Explorations in enzymology: investigating dynamics in dihydrofolate reductase

Sen, Arundhuti

01 December 2011

The relationship between enzyme dynamics and enzymatic catalysis has become a central topic in modern enzymology, and studies in this area promise to enrich our current understanding of catalysis in biological systems. Escherichia coli dihydrofolate reductase (EcDHFR) has been a frequent subject of study in the context of protein dynamics, due to its small size, biological ubiquity, and the fact that its structural, kinetic and mechanistic characteristics are well established. Intrinsic kinetic isotope effects (KIEs) have proven to be highly sensitive probes of the role of dynamics in EcDHFR catalyzed reaction, as they circumvent the kinetic complexity of the enzyme-catalyzed reactions, and extract information directly pertaining to the chemical step. Previously, studies of their temperature-dependence were used to probe the effect of mutations at residues distant from the active site upon the hydride-transfer reaction catalyzed by EcDHFR. The results of these experiments supported the presence of a network of residues that were dynamically linked to the hydride-transfer step, and were in excellent agreement with computational studies predicting the presence of such a network. This thesis aims to extend upon these results to study the nature and extent of the dynamic network in EcDHFR, both by using an established experimental methods and by developing new biophysical probes of protein dynamics in this system. The major experimental methodology utilized in the following chapters is the determination and analysis of KIEs in a variety of EcDHFR mutants. To facilitate these measurements, new synthetic routes to a range of isotopically labeled nicotinamide cofactors have been developed. Some of the labeled materials have been used to establish a sensitive, triple-isotope technique to competitively measure deuterium isotope effects in enzyme-catalyzed reactions in EcDHFR. Synthesized materials were usd to measure the temperature dependence of intrinsic KIEs in selected dynamically altered mutants of EcDHFR, viz. W133F and F125M DHFR. Crystal structures have been obtained for both these mutants as well as for the previously studied G121V isozyme, and the combination of kinetic and structural information discussed in the context of catalytically important dynamic fluctuations in EcDHFR. Pressure-dependence of deuterium KIEs is also developed as a tool to probe the role of dynamics and tunneling in the EcDHFR reaction, with the ultimate aim of establishing high-pressure KIE measurements as a complementary method to variable temperature measurements. Finally, molecular recognition force spectroscopy (MRFS) measurements of an EcDHFR self-assembled monolayer (SAM) on gold are described. The surprisingly active enzymatic SAM has been shown to be a promising platform for future MRFS experiments to measure the forces involved in EcDHFR dynamics. All together, these studies advanced our ability to study the role of enzyme dynamics and quantum tunneling in enhancing their chemistry.

catalysis

crystallography

DHFR

dynamics

enzymes

KIE

Chemistry

Recrossing and Heavy-atom Tunneling in Common Organic Reactions

James, Ollie

2011 December 1900

Non-statistical recrossing in ketene cycloadditions with alkenes, heavy-atom tunneling and the mechanism of the decarboxylation of Mandelylthiamin is investigated in this dissertation. A combination of experimental kinetic isotope effects and theoretical models and kinetic isotope effects is utilized for this endeavor. This dissertation also describes how the use of quasiclassical dynamic trajectories, microcanonical RRKM calculations, and canonical variational transition state theory in combination with small-curvature tunneling approximations is utilized to help advance our research methodology to better understand mechanism. In the cycloaddition of dichloroketene with cis-2-butene, significant amounts of recrossing is observed using quasiclassical dynamic trajectories. An unusual inverse 13C intramolecular KIE lead us to investigate the role that heavy atoms play in non-statistical recrossing. More importantly, this discovery has uncovered a new phenomena of entropic intermediates that not only applies to ketene cycloadditions, but can also be applicable to other "concerted" reactions such as Diels-Alder reactions. The ring-opening of cyclopropylcarbinyl radical has revealed that heavy-atom tunneling plays a major role. The intramolecular 13C kinetic isotope effects for the ring-opening of cyclopropylcarbinyl radical were unprecedentedly large and in combination with theoretical predictions and multidimensional tunneling corrections, the role of tunneling in this reaction can be better understood. The mechanism decarboxylation of mandelylthiamin has been extensively studied in the literature. However, until the use of theoretically predicted KIEs and theoretical binding motifs the rate-limiting step of this reaction has been hotly debated. In this dissertation, a discussion of how the theoretical KIEs indicate the initial C-C bond as the rate-limiting step and chelating binding motifs of pyridinium and mandelylthiamin to explain the observed catalysis is given.

kinetic isotope effects

KIE

dynamics, non-statistical recrossing

mechanism

tunneling

Pin1: WW domain ligands, catalytic inhibitors, and the mechanism

Mercedes-Camacho, Ana Yokayra

25 May 2011

The peptidyl prolyl cis/trans isomerase, PPIase, has been the focus of numerous studies in the field of cell cycle regulation since proline-directed phosphorylation is an essential signaling mechanism that might arrest cancer proliferation. Pin1 is the first phosphorylation-dependent PPIase enzyme to be discovered. The Pin1 regulatory mechanism, acting on other mitotic proteins in vivo and in vitro, remains largely unknown. For the study of Pin1 function, two types of assays were used to identity ligands for Pin1: (1) The Enzyme-Linked Enzyme Binding Assay (ELEBA) for the identification of WW domain ligands, (2) a catalytic assay to identified inhibitors of Pin1 catalytic activity. The ELEBA offers a selective approach for detecting ligands that bind to the Pin1 WW domain from chemical libraries. By using the ELEBA, a pSer-Pro peptidomimetic library of 315 ligands was screened, identifying three promising ligands cis-D2, O2, and M18. Competitive Kd values for cis-D2, O2, and M18 were determined to be 263 ± 6.4, 206 ± 3.4, and 130 ± 3.0μM, respectively. Furthermore, we screened the pSer-Pro peptidomimetic library using a Pin1 discontinuous-catalytic assay to identify inhibitors of Pin1. Ligands D20 and K7 were identified to decrease more than 90% of the Pin1 catalytic activity. To investigate the nature of the Pin1 interaction with c-Myc, we synthesized and characterized four peptides corresponding to the c-Myc sequence. These peptides were used in NMR isomerization studies of Pin1 by our collaborator Dr. Jeffry Peng (University of Notre Dame). Preliminary work shows that Pin1 binds and isomerizes the Ac–LLPpTPPLSPS–NH₂ peptide at the cMyc pThr58 position. Finally, we measured a secondary kinetic isotope effect (2º KIE) to study the Pin1 catalytic mechanism of proline isomerization. The ratio of kH/kD for unlabeled and [d₃]Ser-labeled substrate gave a SKIE value of 1.34 ± 0.01. The normal 2º KIE value indicates that carbonyl-serine hybridization is not changing from sp² to sp³. This result supports substrate analogue inhibitor studies, and previous solvent and SKIE results on Pin1, that suggest a twisted amide mechanism assisted by a transient hydrogen bond in the transition state. / Ph. D.

PPIases

Pin1 inhibitors

WW domain ligands

KIE

c-Myc

ELEBA

Elucidation des Mécanismes de O- et C-glycosylation par des Moyens Chimiques et Spectroscopiques / Elucidating Mechanisms of O- and C-glycosylation by Chemical and Spectroscopic Means

Huang, Min

12 November 2012

L’effet isotopique cinétique (KIE) est un outil puissant pour obtenir un aperçu sur le mécanisme d'une grande variété réactions. Nous avons observé différentes mesures de l’effet isotopique cinétique primaire du 13C pour la formation des α-, et β-mannopyranosides et des α- et β-glucopyranosides, en partant du sulfoxyde de glycosyle protégé par le groupement 4,6-O-benzylidène, par la spectroscopie RMN à ultrahaut champ (13C à 200 MHz et 1H à 800 MHz). Nous avons aussi calculé les KIE pour ces réactions en collaboration avec le Prof. Pratt à l'Université d'Ottawa. Les valeurs expérimentale et calculée (B3LYP / 6-31G (d, p) avec un modèle de continuum polarisable) sont en bon accord sauf pour l’α-mannopyranoside. Trois cas (-mannopyanoside,  et -glucopyranosides) parmi les quatre ont montré un caractère “SN2-like“, mais la formation de l'-mannopyranoside suggère fortement un mécanisme dissociatif (SN1). Une telle différence de mécanisme nécessite une authentification par des mesures cinétiques. Nous avons ensuite porté notre attention sur le développement d'une réaction intramoléculaire, comme horloge intramoléculaire, afin d’évaluer la cinétique relative des réactions de glycosylation. La formation des produits tricycliques fournit une grande évidence de l'existence d'un ion mannosyloxocarbénium comme un intermédiaire transitoire. Les réactions de compétition avec de l'isopropanol et du méthallyltriméthylsilane sont interprétées comme indiquant que la β-O-mannosylation passe par un mécanisme associatif (SN2-like), tandis que l’α-O-mannosylation et le β-C-mannosylation sont dissociative (SN1-like). Ceci est en plein accord avec nos résultats expérimentaux sur l’effet isotopique cinétique. Cette approche de la détermination de la cinétique relative des réactions de glycosylation est une méthode directe et est potentiellement applicable à une large variété de donneurs de glycosyle. / Kinetic isotopic effects (KIEs) are powerful tools to obtain insight into the mechanism of a great range of reactions. We demonstrated differing primary 13C kinetic isotope effect (KIE) measurements for the formation of α-, β-mannopyranosides and α-, β-glucopyranosides from the 4,6-O-benzylidene protected mannosyl and glucosyl sulfoxides by NMR (13C at 200 MHz and 1H at 800 MHz). We have also calculated the KIEs in collaboration with the Pratt group at the University of Ottawa for these reactions. Experimental and calculated (B3LYP/ 6-31G (d,p) values with a polarizable continuum model) were in good agreement, except for the -mannopyranoside. Three of (-mannpyanoside and the -, -glupyranosides) four cases showed a SN2-like character. The formation of the -mannopyranoside on the other hand suggests a strongly dissociative mechanism (SN1). Such a difference in mechanism necessarily demands authentication by kinetic measurements. We turned then our attention to the development of an intramolecular clock reaction with which to probe the relative kinetics of glycosylation reactions and to the formation of the tricyclic products that provides strong evidence for the existence of a mannosyl oxocarbenium ion as a transient intermediate. Competition reactions with isopropanol and trimethylmethallylsilane are interpreted as indicating β-O-mannosylation to proceed via an associative SN2-like mechanism, whereas α-O-mannosylation and β-C-mannosylation are dissociative and SN1-like. This is in full agreement with our experimental KIE results. This approach to the determination of relative kinetics of glycosylation reactions, is straightforward and is potentially applicable to a broad range of glycosyl donors.

Glycosylation

KIE (Effet isotopique cinétique)

Ion oxocarbénium

Cinétique relative

Glycosylation

KIE (Kinetic isotope effect)

Oxocarbenium ion

Relative kinetics

Elucidation des Mécanismes de O- et C-glycosylation par des Moyens Chimiques et Spectroscopiques

Huang, Min

12 November 2012

L'effet isotopique cinétique (KIE) est un outil puissant pour obtenir un aperçu sur le mécanisme d'une grande variété réactions. Nous avons observé différentes mesures de l'effet isotopique cinétique primaire du 13C pour la formation des α-, et β-mannopyranosides et des α- et β-glucopyranosides, en partant du sulfoxyde de glycosyle protégé par le groupement 4,6-O-benzylidène, par la spectroscopie RMN à ultrahaut champ (13C à 200 MHz et 1H à 800 MHz). Nous avons aussi calculé les KIE pour ces réactions en collaboration avec le Prof. Pratt à l'Université d'Ottawa. Les valeurs expérimentale et calculée (B3LYP / 6-31G (d, p) avec un modèle de continuum polarisable) sont en bon accord sauf pour l'α-mannopyranoside. Trois cas (-mannopyanoside,  et -glucopyranosides) parmi les quatre ont montré un caractère "SN2-like", mais la formation de l'-mannopyranoside suggère fortement un mécanisme dissociatif (SN1). Une telle différence de mécanisme nécessite une authentification par des mesures cinétiques. Nous avons ensuite porté notre attention sur le développement d'une réaction intramoléculaire, comme horloge intramoléculaire, afin d'évaluer la cinétique relative des réactions de glycosylation. La formation des produits tricycliques fournit une grande évidence de l'existence d'un ion mannosyloxocarbénium comme un intermédiaire transitoire. Les réactions de compétition avec de l'isopropanol et du méthallyltriméthylsilane sont interprétées comme indiquant que la β-O-mannosylation passe par un mécanisme associatif (SN2-like), tandis que l'α-O-mannosylation et le β-C-mannosylation sont dissociative (SN1-like). Ceci est en plein accord avec nos résultats expérimentaux sur l'effet isotopique cinétique. Cette approche de la détermination de la cinétique relative des réactions de glycosylation est une méthode directe et est potentiellement applicable à une large variété de donneurs de glycosyle.

[CHIM:OTHE] Chemical Sciences/Other

[CHIM:OTHE] Chimie/Autre

Glycosylation

KIE (Effet isotopique cinétique)

Ion oxocarbénium

Cinétique relative

Investigating the contribution of protein dynamics to catalysis in protochlorophyllide oxidoreductase

Hoeven, Robin

January 2015

Enzyme dynamics has been established to play a crucial role in catalysis, and it has therefore become an important area of research to better understand enzymatic rate enhancements. The light-activated enzyme protochlorophyllide oxidoreductase (POR) is a well-studied model system where dynamics are known to be important for catalysis. The catalytic reaction involves a sequential hydride and proton transfer to reduce the C17-C18 double bond in the protochlorophyllide (Pchlide) substrate with NADPH as a cofactor to yield the chlorophyllide (Chlide) product. Both H-transfer steps are established to undergo quantum tunneling, as derived from the temperature-dependence of the kinetic isotope effects (KIEs). Furthermore, a role for ‘promoting motions/vibrations’ has been presumed from the temperature-dependence KIE data, which will be investigated further in this thesis by the study of the KIE response to pressure. A general overview of the pressure-dependence as a new experimental probe is presented and compared with temperature-dependencies of KIEs, to establish whether pressure is suitable as an alternative technique for studying the role of enzyme dynamics in catalysis. This involves a comparison of pressure data from other enzyme systems to newly collected data for POR. However, no clear trend between temperature and pressure data is observed and hence, it can be concluded that pressure effects can be difficult to interpret. A case by case analysis is required and needs to be combined with computational simulations based on structural evidence (e.g. X-ray crystallographic), which is not yet available for POR.Solvent-viscosity has been successfully used to probe enzyme dynamics in POR and provides information on the extent of any protein networks that are involved along the reaction coordinate. Here I investigate the solvent-viscosity dependence of both H-transfer reactions in POR for a range of homologous POR enzymes to obtain an evolutionary perspective of the protein dynamics required for catalysis. This has been successfully used in the past on a limited number of POR homologues and has led to the formulation of a hypothesis supporting a twin-track evolution of the two catalytic steps in POR. I observed a lack of solvent-viscosity dependence in case of the hydride transfer across all the investigated lineages, while the proton transfer was shown to be more strongly affected by viscosity in prokaryotic enzymes than in their eukaryotic counterparts. This supports the proposed theory, suggesting an early optimisation of the dynamics involved in the light-activated hydride transfer with a strong reliance on localised motion. Conversely, the proton transfer experienced selective pressure to reduce its dependence on complex solvent-slaved motion and that has led to localised dynamics in eukaryotic POR homologues. Additionally, I found that the enzymes from eukaryotic species have a higher rate of both H-transfer steps, suggesting that an optimisation of the active site architecture occurred upon endosymbiosis. Enzyme dynamics clearly have a pivotal role to play in catalysis of this unique light-activated enzyme and detection of these will only be possible by detailed structural information.

572

Advancement and Application of Gas Chromatography Isotope Ratio Mass Spectrometry Techniques for Atmospheric Trace Gas Analysis

Giebel, Brian M

22 July 2011

The use of gas chromatography isotope ratio mass spectrometry (GC-IRMS) for compound specific stable isotope analysis is an underutilized technique because of the complexity of the instrumentation and high analytical costs. However stable isotopic data, when coupled with concentration measurements, can provide additional information on a compounds production, transformation, loss, and cycling within the biosphere and atmosphere. A GC-IRMS system was developed to accurately and precisely measure δ13C values for numerous oxygenated volatile organic compounds (OVOCs) having natural and anthropogenic sources. The OVOCs include methanol, ethanol, acetone, methyl ethyl ketone, 2-pentanone, and 3-pentanone. Guided by the requirements for analysis of trace components in air, the GC-IRMS system was developed with the goals of increasing sensitivity, reducing dead-volume and peak band broadening, optimizing combustion and water removal, and decreasing the split ratio to the IRMS. The technique relied on a two-stage preconcentration system, a low-volume capillary reactor and water trap, and a balanced reference gas delivery system. Measurements were performed on samples collected from two distinct sources (i.e. biogenic and vehicle emissions) and ambient air collected from downtown Miami and Everglades National Park. However, the instrumentation and the method have the capability to analyze a variety of source and ambient samples. The measured isotopic signatures that were obtained from source and ambient samples provide a new isotopic constraint for atmospheric chemists and can serve as a new way to evaluate their models and budgets for many OVOCs. In almost all cases, OVOCs emitted from fuel combustion were enriched in 13C when compared to the natural emissions of plants. This was particularly true for ethanol gas emitted in vehicle exhaust, which was observed to have a uniquely enriched isotopic signature that was attributed to ethanol’s corn origin and use as an alternative fuel or fuel additive. Results from this effort show that ethanol’s unique isotopic signature can be incorporated into air chemistry models for fingerprinting and source apportionment purposes and can be used as a stable isotopic tracer for biofuel inputs to the atmosphere on local to regional scales.

OVOCs

Atmospheric Trace Gas

Ethanol

Sources and Sinks

Kinetic Isotope Effect (KIE)