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Reversible Photoregulation of Binding of the Serine Protease α-Chymotrypsin to a Functional Surface

This thesis presents the first example of reversible photoregulation of the binding of a protease, α-chymotrypsin, to a surface. A modular approach is used involving the azobenzene photoswitch group, a surface linker and an enzyme binding group. This approach is designed to be easily extended to the photoregulation of binding of other proteases to surfaces by use of enzyme binding groups selective to these proteases. Chapter one gives a brief outline of some of the important areas involved in to this work, including molecular switches, proteases and surface modification. Chapter two describes the synthesis of azobenzene-containing boronate esters designed as photoswitch inhibitors of α-chymotrypsin. Boronate esters were prepared containing the aminophenylboronate group or the peptidomimetic borophenylalanine group for enzyme binding and a range of substituents designed for enzyme affinity and/or surface attachment. Syntheses primarily involved peptide coupling reactions and azobenzene formation by condensation of nitrosobenzenes and anilines. Coupling reactions were successfully carried out using EDCI or isobutyl chlorofomate in several cases where other reagents gave unacceptable decomposition. Chapter three describes the syntheses and HPLC stability studies of derivatives of a noncovalent α-chymotrypsin inhibitor. Several dipeptide-based compounds containing either an amide group for surface attachment or an azobenzene group for photoswitching were prepared, primarily using peptide coupling reactions. Each compound was incubated with α-chymotrypsin to assess its stability, and all were found by HPLC monitoring to be stable to α-chymotrypsin catalysed hydrolysis. Chapter four describes syntheses of azobenzene-containing trifluoromethylketones and α-ketoesters designed as photoswitch inhibitors of α-chymotrypsin. Trifluoromethylketones/α-ketoesters containing amine groups for surface attachment were prepared, primarily using peptide coupling reactions, but could not be isolated due to the incompatibility of the electrophilic ketone and primary amine groups. Trifluoromethylketones/α-ketoesters containing terminal alkynes for surface attachment were prepared either by the attachment of an alkyne substituent group to a symmetrical azobenzene core or by Pd-catalysed reaction of a protected alkyne with an azobenzene having a halide substitutent. Chapter five describes syntheses of sulfur-containing surface linkers for use in surface attachment of the photoswitch inhibitors described in chapters 2-4. A range of compounds containing disulfide or protected thiol groups for surface attachment and azide or carboxylic acid groups for inhibitor attachment were prepared. Syntheses primarily involved coupling of functionalised alcohols/amides to carboxylic acid-containing disulfides/thioacetates. Selected linkers were attached to azobenzenes by amide coupling or azide-alkyne cycloaddition for surface attachment, photoswitching and/or enzyme assay. Azide-alkyne cycloaddition yields were initially poor, but were improved by use of stoichiometric amounts of copper catalyst. Chapter six describes UV/vis photoisomerisation studies and enzyme assays carried out to assess enzyme photoswitching of the compounds described in chapters 2-5. The trifluoromethylketones and α-ketoesters described in chapter 4 gave the best results, with moderate inhibition of α-chymotrypsin (µM affinity constants) and up to 5.3 fold changes in inhibition on UV/vis irradiation. Many of the boronate esters described in chapter 2 were found to inhibit α-chymotrypsin, but were somewhat unstable to irradiation. The dipeptide-based compounds described in chapter 3 were inactive against α-chymotrypsin. Good photoisomerisation was obtained for an azobenzene containing a symmetrical disulfide surface linker and poor photoisomerisation was obtained for an azobenzene containing a lipoic acid surface linker. Chapter seven describes surface attachment of selected photoswitch inhibitors and studies of photoregulated enzyme binding to the resultant functional surfaces. Self assembled monolayers (SAMs) of disulfides were formed on gold surfaces and characterised by electrochemistry and contact angle measurements. Binding of α-chymotrypsin to SAMs containing a photoswitch inhibitor was detected by quartz crystal microbalance (QCM), but was found to be largely irreversible. An alkyne-containing photoswitch inhibitor was attached to a surface plasmon resonance (SPR) chip in a two step procedure involving generation of an azide modified surface followed by azide-alkyne cycloaddition. Binding of α-chymotrypsin to the resultant modified surface was detected by SPR and successfully regulated by UV/vis irradiation. Chapter eight provides conclusions for the work described in this thesis and suggests future directions. Chapter nine gives experimental details for the work described in this thesis.

Identiferoai:union.ndltd.org:canterbury.ac.nz/oai:ir.canterbury.ac.nz:10092/2508
Date January 2007
CreatorsPearson, David Scott
PublisherUniversity of Canterbury. Chemistry
Source SetsUniversity of Canterbury
LanguageEnglish
Detected LanguageEnglish
TypeElectronic thesis or dissertation, Text
RightsCopyright David Scott Pearson, http://library.canterbury.ac.nz/thesis/etheses_copyright.shtml
RelationNZCU

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