Effects of Amino Acid Insertion on the Substrate and Regiospecificity of a Citrus paradisi Glucosyltransferase

Tolliver, Benjamin M., Shivakumar, Devaiah P., McIntosh, Cecelia A.

03 April 2014

Glucosyltransferases, or GTs, are enzymes which perform glucosylation reactions. These glucosylation reactions involve attaching a UDP-activated glucose molecule to acceptor molecules specific to the enzyme. The products of these reactions are observed to have a myriad of effects on metabolic processes, including stabilization of structures, solubility modification, and regulation of compound bioavailability. The enzyme which our lab focuses its research on is a flavonol-specific 3-O-GT found in Citrus paradisi, or grapefruit. This enzyme is part of the class of enzymes known as flavonoid GTs, which are responsible for, among other things, the formation of compounds which can affect the taste of citrus. Our lab focuses its research on performing site-directed mutagenesis on Citrus paradisi 3-O-GT in an attempt to modify its substrate specificity and regiospecificity. In this poster, we report our findings thus far concerning the addition of specific residues to the 3-O-GT's amino acid sequence based on an alignment with the sequence of a putative flavonoid GT found in Citrus sinensis.

effects

amino acid insertion

substrate

regiospecificity

citrus paradisi

glucosyltransferase

GTs

enzymes

glucosylation reactions

UDP-activated glucose molecule

metabolic processes

Biological Sciences

School of Graduate Studies

Biochemistry

Molecular Biology

Plant Biology

Effects of Amino Acid Sequence Insertion on the Substrate Preference of a Citrus Paradisi Glucosyltransferase

Tolliver, Benjamin M., Shivakumar, Devaiah P., McIntosh, Cecelia A.

09 August 2013

Glucosyltransferases (GTs) are enzymes which perform glucosylation reactions, which involve attaching a UDP-activated glucose molecule to acceptor molecules specifi c to the enzyme. The enzyme which our lab focuses its research on is a fl avonol-specifi c 3-OGT found in Citrus paradisi, or grapefruit (Cp3GT). This enzyme is part of the class of enzymes known as fl avonoid GTs, which are responsible for, among other things, the formation of compounds which can affect the taste of citrus. Our lab focuses its research on performing site-directed mutagenesis on Cp3GT in an attempt to discover the residues important for substrate and regiospecifi city. In this study, we are testing the basis of substrate septicity of Cp3GT. We hypothesize that incorporation of fi ve amino acids specifi c to Citrus sinensis GT (CsGT) into Cp3GT at 308th position may facilitate mCp3GT to use anthocyanidins as one of the substrates. We report our fi ndings thus far concerning the addition of specifi c residues to the Cp3GT’s amino acid sequence based on an alignment with the sequence of a putative fl avonoid GT found in Citrus sinensis.

effects

amino acid insertion

substrate

regiospecificity

citrus paradisi

glucosyltransferase

GTs

enzymes

glucosylation reactions

UDP-activated glucose molecule

metabolic processes

amino acid sequence insertion

Biological Sciences

School of Graduate Studies

Biochemistry

Molecular Biology

Plant Biology