Elucidation of Enzyme-Substrate Selectivity Using a Quick Quantitative Screening Protocol

Somers, Neil A.

January 1999

No description available.

Enzyme-Substrate Selectivity

Autoregulatory and structural control of CaMKII substrate specificity

Johnson, Derrick Ethan

06 July 2016

Indiana University-Purdue University Indianapolis (IUPUI) / Calcium/calmodulin (CaM)-dependent protein kinase II (CaMKII) is a multimeric holoenzyme composed of 8–14 subunits from four closely related isoforms (α, β, γ, δ). CaMKII plays a strategic, multifunctional role in coupling the universal second messenger calcium with diverse cellular processes including metabolism, cell cycle control, and synaptic plasticity. CaMKII exhibits broad substrate specificity, targeting numerous substrates with diverse phosphorylation motifs. Binding of the calcium sensor CaM to the autoregulatory domain (ARD) of CaMKII functions to couple kinase activation with calcium signaling. Important sites of autophosphorylation, namely T287 and T306/7 (δ isoform numbering), reside within the ARD and control either CaM dependence or ability to bind to CaMKII respectively, thus determining various activation states of the kinase. Because autophosphorylation is critical to the function of CaMKII in vivo, we sought to determine the relationship between the activation state of the kinase and substrate selectivity. We show that the ARD of activated CaMKII tunes substrate selectivity by competing for substrate binding to the catalytic domain, thus functioning as a selectivity filter. Specifically, in the absence of T287 autophosphorylation, substrate phosphorylation is limited to high-affinity, consensus substrates. T287 autophosphorylation restores maximal kinase activation and broad substrate selectivity by disengaging ARD filtering. The unique multimeric architecture of CaMKII is an ideal sensor which encodes calcium-spike frequency into graded levels of subunit activation/autophosphorylation within the holoenzyme. We find that differential activation states of the holoenzyme produce distinct substrate phosphorylation profiles. Maximal holoenzyme activation/autophosphorylation leads to further broadening of substrate specificity beyond the effect of autophosphorylation alone, which is consistent with multivalent avidity. Thus, the ability of calcium-spike frequency to regulate T287 autophosphorylation and holoenzyme activation permits cellular activity to dictate switch-like behavior in substrate selectivity that is required for diverse cellular responses by CaMKII.

Autophosphorylation

Autoregulation

CaMKII

Phosphorylation

Substrate selectivity

Directed Evolution of Glutathione Transferases Guided by Multivariate Data Analysis

Kurtovic, Sanela

January 2008

<p>Evolution of enzymes with novel functional properties has gained much attention in recent years. Naturally evolved enzymes are adapted to work in living cells under physiological conditions, circumstances that are not always available for industrial processes calling for novel and better catalysts. Furthermore, altering enzyme function also affords insight into how enzymes work and how natural evolution operates. </p><p>Previous investigations have explored catalytic properties in the directed evolution of mutant libraries with high sequence variation. Before this study was initiated, functional analysis of mutant libraries was, to a large extent, restricted to uni- or bivariate methods. Consequently, there was a need to apply multivariate data analysis (MVA) techniques in this context. Directed evolution was approached by DNA shuffling of glutathione transferases (GSTs) in this thesis. GSTs are multifarious enzymes that have detoxication of both exo- and endogenous compounds as their primary function. They catalyze the nucleophilic attack by the tripeptide glutathione on many different electrophilic substrates. </p><p>Several multivariate analysis tools, <i>e.g.</i> principal component (PC), hierarchical cluster, and K-means cluster analyses, were applied to large mutant libraries assayed with a battery of GST substrates. By this approach, evolvable units (quasi-species) fit for further evolution were identified. It was clear that different substrates undergoing different kinds of chemical transformation can group together in a multi-dimensional substrate-activity space, thus being responsible for a certain quasi-species cluster. Furthermore, the importance of the chemical environment, or substrate matrix, in enzyme evolution was recognized. Diverging substrate selectivity profiles among homologous enzymes acting on substrates performing the same kind of chemistry were identified by MVA. Important structure-function activity relationships with the prodrug azathioprine were elucidated by segment analysis of a shuffled GST mutant library. Together, these results illustrate important methods applied to molecular enzyme evolution.</p>

Biochemistry

DNA shuffling

substrate selectivity

mutant library

glutathione transferase

multivariate data analysis

prodrug

Biokemi

Directed Evolution of Glutathione Transferases Guided by Multivariate Data Analysis

Kurtovic, Sanela

January 2008

Evolution of enzymes with novel functional properties has gained much attention in recent years. Naturally evolved enzymes are adapted to work in living cells under physiological conditions, circumstances that are not always available for industrial processes calling for novel and better catalysts. Furthermore, altering enzyme function also affords insight into how enzymes work and how natural evolution operates. Previous investigations have explored catalytic properties in the directed evolution of mutant libraries with high sequence variation. Before this study was initiated, functional analysis of mutant libraries was, to a large extent, restricted to uni- or bivariate methods. Consequently, there was a need to apply multivariate data analysis (MVA) techniques in this context. Directed evolution was approached by DNA shuffling of glutathione transferases (GSTs) in this thesis. GSTs are multifarious enzymes that have detoxication of both exo- and endogenous compounds as their primary function. They catalyze the nucleophilic attack by the tripeptide glutathione on many different electrophilic substrates. Several multivariate analysis tools, e.g. principal component (PC), hierarchical cluster, and K-means cluster analyses, were applied to large mutant libraries assayed with a battery of GST substrates. By this approach, evolvable units (quasi-species) fit for further evolution were identified. It was clear that different substrates undergoing different kinds of chemical transformation can group together in a multi-dimensional substrate-activity space, thus being responsible for a certain quasi-species cluster. Furthermore, the importance of the chemical environment, or substrate matrix, in enzyme evolution was recognized. Diverging substrate selectivity profiles among homologous enzymes acting on substrates performing the same kind of chemistry were identified by MVA. Important structure-function activity relationships with the prodrug azathioprine were elucidated by segment analysis of a shuffled GST mutant library. Together, these results illustrate important methods applied to molecular enzyme evolution.

Biochemistry

DNA shuffling

substrate selectivity

mutant library

glutathione transferase

multivariate data analysis

prodrug

Biokemi

Alpha-class Glutathione Transferases from Pig: a Comparative Study

Fedulova, Natalia

January 2011

Glutathione transferases (GSTs, EC 2.5.1.18) possess multiple functions and have potential applications in biotechnology. This thesis contributes to knowledge about glutathione transferases from Sus scrofa (pig). The study is needed for better understanding of biochemical processes in this species and is desirable for drug development, for food industry research and in medicine. A primary role of GSTs is detoxication of electrophilic compounds. Our study presents porcine GST A1-1 as a detoxication enzyme expressed in many tissues, in particular adipose tissue, liver and pituitary gland. Based on comparison of activity and expression profiles, this enzyme can be expected to function in vivo similarly to human GST A2-2 (Paper II). In addition to its protective function, human GST A3-3 is an efficient steroid isomerase and contributes to the biosynthesis of steroid hormones in vivo. We characterized a porcine enzyme, pGST A2-2, displaying high steroid-isomerase activity and resembling hGST A3-3 in other properties as well. High levels of pGST A2-2 expression were found in ovary, testis and liver. The properties of porcine enzyme strengthen the notion that particular GSTs play an important role in steroidogenesis (Paper I). Combination of time-dependent and enzyme concentration-dependent losses of activity as well as the choice of the organic solvent for substrates were found to cause irreproducibility of activity measurements of GSTs. Enzyme adsorption to surfaces was found to be the main explanation of high variability of activity values of porcine GST A2-2 and human Alpha-class GSTs reported in the literature. Several approaches to improved functional comparison of highly active GSTs were proposed (Paper III). / Felaktigt tryckt som Digital Comprehensive Summaries of Uppsala Dissertations from the Faculty of Science and Technology 733

glutathione transferase

substrate selectivity

steroidogenesis

Sus scrofa

functional comparison

irreproducibility

reproducible assays

Biochemistry

Biokemi

Structure and Function in Plant Ä12 Fatty Acid Desaturases and Acetylenases

Gagne, Steve Joseph

22 December 2008

This study provides insight into the structure/function relationship between desaturases and acetylenases, and indicates amino acid residues within acetylenases which influence reaction outcome. <i>Oleate desaturases</i> belong to a family of enzymes capable of introducing cis double bonds between C12 - C13 in oleate esters. Acetylenases are a subset of oleate desaturase enzymes which introduce a triple bond in the C12 - C13 position of linoleate. To better understand which amino acids could be responsible for differentiating the activity of acetylenases from typical desaturases, a total of 50 protein sequences were used to compare the two classes of enzymes resulting in the identification of 11 amino acid residues which are conserved within either separate family but differ between the two groups of enzymes. These identified amino acid residues were then singularly altered by site-directed mutagenesis to test their role in fatty acid modification. Specifically, the wild type acetylenase, Crep1 from <i>Crepis alpina</i>, and a number of point mutants have been expressed in <i>Saccharomyces cerevisiae</i>, followed by fatty acid analysis of the resulting cultures. Results indicate the importance of 4 amino acid residues within Crep1 (Y150, F259, H266, and V304) with regards to desaturase and acetylenase chemoselectivity, stereoselectivity, and/or substrate recognition. The F259L mutation affected the acetylenase by converting it to an atypical FAD2 capable of producing both cis and trans isomers. The V304I mutation resulted in the conversion of Crep1 into a stereoselective FAD2, where only the cis isomers of 16:2 and 18:2 were produced. The Y150F mutation led to a loss of acetylenase activity without affecting the inherent desaturase activity of Crep1. The H266Q mutation appears to affect substrate selection causing an inability to bind substrate (16:1-9c and/or 18:1-9c) in a cisoid conformation, resulting in an increased accumulation of trans product. The changes in enzyme activity detected in cultures expressing Crep1 mutants demonstrate the profound effect that exchanging as little as one amino acid can have on an enzyme properties. Enzymes retain some conservation of amino acids necessary for activity, such as those involved in metal ion binding, whereas subtle changes can affect overall enzyme function and catalysis.

Substrate selectivity

Stereoselectivity

Chemoselectivity

Fatty Acid

Molecular Evolution

Crepis alpina

FAD2

Desaturase

Acetylenase

Acetylenation

Desaturation

Crep1

Enzyme Engineering

Structure and Function in Plant Ä12 Fatty Acid Desaturases and Acetylenases

Gagne, Steve Joseph

22 December 2008

This study provides insight into the structure/function relationship between desaturases and acetylenases, and indicates amino acid residues within acetylenases which influence reaction outcome. <i>Oleate desaturases</i> belong to a family of enzymes capable of introducing cis double bonds between C12 - C13 in oleate esters. Acetylenases are a subset of oleate desaturase enzymes which introduce a triple bond in the C12 - C13 position of linoleate. To better understand which amino acids could be responsible for differentiating the activity of acetylenases from typical desaturases, a total of 50 protein sequences were used to compare the two classes of enzymes resulting in the identification of 11 amino acid residues which are conserved within either separate family but differ between the two groups of enzymes. These identified amino acid residues were then singularly altered by site-directed mutagenesis to test their role in fatty acid modification. Specifically, the wild type acetylenase, Crep1 from <i>Crepis alpina</i>, and a number of point mutants have been expressed in <i>Saccharomyces cerevisiae</i>, followed by fatty acid analysis of the resulting cultures. Results indicate the importance of 4 amino acid residues within Crep1 (Y150, F259, H266, and V304) with regards to desaturase and acetylenase chemoselectivity, stereoselectivity, and/or substrate recognition. The F259L mutation affected the acetylenase by converting it to an atypical FAD2 capable of producing both cis and trans isomers. The V304I mutation resulted in the conversion of Crep1 into a stereoselective FAD2, where only the cis isomers of 16:2 and 18:2 were produced. The Y150F mutation led to a loss of acetylenase activity without affecting the inherent desaturase activity of Crep1. The H266Q mutation appears to affect substrate selection causing an inability to bind substrate (16:1-9c and/or 18:1-9c) in a cisoid conformation, resulting in an increased accumulation of trans product. The changes in enzyme activity detected in cultures expressing Crep1 mutants demonstrate the profound effect that exchanging as little as one amino acid can have on an enzyme properties. Enzymes retain some conservation of amino acids necessary for activity, such as those involved in metal ion binding, whereas subtle changes can affect overall enzyme function and catalysis.

Substrate selectivity

Stereoselectivity

Chemoselectivity

Fatty Acid

Molecular Evolution

Crepis alpina

FAD2

Desaturase

Acetylenase

Acetylenation

Desaturation

Crep1

Enzyme Engineering

Discrimination of Methionine Sulfoxide and Sulfone by Human Neutrophil Elastase

Leahy, Darren, Grant, Cameron, Jackson, Alex, Duff, Alex, Tardiota, Nicholas, Van Haeften, Jessica, Chen, Xingchen, Peake, Jonathan M., Kruppa, Michael D., Smith, Eliot T., Johnson, David A., Lott, William B., Harris, Jonathan M.

01 September 2021

Human neutrophil elastase (HNE) is a uniquely destructive serine protease with the ability to unleash a wave of proteolytic activity by destroying the inhibitors of other proteases. Although this phenomenon forms an important part of the innate immune response to invading pathogens, it is responsible for the collateral host tissue damage observed in chronic conditions such as chronic obstructive pulmonary disease (COPD), and in more acute disorders such as the lung injuries associated with COVID-19 infection. Previously, a combinatorially selected activity-based probe revealed an unexpected substrate preference for oxidised methionine, which suggests a link to oxida-tive pathogen clearance by neutrophils. Here we use oxidised model substrates and inhibitors to confirm this observation and to show that neutrophil elastase is specifically selective for the di-oxygenated methionine sulfone rather than the mono-oxygenated methionine sulfoxide. We also posit a critical role for ordered solvent in the mechanism of HNE discrimination between the two oxidised forms methionine residue. Preference for the sulfone form of oxidised methionine is especially significant. While both host and pathogens have the ability to reduce methionine sulfoxide back to methionine, a biological pathway to reduce methionine sulfone is not known. Taken to-gether, these data suggest that the oxidative activity of neutrophils may create rapidly cleaved elas-tase “super substrates” that directly damage tissue, while initiating a cycle of neutrophil oxidation that increases elastase tissue damage and further neutrophil recruitment.

human neutrophil elastase

methi-onine oxidation

methionine sulfone

peptide aldehyde

substrate guided inhibitor design

substrate selectivity

Biomedical Sciences

Characterization and Directed Evolution of an Alcohol Dehydrogenase : A Study Towards Understanding of Three Central Aspects of Substrate Selectivity

Hamnevik, Emil

January 2017

Many different chemicals are used in the everyday life, like detergents and pharmaceuticals. However, their production has a big impact on health and environment as much of the raw materials are not renewable and the standard ways of production in many cases includes toxic and environmentally hazardous components. As the population and as the life standard increases all over the planet, the demand for different important chemicals, like pharmaceuticals, will increase. A way to handle this is to apply the concept of Green chemistry, where biocatalysis, in the form of enzymes, is a very good alternative. Enzymes do not normally function in industrial processes and needs modifications through protein engineering to cope in such conditions. To be able to efficiently improve an enzyme, there is a need to understand the mechanism and characteristics of that enzyme. Acyloins (α-hydroxy ketones) are important building blocks in the synthesis of pharmaceuticals. In this thesis, the enzyme alcohol dehydrogenase A (ADH-A) from Rhodococcus ruber has been in focus, as it has been shown to display a wide substrate scope, also accepting aryl-substituted alcohols. The aim has been to study the usefulness of ADH-A as a biocatalyst towards production of acyloins and its activity with aryl-substituted vicinal diols and to study substrate-, regio-, and enantioselectivity of this enzyme. This thesis is based on four different papers where the focus of the first has been to biochemically characterize ADH-A and determine its mechanism, kinetics and its substrate-, regio-, and enantioselectivity. The second and third paper aims towards deeper understanding of some aspects of selectivity of ADH-A. Non-productive binding and its importance for enantioselectivity is studied in the second paper by evolving ADH-A towards increased activity with the least favored enantiomer through protein engineering. In the third paper, regioselectivity is in focus, where an evolved variant displaying reversed regioselectivity is studied. In the fourth and last paper ADH-A is studied towards the possibility to increase its activity towards aryl-substituted vicinal diols, with R-1-phenyl ethane-1,2-diol as the model substrate, and the possibility to link ADH-A with an epoxide hydrolase to produce acyloins from racemic epoxides.

Alcohol dehydrogenase

ADH-A

Biocatalysis

Directed evolution

Enantioselectivity

Enzyme kinetics

Enzyme mechanisms

Protein Engineering

Regioselectivity

Substrate selectivity

Biochemistry and Molecular Biology

Biokemi och molekylärbiologi

Modulating Enzyme Functions by Semi-Rational Redesign and Chemical Modifications : A Study on Mu-class Glutathione Transferases

Norrgård, Malena A

January 2011

Today, enzymes are extensively used for many industrial applications, this includes bulk and fine-chemical synthesis, pharmaceuticals and consumer products. Though Nature has perfected enzymes for many millions of years, they seldom reach industrial performance targets. Natural enzymes could benefit from protein redesign experiments to gain novel functions or optimize existing functions. Glutathione transferases (GSTs) are detoxification enzymes, they also display disparate functions. Two Mu-class GSTs, M1-1 and M2-2, are closely related but display dissimilar substrate selectivity profiles. Saturation mutagenesis of a previously recognized hypervariable amino acid in GST M2-2, generated twenty enzyme variants with altered substrate selectivity profiles, as well as modified thermostabilities and expressivities. This indicates an evolutionary significance; GST Mu-class enzymes could easily alter functions in a duplicate gene by a single-point mutation. To further identify residues responsible for substrate selectivity in the GST M2-2 active site, three residues were chosen for iterative saturation mutagenesis. Mutations in position10, identified as highly conserved, rendered enzyme variants with substrate selectivity profiles resembling that of specialist enzymes. Ile10 could be conserved to sustain the broad substrate acceptance displayed by GST Mu-class enzymes. Enzymes are constructed from primarily twenty amino acids, it is a reasonable assumption that expansion of the amino acid repertoire could result in functional properties that cannot be accomplished with the natural set of building blocks. A combination approach of site-directed mutagenesis and chemical modifications in GST M2-2 and GST M1-1 resulted in novel enzyme variants that displayed altered substrate selectivity patterns as well as improved enantioselectivities. The results presented in this thesis demonstrate the use of different protein redesign techniques to modulate various functions in Mu-class GSTs. These techniques could be useful in search of optimized enzyme variants for industrial targets. / biokemi och organisk kemi

protein redesign

semi-rational redesign

saturation mutagenesis

iterative saturation mutagenesis

chemical modification

Cys

Cys-X scanning

enzyme evolution

promiscuous

substrate selectivity

enantioselectivity

Biochemistry

Biokemi