The spatial patterns of activity elicited in the rat olfactory bulb under different odor conditions have been analysed using the 2-deoxyglucose (2DG) technique. Rats were injected with 14C-2DG, exposed to controlled environments of amyl acetate, camphor, cage air, dimethyl disulfide, and pure air and autoradiographs prepared by the method of Sokoloff. Amyl acetate was associated with regions of glomerular layer densities in the anterolateral and mid- to posteromedial parts of the bulbar circumference, as previously reported. The extents of the densities increased with increasing concentration. Camphor odor was associated with regions of increased density in the anterodorsal and mid- to posteromedial parts of the bulb. Exposure to cage air produced scattered densities in the posteromedial and posterolateral bulb. Exposure to dimethyl disulfide gave variable results. Pure air was associated with a minimal number of small dense foci. The results with amyl acetate, camphor and cage air suggest that patterns for different odors are distinguishably different but overlapping. The regions of activity are greatest in extent and density with the highest odor concentrations. These define the regions within which more restricted and isolated foci appear at lower concentrations. The results thus provide evidence for the specific role of spatial factors in the neural processing of odor quality and odor concentration.
Recent data have demonstrated that vascular endothelial growth factor (VEGF) is expressed by subsets of neurons, coincident with angiogenesis within the developing cerebral cortex. Here we investigate the characteristics of VEGF expression by neurons and test the hypothesis that VEGF may serve both paracrine and autocrine functions in the developing central nervous system. To begin to address these questions, we assayed expression of VEGF and one of its potential receptors, Flk-1 (VEGFR-2), in the embryonic mouse forebrain and embryonic cortical neurons grown in vitro. Both VEGF and Flk-1 are present in subsets of post-mitotic neurons in vivo and in vitro. Moreover, VEGF levels are up-regulated in neuronal cultures subjected to hypoxia, consistent with our previous results in vivo. While the abundance of Flk-1 is unaffected by hypoxia, the receptor exhibits a higher level of tyrosine phosphorylation, as do downstream signaling kinases, including extracellular signal-regulated protein kinase, p90RSK and STAT3a, demonstrating activation of the VEGF pathway. These same signaling components also exhibited higher tyrosine phosphorylation levels in response to exogenous addition of rVEGFA 165 . This activation was diminished in the presence of specific inhibitors of Flk-1 function and agents that sequester VEGF, resulting in a dose-dependent increase in apoptosis in these neuronal cultures. Further, inhibition of MEK resulted in increased apoptosis, while inhibition of phosphatidylinositol 3-kinase had no appreciable affect. In addition to the novel function for VEGF that we describe in neuronal survival, neuronal VEGF also affected the organization and differentiation of brain endothelial cells in a three-dimensional culture paradigm, consistent with its more traditional role as a vascular agent. Thus, our in vitro data support a role for neuronal VEGF in both paracrine and autocrine signaling in the maintenance of neurons and endothelia in the central nervous system.
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