Active water in protein-protein communication within the membrane: the case of SRII-HtrII signal relay.

We detect internal water molecules in a membrane-embedded receptor-transducer complex and demonstrate water structure changes during formation of the signaling state. Time-resolved FTIR spectroscopy reveals stimulus-induced repositioning of one or more structurally active water molecules to a significantly more hydrophobic environment in the signaling state of the sensory rhodopsin II (SRII)-transducer (HtrII) complex. These waters, distinct from bound water molecules within the SRII receptor, appear to be in the middle of the transmembrane interface region near the Tyr199(SRII)-Asn74(HtrII) hydrogen bond. We conclude that water potentially plays an important role in the SRII --> HtrII signal transfer mechanism in the membrane's hydrophobic core.

Active Learning in Nursing Education

ALINE is a pedagogical model developed to aid nursing faculty transition from passive to active learning. Based on constructionist theory, ALINE serves as a tool for organizing curriculum for online and classroom based interaction and permits positioning the student as the active player and the instructor, the facilitator to nursing competency.

In vitro incorporation of molybdate into demolybdoproteins in Escherichia coli.

When Escherichia coli was grown in the presence of tungstate, inactive forms of two molybdoenzymes, nitrate reductase and formate dehydrogenase, accumulated and were converted to their active forms upon incubation of cell suspensions with molybdate and chloramphenicol. The conversion to the active enzymes did not occur in cell extracts. When incubated with [(99)Mo]molybdate and chloramphenicol, the tungstate-grown cells incorporated (99)Mo into protein components which were released from membranes by procedures used to release nitrate reductase and formate dehydrogenase and which migrated with these activities on polyacrylamide gels. Although neither activity was formed during incubation of the crude extract with molybdate, (99)Mo was incorporated into protein components which were released from the membrane fraction under the same conditions and were similar to the active enzymes in their electrophoretic properties. The in vitro incorporation of (99)Mo occurred specifically into these components and was equal to or greater than the amount incorporated in vivo under the same conditions. Molybdenum in preformed, active nitrate reductase and formate dehydrogenase did not exchange with [(99)Mo]molybdate, demonstrating that the observed incorporation depended on the demolybdo forms of the enzymes. We conclude that molybdate may be incorporated into the demolybdo forms both in vivo and in vitro; some unknown additional factor or step, required for active enzyme formation, occurs in vivo but not in vitro under the conditions employed.

Molecular regulatory mechanisms and embryonic tissue specification in sea urchin development

To understand how a eukaryote achieves differential transcription of genes in precise spatial patterns, the molecular details of tissue specific expression of the Strongylocentrotus purpuratus Spec2a gene were investigated by functional studies of the cis-regulatory components in the upstream enhancer. Regional activation of Spec2a in the aboral ectoderm is conferred by a combination of activators and repressors. The positive regulators include previously identified SpOtx and a trans-regulatory factor binding at the CCAAT site in the Spec2a enhancer. The nuclear protein binding to the CCAAT box was determined to be the heterotrimeric CCAAT binding factor (SpCBF). SpCBF also mediates general activation in the ectoderm. The negative regulators consist of an oral ectoderm repressor (OER), an endoderm repressor (ENR), and an S. Purpuratus goosecoid homologue (SpGsc). OER functions to prevent expression in the oral ectoderm, while ENR is required to repress endoderm expression. SpGsc antagonizes the SpOtx function by competing for binding at SpOtx target genes in oral ectoderm, where it functions as an active repressor. Thus, SpOtx and SpGsc perform collectively to establish and maintain the oral-aboral axis. Finally, purification of ENR and OER proteins from sea urchin blastula stage nuclear extracts was performed using site-specific DNA-affmity chromatography. ^

Structural studies of cytochrome P4501A1: Identification of substrate and cumene hydroperoxide binding regions in the active site of P4501A1 and characterization of the P4501A1 interaction with cytochrome P450 reductase

Cytochromes P450 are a superfamily of heme-thiolate proteins that function in a concert with another protein, cytochrome P450 reductase, as terminal oxidases of an enzymatic system catalyzing the metabolism of a variety of foreign compounds and endogenous substrates. In order to better understand P450s catalytic mechanism and substrate specificity, information about the structure of the active site is necessary. Given the lack of a crystal structure of mammalian P450, other methods have been used to elucidate the substrate recognition and binding site structure in the active center. In this project I utilized the photoaffinity labeling technique and site-directed mutagenesis approach to gain further structural insight into the active site of mammalian cytochrome P4501AI and examine the role of surface residues in the interaction of P4501A1 with the reductase. ^ Four crosslinked peptides were identified by photoaffinity labeling using diazido benzphetamine as a substrate analog. Alignment of the primary structure of cytochrome P4501A1 with that of bacterial cytochrome P450102 (the crystal structure of which is known) revealed that two of the isolated crosslinked peptides can be placed in the vicinity of heme (in the L helix region and β10-β11 sheet region of cytochrome P450102) and could be involved in substrate binding. The other two peptides were located on the surface of the protein with the label bound specifically to Lys residues that were proposed to be involved in reductase-P450 interaction. ^ Alternatively, it has been shown that some of the organic hydroperoxides can support P450 catalyzed reactions in the absence of NADPH, O2 and reductase. By means of photoaffinity labeling the cumene hydroperoxide binding region was identified. Using azidocumene as the photoaffinity label, the tripeptide T501-L502-K503 was shown to be the site where azidocumene covalently binds to P4501A1. The sequence alignment of cytochrome P4501A1 with cytochrome P450102 predicts that this region might correspond to β-sheet structure localized on the distal side of the heme ring near the I helix and the oxygen binding pocket. The role of Thr501 in the cumene hydroperoxide binding was confirmed by mutations of this residue and kinetic analysis of the effects of the mutations. ^ In addition, the role of two lysine residues, Lys271 and Lys279, in the interaction with reductase was examined by means of site-directed mutagenesis. The lysine residues were substituted with isoleucine and enzymatic activity of the wild type and the mutants were compared in reductase- and cumene hydroperoxide-supported systems. The lysine 279 residue has been shown to play a critical role in the P4501A1-reductase interaction. ^

SFRP4 regulation of Wnt7a signaling and cellular proliferation in the endometrium

In the endometrium, hormonal effects on epithelial cells are often elicited through stromal hormone receptors via unknown paracrine mechanisms. Several lines of evidence support the hypothesis that Wnts participate in stromal-epithelial cell communication and thus mediate hormone action. Characterization of specific Wnt signaling components in the endometrium was performed using cellular localization studies and evaluating hormone effects in a rat model. Wnt7a was expressed in the luminal epithelium, whereas the extracellular Wnt modulator, SFRP4, was localized to the endometrial stroma. SFRP4 expression is significantly decreased in endometrial carcinoma and aberrant Wnt7a signaling has been shown to cause uterine defects and contribute to the onset of disease. The specific Fzds and SFRPs that bind Wnt7a and the particular signal transduction pathway each Wnt7a-Fzd pair activates have not been identified. Additionally, the function of Wnt7a and SFRP4 in the endometrium has not been addressed. A survey of all Wnt signaling proteins expressed in the endometrium was conducted and Fzd5 and Fzd10 were identified as two receptors capable of transducing the Wnt7a signal. Biologically active recombinant Wnt7a and SFRP4 proteins were purified for quantitative biochemical studies. In Ishikawa cells, Wnt7a binding to Fzd5 activated β-catenin/canonical Wnt signaling and increased cellular proliferation. Wnt7a signaling mediated by Fzd10 induced a non-canonical/JNK-responsive pathway. SFRP4 suppressed Wnt7a action in both an autocrine and paracrine manner. Treatment with SFRP4 protein and overexpression of SFRP4 inhibited endometrial cancer cell growth and induced apoptosis in vitro. A split-eGFP complementation assay was developed to visually detect Wnt7a-Fzd interactions and subsequent pathway activation in cells. By employing a unique ELISA-based protein-protein binding technique, it was demonstrated that Wnt7a binds to SFRP4 and Fzd5 with equal nanomolar affinity. The development of these novel biological tools could lead to a better understanding of Wnt-protein interactions and the identification of new modulators of Wnt signaling. This study supports a mechanism by which the nature of the Wnt7a signal in the endometrium is dependent upon the Fzd repertoire of the cell and can be regulated by SFRP4. The potential tumor suppressor function of SFRP4 suggests it may serve as a therapeutic target for endometrial carcinoma. ^