Sleep. A physiologic role for IL-1 beta and TNF-alpha.

Interleukin-1 beta (IL-1 beta) and tumor necrosis factor-alpha (TNF-alpha) are involved in physiologic sleep regulation. Administration of exogenous IL-1 beta or TNF-alpha induces increased non-rapid eye movement sleep (NREMS). Inhibition of IL-1 or TNF reduces spontaneous sleep. There is a diurnal rhythm of TNF-alpha mRNA and IL-1 beta mRNA in brain with highest levels occurring during peak sleep periods. Mice lacking either the TNF 55-kD receptor or the IL-1 type I receptor sleep less than do strain controls. IL-1 beta and TNF-alpha are part of a larger biochemical cascade involved in sleep regulation; other somnogenic substances in this cascade include growth hormone-releasing hormone and nitric oxide. Several additional substances are involved in inhibitory feedback mechanisms, some of which inhibit IL-1 and TNF. A major challenge to sleep research is to define how and where these molecular steps produce sleep.

Overexpression of bradykinin type 2 receptors on glioma cells enhances bradykinin-mediated blood-brain tumor barrier permeability increase.

Variations in the expression levels of bradykinin (BK) type 2 receptors (B2R) in different brain tumors may explain variable increases in BK-mediated blood-brain tumor barrier (BTB) permeability. This study investigated whether elevation of the B2R expression levels on glioma cells enhances BK-mediated BTB permeability increases. Stable transfectants of C6 rat glioma cells overexpressing B2R were established by transfection with recombinant vectors harboring rat B2R cDNA sequence. Elevated B2R expression levels in transfectants were confirmed by quantitative real-time PCR, Western blots, and [3H]-BK binding studies. BTB permeability was quantified with autoradiography and expressed as a unidirectional transport constant, Ki, for [14C]-alpha-aminoisobutyric acid (AIB: Mr 103), using a rat brain tumor model. Baseline Ki values in tumors overexpressing B2R were not significantly higher than in control tumors. Ki values after BK treatment in tumors overexpressing B2R, however, were significantly higher than in control tumors. Western blots confirmed that B2R expression levels in vivo in tumors overexpressing B2R remained higher than in control tumors. These results suggested that alteration of B2R expression levels on tumor cells could modulate BK-mediated BTB permeability. Therefore, B2R expression levels in human glioma could be used to analyze the treatment results of patients undergoing treatment involving BK-modulated BTB permeability.