Expression of the ligand-binding nicotinic acetylcholine receptor subunit D alpha 2 in the Drosophila central nervous system.

The D alpha 2 gene encodes a ligand-binding subunit of nicotinic acetylcholine receptors (nAChRs) from Drosophila melanogaster. We have studied the distribution of D alpha 2 transcripts and protein by in situ hybridization and immunohistochemistry, respectively, as well as the regulation of D alpha 2 gene expression in vivo using D alpha 2 promoter fragments fused to the Escherichia coli lacZ gene. Transcripts and protein from the D alpha 2 gene were detected exclusively in the central nervous system. Both in late embryos and adults D alpha 2-like immunoreactivity is widely but not uniformly distributed in the synaptic neuropil, suggesting that the D alpha 2 protein is a subunit of a synaptic nicotinic receptor. Its distribution resembles that of ALS and ARD proteins, two other nAChR subunits of the fly. Five different D alpha 2-lacZ fusion gene constructs were introduced into the Drosophila genome by P-element-mediated gene transfer to identity functional elements of the D alpha 2 promoter. All constructs produce a basic lacZ expression pattern that is compatible with the distribution of D alpha 2 transcripts and protein. A 880 bp upstream fragment harbors the cis elements for the expression of a weak but specific basic D alpha 2 pattern. The next 350 bp further upstream significantly enhance beta-galactosidase expression without influencing the pattern of expression. Between 1.7 and 7.3 kb upstream of the transcription start site one or more elements that are required for D alpha 2 expression in optic lobe tangential cells are located.

Cellular interactions and exaggerated arachidonic acid metabolism in rabbit renal injury.

Cell cultures from explants of the rabbit hydronephrotic kidney (HNK) cortex consisted of fibroblasts and an esterase-positive cell that phagocytizes zymosan. Cortical cell cultures from the contralateral kidney (CLK) contained only the fibroblast. The HNK cultures exhibited an endotoxin-induced prostaglandin (PG) E2 (three - fourfold) release indicative of the presence of macrophages, whereas no response was observed in the CLK cultures. At bradykinin concentrations as low as 10(-9)M there was a 20-fold stimulation of PGE2 from the HNK cultures and a sevenfold stimulation in the CLK cultures. The heterogeneous population of cells in the HNK cultures was separated using a mild trypsin treatment which permits passage of only the fibroblasts. The HNK-passaged cultures contained no phagocytic cells and did not release PGE2 in response to endotoxin. The passaged HNK cultures released less PGE2 in response to bradykinin as compared to primary cultures and had a decreased cyclooxygenase activity as determined by exogenous arachidonic acid conversion to PGE2. Conditioned media from adherent rabbit peripheral blood mononuclear cells stimulated basal PGE2 production (two - threefold) from both the HNK and CLK cultures. These findings demonstrated the similarity of the PGE2 production by cultured HNK cortical cells as compared to the ex vivo perfused HNK.

Presence of inflammatory cells associated with exaggerated arachidonic acid metabolism in renal injury.

Unilateral ureter obstruction induces an exaggerated prostaglandin release from isolated perfused rabbit kidneys in response to vasoactive peptides. Perfused hydronephrotic kidneys also exhibit the release of thromboxane A2 which is not detected with normal or contralateral kidneys. Reversal of the ureteral obstruction causes a decreased production of PGs and TxA2 in response to bradykinin. Morphological examination of the HNK demonstrates an enlarged interstitial space containing a fibroblast-like cell and the presence of mononuclear cells. Administration of endotoxin to the perfused HNK elicits the release of PGE2 and TxB2 consistent with the ability of endotoxin to stimulate arachidonic acid metabolism in cultured macrophage. Rabbit CLK and the cat HNK, which are deficient in macrophages, exhibit minimal PGE2 and no detectable TxA2 release after endotoxin stimulation. Cells cultured from the rabbit HNK cortex contain fibroblast-like cells and phagocytic cells which respond to BK with a profound PG production. Conditioned media from mononuclear cells have been shown by others to stimulate PGE2 production from fibroblasts. Other models of renal disease (renal venous constriction and glycerol-induced tubular necrosis) exhibit exaggerated PG and TxA2 release and facilitated cortical microsomal AA metabolism. These data suggest that proliferation of fibroblast-like cells and the presence of mononuclear cells may be involved in this exaggerated PG and TxA2 production underlying renal injury.

Metabolic and cellular alterations underlying the exaggerated renal prostaglandin and thromboxane synthesis in ureter obstruction in rabbits. Inflammatory response involving fibroblasts and mononuclear cells.

Unilateral ureter obstruction in rabbits produced profound changes in endogenous and exogenous renal arachidonic acid metabolism. Isolated perfused hydronephrotic kidneys (removed after 3 or 10 d of ureter obstruction) responded to bradykinin stimulation with a markedly enhanced release of prostaglandin E2 and thromboxane A2. Reversal (3 or 10 d) of the ureter obstruction resulted in a reduction in the vasoactive peptide-induced release of prostaglandin E2 and thromboxane A2 from the perfused hydronephrotic kidney. However, postobstruction reversal of prostaglandin production by the agonist-stimulated perfused kidney was not reflected in the cortical microsomal cyclooxygenase activity, which is greatly enhanced during ureter obstruction and does not decrease after removal of the obstruction. Histological analysis of the renal cortex in rabbits with ureteral obstruction revealed a proliferation of fibroblast-like cells and the presence of mononuclear cells; removal of the obstruction did not result in a disappearance of cortical fibroblasts but did result in a decrease of monocytes. The critical involvement of mononuclear cells in the exaggerated arachidonate metabolism that occurs during hydronephrosis was exhibited by the demonstration that: (a) only the perfused hydronephrotic rabbit kidney responded to administration of endotoxin with a sustained release of prostaglandin E2 and thromboxane A2; (b) the contralateral rabbit kidney, which is devoid of mononuclear cells, did not respond to endotoxin; and (c) the hydronephrotic cat kidney, which exhibits a fibroblast proliferation with a low number of mononuclear cells, did not respond to endotoxin. Thus, proliferation of fibroblast-like cells and the presence of mononuclear cells appear to be involved in the exaggerated prostaglandin and thromboxane production underlying hydronephrosis. The increase in microsomal cyclooxygenase activity is apparently most closely correlated with the increased fibroblastic activation and cellularity, whereas mononuclear cells (possibly via monokines) seem to be critical for the markedly enhanced prostaglandin and thromboxane release induced by endotoxin and bradykinin.