Glutamatergic Activation of Neuronostatin Neurons in the Periventricular Nucleus of the Hypothalamus

Extensive development of inhaled and oral glucocorticoids has resulted in highly potent molecules that have been optimized to target activity to the lung and minimize systemic exposure. These have proved highly effective for most asthmatic subjects, but despite these developments, there are a number of subjects with asthma who fail to respond to even high doses of inhaled or even oral glucocorticoids. Advances in delineating the fundamental mechanisms of glucocorticoid pharmacology, especially the concepts of transactivation and transrepression and cofactor recruitment, have resulted in better understanding of the molecular mechanisms whereby glucocorticoids suppress inflammation. The existence of multiple mechanisms underlying glucocorticoid insensitivity raises the possibility that this might indeed reflect different diseases with a common phenotype, and studies examining the efficacy of potential new agents should be targeted toward subgroups of patients with severe corticosteroid-resistant asthma who clearly require effective new drugs and other approaches to improved asthma control.

The p38 MAPK signalling pathway plays an important role in inflammation and other physiological processes. Specific inhibitors of p38 alpha and beta MAPK block production of the major inflammatory cytokines (i.e. tumour necrosis factor-alpha and interleukin-1) and other proteins (e.g. cyclooxygenase-2), and are anti-inflammatory in animal models of disease. A major function of the pathway is post-transcriptional control of inflammatory gene expression. Many of the mRNAs are unstable (or untranslatable) because of AU-rich elements in the 3'untranslated region. Signalling in the p38 pathway counteracts these and stabilizes the mRNAs by preventing their otherwise rapid de-adenylation.

Vesicular glutamate transporter 1 (VGluT1) is one of the best markers for glutamatergic neurons, because it accumulates transmitter glutamate into synaptic vesicles. Differentiation-associated Na(+)-dependent inorganic phosphate cotransporter (DNPI) shows 82% amino acid identity to VGluT1, and is another candidate for vesicular glutamate transporters. Here, we report the immunocytochemical localization of DNPI and compare it with that of VGluT1 in the adult rat brain. Both DNPI and VGluT1 immunoreactivities were found mostly in neuropil, presumably in axon terminals, throughout the brain. In the telencephalic regions, intense DNPI immunoreactivity was observed in the glomeruli of the olfactory bulb, layer IV of the neocortex, granular layer of the dentate gyrus, presubiculum, and postsubiculum. In contrast, VGluT1 immunoreactivity was intense in the olfactory tubercle, layers I-III of the neocortex, piriform cortex, entorhinal cortex, hippocampus, dentate gyrus, and subiculum. In the thalamic nuclei, DNPI-immunoreactive terminal-like profiles were much larger than VGluT1-immunoreactive ones, suggesting that DNPI immunoreactivity was subcortical in origin. DNPI immunoreactivity was much more intense than VGluT1 immunoreactivity in many brainstem and spinal cord regions, except the pontine nuclei, interpeduncular nucleus, cochlear nuclei, and external cuneate nucleus. In the molecular layer of the cerebellar cortex, climbing-like fibers showed intense DNPI immunoreactivity, whereas neuropil contained dense VGluT1-immnoreactive deposits. Both DNPI and VGluT1 immunoreactivities were observed as mossy fiber terminal-like profiles in the cerebellar granular layer. DNPI and VGluT1 immunoreactivities appeared associated with synaptic vesicles in the axon terminals forming asymmetric synapses in several regions examined electron microscopically. The present results indicate that DNPI and VGluT1 are used by different neural components in most, if not all, brain regions, suggesting the complementary functions of DNPI and VGluT1. Copyright 2002 Wiley-Liss, Inc.