Vascular endothelial growth factor expression is independent of hypoxia in human malignant glioma spheroids and tumours.

We recently showed that severe hypoxia was not universally present adjacent to necrosis in human glioma xenografts and spheroids established from the M059K, M006, M006X, M006XLo and M010b cell lines. Using these glioma models, we wished to test whether oxygen serves as a regulator of cellular VEGF expression in situ. In situ hybridization (ISH) and immunohistochemistry (IHC) were used to detect vascular endothelial growth factor (VEGF) mRNA and protein expression in sections of glioma xenografts and spheroids in which hypoxic regions and regions with well-oxygenated necrosis were identified on contiguous sections by use of the hypoxia-specific marker, 3H-misonidazole. Independent validation of the presence of radiobiologically hypoxic cells in M006 xenografts was undertaken using the comet assay. Northern blotting analyses of monolayer cells demonstrated significant up-regulation of VEGF mRNA in the M006X line at oxygen concentrations of 6% and below. ISH analysis of VEGF mRNA showed unexpectedly strong staining for VEGF mRNA across the entire viable rim of M006X and M006XLo glioma spheroids. Similarly, in virtually all xenograft tumours of the M059K, M006 and M010b lines, VEGF ISH showed similar staining across all regions of healthy cells up to the border of necrosis. Only in one M006X tumour was there a suggestion of increased VEGF expression in cells adjacent to necrosis. IHC for VEGF showed good concordance with the ISH results. IHC analysis of the VEGF receptor flt-1 showed strong tumour cell staining in M006XLo glioma cells. In human glioma spheroids and xenograft tumours, regions of severe hypoxia do not correspond to areas of up-regulated VEGF expression; in fact, VEGF expression is quite uniform. Furthermore, this and our previous study demonstrate that levels of VEGF expression vary among sublines (M006, M006X and M006XLo) derived from a single human glioma specimen.

Exogenous IL-10 and IL-4 down-regulate IL-6 production by SLE-derived PBMC.

The elevated expression of IL-6 and IL-10 may have an important role in SLE pathogenesis. IL-6 production by normal monocytes can be inhibited by IL-10, and it has been suggested that SLE monocytes are refractory to this negative signal. To examine this possibility, the effects of regulatory factors on IL-6 expression by SLE PBMC (N = 51) were compared to effects on control PBMC (N = 21). We found that (1) exogenous rIL-10 and rIL-4 mediated reduction of constitutive and lectin-induced IL-6 in monocytes of SLE patients as effectively as that of controls; (2) IL-6 mRNA decay was significantly delayed in SLE with active disease (P < 0.001); (3) adding rIL-10 or neutralizing endogenous IL-1 beta and TNF-alpha down-regulated IL-6 mainly by destabilizing IL-6 transcripts, whereas exogenous IL-4 and TGF beta 1 down-regulated IL-6 transcriptionally; (4) time kinetics and levels of IL-10 were lower than those of IL-6 and IL-1 beta. Thus, contrary to a previous report, IL-6 production by SLE PBMC responds normally to regulatory signals, and the IL-6 overexpression in SLE may be due, at least in part, to the kinetics and availability of regulatory cytokines.