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  • About
  • The Global ETD Search service is a free service for researchers to find electronic theses and dissertations. This service is provided by the Networked Digital Library of Theses and Dissertations.
    Our metadata is collected from universities around the world. If you manage a university/consortium/country archive and want to be added, details can be found on the NDLTD website.
1

Substrate specificity of factor inhibiting HIF-1 (FIH-1).

Linke, Sarah January 2008 (has links)
To detect and respond to the detrimental situation of hypoxia, metazoan cells employ O₂- sensing prolyl and asparaginyl hydroxylases which directly utilise O₂ to hydroxylate and regulate the Hypoxia Inducible transcription Factor-α (HIF-α). This thesis focuses upon the asparaginyl hydroxylase, ‘Factor Inhibiting HIF-1 (FIH-1), which represses HIF-α in normoxia by asparaginyl hydroxylation of its C-terminal trans-Activation Domain (CAD). During hypoxia FIH-1 is inhibited, allowing non-hydroxylated HIF-α to drive expression of over 70 target genes, leading to tissue and cellular changes that increase O₂ supply and reduce its consumption. This response is central to normal physiology and to the pathophysiology of diseases, including stroke and cancer. The pivotal role of FIH-1 in regulating these processes invites its characterisation, as a key cellular O₂-sensor and therapeutic target. This thesis contributes important information by elucidating a novel FIH-1 substrate and by defining numerous FIH-1 substrate recognition determinants. The first aim was to investigate the cell-fate regulator Notch1 as a potential FIH-1 substrate, due to myriad reports of Notch/hypoxic crosstalk and the discovery by collaborators that FIH- 1 represses Notch1 activity. Mutagenesis, hydroxylation assays, affinity-purification and mass spectrometry techniques enabled definition of two asparaginyl hydroxylations of mouse Notch 1 ankyrin repeat domain (N1945 and N2012), performed by FIH-1 in vitro. These residues were likewise detected to be hydroxylated in mNotch1 expressed in mammalian cells. FIH-1 kinetic assays comparing mNotch1 ankyrin domain with the unstructured hHIF- 1α CAD uncovered major distinctions between substrates; mNotch1 facilitated a 7-fold lower rate of cosubstrate turnover by FIH-1, but affinity was robust (>10-fold higher). Interrogation of the structure/affinity correlate implies FIH-1 binds unstable ankyrins preferentially. Functionally, a non-catalytic mechanism of Notch1 repression by FIH-1 is supported. The second aim derived from literature analyses implicating threonine and RLL motifs in HIF-α as critical hydroxylation determinants. T796 (hHIF-1α) contacts FIH-1 and is a likely phospho-acceptor, thus a mimetic T796D mutant was generated and its hydroxylation kinetics compared with wildtype hHIF-1α CAD. In vitro, the mutant exhibited a 6-fold greater apparent Km, explaining its constitutive activity in cell-based reporter assays, whereas wildtype hHIF-1α CAD is hydroxylated and thus repressed in normoxia by FIH-1. This indicates that phosphorylation reduces hydroxylation by FIH-1 in vitro and in vivo. The RLL motif does not contact FIH-1 in vitro however RLL-AAA mutant HIF-α proteins are constitutively active in normoxia, suggesting resilience to hydroxylation within cells. To reconcile these data I predicted that a cellular Factor X functionalises the RLL motif as an FIH-1 binding site. Reporter assays, in vitro kinetic assays and interaction assays +/- lysate confirmed this hypothesis and additionally showed the motif to increase HIF-α protein turnover 8-fold. Numerous mechanisms for Factor X including nuclear export, posttranslational modifications of FIH-1 or HIF-α, and involvement of small molecules, were experimentally examined, but deemed unlikely. Rather, the data imply Factor X to be a proteinaceous facilitator of a HIF-α/FIH-1 complex, thus proteomic capture screens are underway. This research provides novel insight into FIH-1; its role in Notch/hypoxic crosstalk, its substrate recognition requirements, and its potential functions in cellular O₂-sensing. / http://proxy.library.adelaide.edu.au/login?url= http://library.adelaide.edu.au/cgi-bin/Pwebrecon.cgi?BBID=1326855 / Thesis (Ph.D.) -- University of Adelaide, School of Molecular and Biomedical Science, 2008

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