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.
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.
The possibility that norepinephrine (NE) influences lymphoid cell outflow independently of its vasoconstrictor action was investigated in the perfused rat spleen. Using agents that affect the vasoconstrictor tonus of the spleen, we observed an inverse correlation between flow resistance and splenic cell output. The curve obtained served as a reference for evaluating effects of different treatments on the number of cells that are mobilized at defined levels of flow resistance. Perfusion of the β-adrenergic blocker propranolol either alone or in combination with NE lowered splenic leukocyte outflow clearly beyond the number of cells expected at the corresponding flow resistance. No comparable effects were observed when the α-adrenergic blocker phentolamine was perfused. When the vasoconstrictor effect of NE was counteracted by papaverine, splenic cell outflow was significantly higher than expected for the level of flow resistance attained. Furthermore, when NE was perfused together with endotoxin, which does not inhibit the vasoconstriction induced by catecholamines, splenic cell mobilization was severalfold higher than expected at increased flow resistance. Propranolol abrogated this effect to a large extent. Furthermore, perfusion of the β-agonist isoproterenol stimulated lymphoid cell outflow from the spleen despite increased flow resistance. These studies show a dual effect of NE on cell mobilization from the spleen: cell retention by decreasing blood flow and stimulation of cell output by a β-adrenergically mediated, smooth muscle-independent mechanism.
A BSTRACT : Lipopolysaccharide (LPS), an endotoxin that elicits the production of several cytokines, induces cardiovascular changes characterized by increased perfusion of immune organs and compensatory sympathetic vasoconstriction in other tissues. We therefore hypothesized that to adapt to altered blood flow distribution following LPS administration, changes in the sensitivity of reflexes that control blood pressure would occur. Our data show that the sensitivity of the baroreceptor reflex increases significantly two and three hours after the intravenous administration of a subpyrogenic dose of the endotoxin. This change in sensitivity that could occur at peripheral or central levels may underlie necessary adjustments of cardiovascular mechanisms during the course of certain immune responses.
Objectives: The noradrenergic innervation of lymphoid organs controls several immune cell functions and local blood perfusion. Considering that cell and antigen uptake depend on the blood supply to lymphoid organs, the hypothesis was tested that feedback signals from activated immune cells control sympathetic vasomotor activity. Methods: We determined the blood flow in spleen and mesenteric lymph nodes (mLN) of Wistar Kyoto rats during immune stimulation with endotoxin (LPS; 10 µg/kg) and following disruption of the noradrenergic transmission. Results: Our data indicate that (a) the splenic noradrenaline content, which reflects the density of the sympathetic innervation, is 5 times higher in the spleen than in other peripheral organs and the spleen receives stronger tonic sympathetic input than mLN; (b) immune stimulation with LPS causes a 4-fold increase in the IL-1β production in the spleen, but only 2-fold in mLN; (c) IL-1β causes an inhibition of the sympathetic vasoconstrictor tonus in the spleen, but has no significant effect on the noradrenergic vascular tonus in mLN, and (d) in mLN, the local hyperemia induced by LPS is attenuated by the degranulation of vesicular stores of histamine and serotonin, indicating that these monoamines participate in the vasodilator effect of LPS in mLN. Conclusions: The present experiments, taken together with our previous studies, indicate that the control of blood supply to the spleen and mLN involves different mechanisms. While blood perfusion in the spleen depends on the inhibition of the noradrenergic vasoconstriction by endogenously produced IL-1β, other vasoactive mediators such as serotonin and histamine play a role in the control of mLN perfusion.
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