The peroxisome proliferator-activated receptors (PPAR) are members of the nuclear receptor supergene family and are considered as key sensors of both lipid and glucose homeostasis. The role of the PPAR␥ isoform in glucose metabolism is illustrated by the fact that antidiabetic thiazolidinediones have been shown to be bona fide PPAR␥ ligands. Here we report the crystal structure of apo-PPAR␥ ligand binding domain (LBD) determined to 2.9-Å resolution. Although the structure of apo-PPAR␥-LBD retains the overall fold described previously for other nuclear receptor LBDs, three distinct structural differences are evident. 1) The core AF-2 activation domain of apo-PPAR␥ LBD is folded back toward the predicted ligand binding pocket similar to that observed in the holo-forms of other nuclear receptors. 2) The proposed ligand binding pocket of apo-PPAR␥-LBD is larger and more accessible to the surface in contrast to other LBDs. 3) The region of the LBD called the -loop is extended in PPAR␥ and contains additional structural elements. Taken together, the apo-PPAR␥-LBD structure is in several aspects different from previously described LBDs. Given the central role of PPAR␥ as a mediator in glucose regulation, the structure should be an important tool in the development of improved anti-diabetic agents.
The ability of products from the adenovirus early region 1A to stimulate viral and cellular gene expression has been studied, using a transient expression assay in HeLa cells. We show that the E1A 13S mRNA encodes a diffusible product which is capable of stimulating transcription of adenovirus genes as well as the rabbit beta‐globin gene. The E1A 12S mRNA has no detectable stimulatory effect on either cellular or viral genes. Although being able to stimulate both types of genes, we find that the E1A regulatory protein enhances viral gene expression approximately 10 times more than beta‐globin gene expression. We also find that when connected to the cis‐acting SV40 enhancer element, the beta‐globin gene cannot be further stimulated by the trans‐acting E1A product. Finally, we find that transfection of either adenovirus or the beta‐globin gene into 293 cells, which constitutively expresses the E1A gene products, leads to an enhanced expression which is 10‐ to 20‐fold higher than obtained by co‐transfection of HeLa cells. The 293 cells thus provide a simple assay to demonstrate E1A‐mediated transcriptional regulation.
Field experiments were performed in artificial ponds to evaluate how the density of predatory diving beetles (Dytiscidae) would affect the population levels of mosquito larvae (Culicidae). Mosquitoes colonizing the ponds were predominantly species of the genus Culex. In 2000, most of the dytiscids colonizing the ponds were small (Hydroporus spp.), and these predators had no impact on the size of larval mosquito populations, not even in ponds with added dytiscids. In 2001, larger beetles (Ilybius, Rhantus, and Agabus spp.) were more common, and there were significantly fewer mosquito larvae in ponds with the highest numbers of dytiscids. There was a negative correlation between numbers of diving beetles in the ponds and the mean body length of mosquito larvae. In neither year could dytiscid densities be maintained above a certain level owing to emigration. In laboratory tests, there were marked differences between three common dytiscid species in regard to preferences for Daphnia and Culex species as prey: Colymbetes paykulli Erichson chose mosquito larvae more often, whereas both Ilybius ater (De Geer) and I. fuliginosus (Fabricius) preferred Daphnia spp. All of the tested dytiscids consumed large numbers of prey. Since some dytiscid species can efficiently decrease populations of mosquito larvae, they are probably important in the natural control of these dipterans.
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