Examination of 2-Oxoglutarate Dependant Dioxygenases Leading to the Production of Flavonols in <i>Arabidopsis thaliana</i>

Owens, Daniel Kenneth

21 October 2005

The flavonols are a varied and abundant sub-class of flavonoids that are associated with a number of essential physiological functions in plants and pharmacological activities in animals. The 2-oxoglutarate-dependant dioxygenases(2-ODDs), flavonol synthase (FLS) and flavanone 3-hydroxylase (F3H), are essential for flavonol synthesis. The primary goal of this study has been to gain a deeper understanding of the biochemistry of these enzymes in Arabidopsis. To accomplish this goal, an activity assay employing recombinant protein expression and HPLC as a detection system was developed for F3H and adapted for use with FLS. The assay was employed to establish the biochemical parameters of F3H from Arabidopsis, and to further characterize the F3H mutant allele, <i>tt6</i>(87). Enzymatic activity was demonstrated for F3H enzymes from <i>Ipomoea alba</i> (moonflower), <i>Ipomoea purpurea</i> (common morning glory), <i>Citrus sinensis</i> (sweet orange), and <i>Malus X domestica</i> (newton apple), each of which had previously been identified solely based on sequence homology. Arabidopsis contains six genes with high similarity to <i>FLS</i> from other plant species; however, all other central flavonoid pathway enzymes in Arabidopsis are encoded by single genes. The hypothesis that differential expression of FLS isozymes with varying substrate specificities is responsible for observed tissue-specific differences in flavonol accumulation was tested. Sequence analysis revealed that <i>AtFLS2, 4</i> and <i>6</i> contain premature stop codons that eliminate residues essential for enzyme activity. AtFLS1 was found to have a strong preference for dihydrokaempferol as a substrate. However, no enzyme activity was observed for AtFLS3 or AtFLS5 with a number of different substrates under a variety of reaction conditions. To identify structural elements that may contribute to the observed differences in biochemical activity, homology models for each of the isoforms were generated utilizing Arabidopsis anthocyanin synthase (ANS) as a template. A domain at the N-terminus of AtFLS1 that is missing in the other isozymes was insufficient to convey activity to an AtFLS1/5 chimera. These findings suggest a single catalytically-active form of FLS exists in Arabidopsis. The possibility that the apparently expressed but non-catalytic proteins, AtFLS2, 3, and 5, serve noncatalytic roles in flavonol production were explored by yeast 2-hybrid analysis. / Ph. D.

2-oxoglutarate dependant dioxygenases

Michaelis-Menten kinetics

flavanone 3-hydroxylase

flavonoid biosynthesis

flavonol synthase

Using Site-Directed Mutagenesis to Determine Impact of Amino Acid Substitution on Substrate and Regiospecificity of Grapefruit Flavonol 3-O-Glucosyltransferase

Adepoju, Olusegun A., Shiva, Devaiah K., McIntosh, Cecelia A.

03 April 2014

Flavonoids are secondary metabolites that are important in plant defense, protection and human health. Most naturally-occurring flavonoids are found in glucosylated form. Glucosyltransferases (GTs) are enzymes that catalyze the transfer of glucose from a high energy sugar donor to an acceptor molecule. A flavonol-specific 3-O-GT enzyme has been identified and cloned from leaf tissues of grapefruit. The enzyme shows rigid substrate specificity and regiospecificity. F3-O-GTs from grape (Vitis vinifera) and grapefruit (Citrus paradisi) were modeled against F7-O-GTs from Crocus sativus and Scrutellaria biacalensis, and several non-conservative amino acid differences were identified that may impact regioselectivity. This research is designed to test the hypothesis that specific amino acid residues impart the regiospecificity of the grapefruit enzyme. Site-directed mutagenesis was performed on three potentially key amino acid residues within the grapefruit F3-O-GT that were identified through homology modeling. Analyses of the enzyme activity of the mutant F3-O-GT proteins revealed that the single point mutations of serine 20 to leucine (S20L) and proline 297 to phenylalanine (P297F) rendered the recombinant enzyme inactive with flavonol substrates. Mutation of glycine 392 to glutamate (G392E) was active at 80% relative to the wild type. The mutant enzyme also did not show broadened acceptor specificity as it also favored flavonols as the preferred acceptor substrate. The glucosylation products of the active mutant enzyme will be analyzed to determine if this resulted in a change in regiospecificity.

site-directed

mutational anaylsis

flavonol-3-O-glucosyltransferases

citrus paradisi

site-directed mutagenesis

amino acid substitution

substrate

regiospecificity

grapefruit flavonol

GTs

Biological Sciences

School of Graduate Studies

Biochemistry

Molecular Biology

Plant Biology

Mutagenesis of a Flavonol- 3-O-Glucosyltransferase and the Effect on Enzyme Function

Carter, Lisa, Shivakumar, Devaiah P., McIntosh, Cecelia A.

09 August 2013

Flavonoids are an important group of secondary metabolites found in plants and have a wide variety of properties. Some play a role in fl ower pigmentation, while others have antimicrobial properties. Glucosylation is an important modifi cation of fl avonoids and is mediated by glucosyltransferases. In this process, the enzyme transfers glucose from UDP-glucose to a specifi c position on the fl avonoid. Previous study from the lab characterized a glucosyltransferase from C. paradisi that is fl avonol specifi c. In this study an attempt has been made to study the structure and function of this fl avonol specifi c glucosyltransferase using site directed mutagenesis. The glutamine residue at position 87 of the Cp-3-O-GT enzyme was changed to isoleucine, the analogous residue in the 3-O-glucosyltransferase of Clitoria ternatea. Similarly, the histidine at position 154 was changed to tyrosine. We hypothesize that these mutations will change substrate specifi city. The glutamate at position 88 was changed to an aspartic acid. We hypothesize that this will change the regiospecifi city of the enzyme, as aspartic acid is the analogous residue found in some 7-O-glucosyltransferases. Finally, we introduced a double mutation with glutamine 87 becoming isoleucine and glutamate 88 becoming aspartic acid, with the hypothesis that both regiospecifi city and substrate specifi city will be changed.

mutagenesis

flavonol-3-O-glucosyltransferase

enzyme function

flavonoids

Biological Sciences

School of Graduate Studies

Biochemistry

Molecular Biology

Plant Biology

Crystallization of a Flavonol-Specific 3-O-Glucosyltrasnferase found in Citrus paradisi

Birchfield, Aaron, McIntosh, Cecelia A.

12 April 2017

Citrus and other fruits produce secondary metabolites that are synthesized, regulated, and modified in part by a class of enzymes called glycosyltransferases. This class of enzymes is of substantial interest to this lab due to their unique structural and functional properties. Glycosides of flavonoids produced by glycosyltransferases have emerged in recent years as a critical part of plant metabolism, thus impacting every aspect of their growth, cultivation, production, and utilization. One such glycosyltransferase, found in Duncan Grapefruits (Citrus paradisi), was previously identified, recombinantly expressed, and shown through biochemical characterization to exclusively glycosylate the flavonol class of flavonoids. The structural basis that accounts for a glycosyltransferase's selectivity has been determined by protein crystallization in other labs, yet no structural basis currently exists for the specificity exhibited by this flavonol-specific glycosyltransferase. Currently, the WT enzyme and two mutants were expressed in E. coli, where they underwent site-directed mutagenesis to insert thrombin cleavage tags for removal of protein purification vectors, with the goal of transforming into yeast for adequate protein production. Subsequent purification and crystallization screens will allow for formation and acquisition of glycosyltransferase crystals, whose x-ray diffraction patterns will be decoded, thus revealing the enzyme's complete structure. We hypothesize that obtaining a crystal structure for this enzyme will illuminate the structural basis of its specificity. Additionally, we hypothesize that a thrombin- cleavage gene vector inserted for removal of purification tags will have no impact on enzyme activity or specificity.

crystallization

citrus paradisi

flavanoids

Biological Sciences

School of Graduate Studies

Biochemistry

Molecular Biology

Plant Biology

Site-Directed Mutational Analysis of Flavonol 3-0-Glucosyltransferases from Citrus paradisi

Devaiah, Shivakumar P., McIntosh, Cecelia A.

04 April 2013

Glucosyltransferases (GTs) are the important group of enzymes which facilitates the incorporation of UDPactivated glucose to a corresponding acceptor molecule through glucosylation. Glucosylation is a common alteration reaction in plant metabolism and is regularly associated with the production of secondary metabolites. Glucosylation serves a number of roles within metabolism including: stabilizing structures, affecting solubility, transport, and regulating the bioavailability of the compounds for other metabolic processes. GTs involved in secondary metabolism share a conserved 44 amino acid residue motif (60–80% identity) known as the plant secondary product glucosyltransferase (PSPG) box, which has been demonstrated to include the UDP-sugar binding moiety. Among the secondary metabolites, flavonoid glycosides affect taste characteristics in citrus making the associated glucosyltransferases particularly interesting targets for biotechnology applications in these species. Custom design of enzymes requires understanding of structure/function of the protein. The present study focuses on creating mutant Flavonol- 3-O- Glucosyltransferases proteins using site-directed mutational analysis and testing the effect of each mutation on substrate specificity and kinetic properties of the enzyme.

site-directed

mutational anaylsis

flavonol-3-O-glucosyltransferases

citrus paradisi

Biological Sciences

School of Graduate Studies

Biochemistry

Molecular Biology

Plant Biology

The Effect of Recombinant Tags on Citrus Paradisi Flavonol-Specific 3-O Glucosyltransferase Activity

Birchfield, Aaron S., McIntosh, Cecilia A.

01 March 2020

Recombinant tags are used extensively in protein expression systems to allow purification through IMAC (Immobilized Metal Affinity Chromatography), identification through Western blot, and to facilitate crystal formation for structural analysis. While widely used, their role in enzyme characterization has raised concerns with respect to potential impact on activity. In this study, a flavonol-specific 3-O glucosyltransferase (Cp3GT) from grapefruit (Citrus paradisi) was expressed in Pichia pastoris, and was assayed in its untagged form and with a C-terminal c-myc/6x His tag under various conditions to determine the effect of tags. Prior characterization of pH optima for Cp3GT obtained through expression in Escherichia coli, containing an N-terminal thioredoxin/6x His tag, indicated an optimal pH of 7–7.5, which is indicative of a normal physiological pH and agrees with other glucosyltransferase (GT) pH optima. However, characterization of Cp3GT expressed using P. pastoris with a C-terminal c-myc-6x His tag showed a higher optimal pH of 8.5–9. This suggests a possible tag effect or an effect related to physiological differences between the cell expression systems. Results testing recombinant Cp3GT expressed in Pichia with and without C-terminal tags showed a possible tag effect with regard to substrate preference and interactions with metals, but no apparent effect on enzymatic kinetics or pH optima.

c-terminal recombinant tags

flavonoids

flavonol

glucosyltransferase

grapefruit

His-tag

PH optima

reaction kinetics

recombinant tags

Biological Sciences

Substrate Specificity and Kinetic Properties of Flavonol-3-O-Glucosyltransferase From Citrus Paradisi

Devaiah, Shivakumar P., McIntosh, Cecelia A.

04 August 2013

Glucosyltransferases (GTs) are enzymes that expedite the incorporation of UDP-activated glucose to a corresponding acceptor molecule. This enzymatic reaction stabilizes structures and affects solubility, transport, and bioavailability of flavonoids for other metabolic processes. Flavonoid glycosides affect taste characteristics in citrus making the associated glucosyltransferases particularly interesting targets for biotechnology applications. Custom design of enzymes requires understanding of structure/function of the protein. The present study focuses on creating mutant flavonol-3-O-glucosyltransferase (F-3-O-GT) proteins using site directed mutagenesis and testing the effect of each mutation on substrate specificity, regiospecificity and kinetic properties of the enzyme. Mutations were selected on the basis of sequence similarity between grapefruit F-3- O-GT, an uncharacterized GT gene in blood orange (98%), and grape F3GT (82%). Grapefruit F-3-O-GT prefers flavonol as a substrate whereas the blood orange sequence is annotated to be a flavonoid 3GT and the grape GTs could glucosylate both flavonols and anthocyanidins. Mutants of F-3-O-GT were generated by substituting N242K, E296K and N242K+E296K and proteins were expressed in Pichia pastoris using the pPICZA vector. Analysis of these mF-3-O-GTs showed that all of them preferred flavonols over flavanone, flavone, isoflavones, or anthocyanidin substrates and showed decrease in enzyme activity of 16 to 51% relative to the wild type F-3- O-GT.

substrate specificity

kinetic properties

flavonol-3-O-glucosyltransferase

citrus paradisi

enzymes

GTs

glucosyltransferases

UDP-activated glucose

Biological Sciences

School of Graduate Studies

Biochemistry

Molecular Biology

Plant Biology

Investigating Potentially Key Residues Which Imparts the Substrate and Regiospecifi city of aFlavonol-Specifi c 3-O-Glucosyltransferase from Grapefruit

Adepoju, Olusegun A., Shivakumar, Devaiah P., McIntosh, Cecelia A.

09 August 2013

Most naturally-occurring fl avonoids are found in glucosylated form. Glucosyltransferases (GTs) are enzymes that catalyze the transfer of glucose from a high energy sugar donor to an acceptor molecule. Citrus paradisi fl avonol-specifi c glucosyltransferase (Cp-F3-O-GT) is recognized for its rigid substrate and regiospecifi city. In this work, homology modeling, site-directed mutagenesis, and biochemical analyses of the recombinant mutant Cp-F3-O-GT proteins were used to investigate potential amino acid residues that might be responsible for the enzymes strict regiospecifi city while also investigating its substrate specifi city. The single point mutations of three amino acid residues within the grapefruit F3-O-GT identifi ed through sequence alignment and homology modeling were performed. Analyses of the enzyme activity of the recombinant mutant F3-O-GT proteins revealed that the single point mutations of serine 20 to leucine (S20L) and proline 297 to phenylalanine (P297F) rendered the recombinant enzymes inactive with fl avonol substrates at 6% and 12% respectively relative to wild-type. However, the mutation of glycine 392 to glutamate (G392E) remained active and glucosylated the fl avonol acceptors quercein (Km app= 11 μM; Vmax = 5.7 pKat/μg) relative to the wild-type (Km app= 93 μM; Vmax = 41.7 pKat/μg), and kaempferol (Km app= 7 μM; Vmax = 3.8 pKat/μg) relative to the wild-type (Km app = 39 μM; Vmax = 4.2 pKat/ μg). The mutant enzyme also did not show broadened acceptor substrate specifi city as it also favored fl avonols as the preferred acceptor substrate. The optimum pH of the mutant enzyme was 8.0 similar to the wild-type F3-O-GT. Activity of the mutant enzyme was stimulated by NaCl and KCl, but inhibited by Cu2+, Zn2+, Fe2+ as well as UDP with an apparent Ki of 10μM. Product identifi cation to determine glucosylation position is being investigated for a possible change in regiospecifi city.

key residues

substrate

regiospecificity

flavonol-specific

3-O-glucosyltransferase

grapefruit

GTs

glucosyltransferases

mutagenesis

flavonoids

Citris paradisi

Biological Sciences

School of Graduate Studies

Biochemistry

Molecular Biology

Plant Biology

Determination of the Substrate Specificity of the Mutant D344P of Citrus paradisi Flavonol-Specific 3-O-Glucosyltransferase

Spaulding, Nathan, Devaiah, Shivakumar, McIntosh, Cecelia A.

12 April 2017

Plants produce a vast array of secondary metabolites. The phenolic compounds flavonoids are metabolites ubiquitous among plants and are known to aid in processes such as plant reproduction, UV defense, pigmentation and development. In relation to human health, flavonoids have also been found to possess anti-inflammatory, anti-cancer, and anti-oxidant properties. Flavonoids ability to participate in so many interactions is due in part to their subclass variation and further chemical modification. One such modification is glucosylation, where a glucose molecule is added to the flavonoid substrate. The enzymes that catalyze these reactions are known as glucosyltransferases. Citrus paradisi contains a glucosyltransferase that is specific to the 3-O position of flavonols. To further understand the reactions it catalyzes, Cp3-O-GT structure was modeled against an anthocyanidin/flavonol 3 GT found in Vitis vinifera to identify candidate amino acids for mutations. Mutants were then created using site-directed mutagenesis, and one mutant, D344P, was constructed by an aspartate being replaced with a proline based off of the sequence comparison of the original enzymes. Biochemically characterizing the mutant D344P protein will determine whether the mutation has an effect on the substrate specificity of Cp3-O-GT. An initial quickscreening assay using radioactive UDP-glucose as a sugar donor suggested there may have been expansion of substrate acceptance. Confirming time course assays did not support this. Additionally, results of these assays show that D344P protein has decreased activity with flavonols as compared to wild type Cp3-O-GT. with no expansion of substrate specificity. Models suggest that a change in protein conformation has resulted in decreased activity.

substrate specificity

kinetic properties

flavonol-3-O-glucosyltransferase

citrus paradisi

enzymes

GTs

glucosyltransferases

UDP-activated glucose

Biological Sciences

School of Graduate Studies

Biochemistry

Molecular Biology

Plant Biology

The Effect of R382W Mutation on C. paradisi Flavonol-Specific 3-O-Glucosyltransferase

King, Kathleen, Shivakumar, Devaiah P., McIntosh, Cecelia A.

10 August 2015

Flavonoids are a class of plant metabolites with C6-C3-C6 structure responsible for many biological functions, including coloration and defense. Citrus paradisi, grapefruit, contains a wide variety of flavonoids which are grouped by the extent of modification, examples of which are flavonols, flavones, and flavanones. A major modification is the addition of glucose by glucosyltransferases (GTs) to stabilize the structure and provide ease of transport. This process can be highly substrate and regiospecific. With Cp3OGT, glucose is added at the 3-hydroxy position. This 3GT only accepts flavonols as its substrate; however, a Vitis vinifera (grape) 3-GT can accept both flavonols and anthocyanidins. Homology modeling using the crystallized structure of the V. vinifera GT predicted sites of amino acids that could influence substrate binding site. The 382 position was of particular interest with arginine in C. paradisi and tryptophan in V. vinifera. This change is hypothesized to cause a shift in substrate specificity of the Cp3OGT to accept anthocyanidins as well as flavonols. Site-directed mutagenesis was performed to form the R382W mutant Cp3OGT and transformed into yeast for expression. Western blot determined the optimal protein induction period for the cells, after which the cells were broken to extract the recombinant mutant protein. Purification of the R382W 3GT allowed for enzyme analysis to be performed by measuring the incorporation of radioactive glucose into the reaction product. HPLC will be used to identify reaction products. An enzyme kinetics study will show the extent of any biochemical change in function as a result of this mutation; results will then be incorporated into a refined protein model.

R382w mutation

Citrus paradisi

flavonol

flavonoids

3-O-glucosyltransferase

C6-C3-C6 structure

Biological Sciences

School of Graduate Studies

Biochemistry

Molecular Biology

Plant Biology