain in their relative positions, and that deep lying fibres project to the rostral and central tectum, superficial fibres to the caudal tectum. The transformations which we have observed follow specific rules and thus maintain order in the pathway although retinotopy is lost. In conjunction with our earlier studies on the development of the retinotectal system we conclude that fibres are laid down in a chronotopic order. The transformations take place under particular structural constraints.(ABSTRACT TRUNCATED AT 400 WORDS)
The possibility that interleukin-1 (IL-1), a cytokine involved in immune and inflammatory mechanisms, can affect the blood flow of the spleen was considered because changes in spleen perfusion can affect immune cell recirculation, traffic, and homing. The results indicate that administration of a subpyrogenic dose of IL-1 induced a pronounced increase in splenic blood flow. This was not a general effect, because no change in blood flow of skeletal muscle was noticed. The studies also show that 1) the increase in splenic perfusion induced by IL-1 is to a large extent independent from the secondary induction of nitric oxide (NO), 2) the splenic blood flow in the rat is under sympathetic control, and 3) the effect of IL-1 on splenic blood flow is completely abrogated after surgical interruption of the splenic nerve, which is predominantly composed of sympathetic fibers. It is concluded that the IL-1-mediated increase in splenic blood flow is most likely based on the inhibition of the sympathetic vasoconstrictor tonus in the rat spleen. These results show that a cytokine released by activated immune cells can regulate the blood flow of a main lymphoid organ, the spleen, by affecting mechanisms under neural control.
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