Kinetic and mechanistic studies of oxygen sensing Fe(II)/2-oxoglutarate dependent oxygenases

Tarhonskaya, Hanna

January 2014

The Fe(II)/2-oxoglutarate (2OG) dependent oxygenases are a widespread enzyme family, which are characterised by structurally similar active sites and proposed to employ a common reaction mechanism. The work described in this thesis concerned kinetic and biophysical studies on 2OG oxygenases, with a particular focus on the hypoxia-inducible transcription factor (HIF) hydroxylases and mechanistic aspects of their reaction with oxygen. The four human HIF hydroxylases regulate cellular levels and transcriptional activity of HIF by catalysing its post-translational hydroxylation in response to changes in oxygen availability. The three prolyl hydroxylase domain enzymes (PHDs1-3) and factor inhibiting HIF (FIH) are proposed to act as cellular oxygen sensors and provide a direct link between oxygen availability and the hypoxic response. Previous transient kinetic studies have shown that PHD2 (the most important human PHD isoform) reacts slowly with oxygen, a factor proposed to be related to its oxygen-sensing role. The molecular mechanisms for the slow PHD2 reaction with oxygen were investigated using a range of kinetic and biophysical techniques to probe the effects of key active site substitutions. The studies reveal that a conservative substitution to an Fe(II)/H₂O binding residue results in 5-fold faster reaction with oxygen, suggesting a role for H₂O release from the active site in limiting the ability of oxygen to react with PHD2. This thesis also describes the first transient kinetic studies of FIH. The obtained results show that the rate of the FIH reaction with oxygen was significantly faster than for PHD2. Further, FIH catalyses hydroxylation not only of HIF-α, but also of proteins containing ankyrin repeat domains (ARD). The rate of the FIH reaction with oxygen was shown to be substrate dependent; faster oxygen activation of the reaction in the presence of ARD compared with HIF substrates was observed. Mechanistic studies were performed to investigate a report that PHD2 is involved in the enzymatic oxidation of an oncometabolite (R)-2-hydroxyglutarate (2HG) to give 2OG, in what would be an unprecedented reaction for a 2OG oxygenase. This work found that 2HG does not substitute for 2OG in PHD2 catalysis. Instead, the non-enzymatic transformation of 2HG to 2OG was observed, which could potentially contribute to the reported 2HG-dependent PHD activation in vivo. The biophysical and transient kinetic techniques used for studying the HIF hydroxylases were also applied to study the mechanism of deacetoxycephalosporin C synthase (DAOCS, the enzyme catalysing penicillin N ring expansion). Previously, it has been suggested that the DAOCS mechanism differs from the consensus 2OG oxygenase mechanism. The results described in this thesis provide strong evidence that DAOCS employs the consensus ordered mechanism characteristic of 2OG oxygenases, supporting the proposal that the consensus mechanism is a common feature of the 2OG oxygenase family. Overall, the work described in this thesis is supportive of the proposal that most, if not all, 2OG oxygenases employ a common mechanism. However, the differences in the kinetics of their reaction with oxygen, presented throughout the thesis, suggest that different 2OG oxygenases have different rate-limiting steps. Thus, the kinetics of specific oxygenases may be adapted to their biological function, in particular that of PHD2 as the key cellular O₂ sensor.

572

Molecular aspects of biomolecule structure and function

Rodger, Alison

January 2002

All biological processes are fundamentally inter-molecular interactions. In order to understand, and hence control, biomolecular structure and function, methods are required that probe biological systems at the molecular level, ideally with those molecules being in their native environment. The research summarized herein has at its core the development and application of ultra violet (UV)-visible spectrophotometric techniquies for this prupose, in particular circular dichrosim (CD) and linear dichrosim (LD) but also absorbance, fluorescence and resonance light scattering. The spectroscopy is complemented by fundamental theoretical work on molecular structure and reactivity that forms the basis for designing molecules to bind to biomolecules for a particular structural or functional effect. A brief summary of the contributions of the listed publications to our understanding of 'Molecular aspects of biololecule structure and function' is given below under five headings: Circular dichroism theory Molecular geometry and reactivity Small molecule-macromolecule interactions: spectroscopic probes of inter-molecular geometries Molecular design for nucleic acid structure and control Spectroscopic probes of biomolecule structure: instrumentation and application In general terms these correspond to successive phases of the research programme, however, all areas have been present since the first publications in 1983 and can be traced weaving through all subsequent activity.

An Ultrafast Spectroscopic and Quantum-Chemical Study of the Photochemistry of Bilirubin : Initial Processes in the Phototherapy for Neonatal Jaundice

Zietz, Burkhard

January 2006

<p>Bilirubin is a degradation product of haem, which is constantly formed in all</p><p>mammals. Increased levels of bilirubin in humans lead to jaundice, a condition</p><p>that is very common during the first days after birth. This neonatal</p><p>jaundice can routinely be treated by phototherapy without any serious side</p><p>effects. During this treatment, bilirubin undergoes a photoreaction to isomers</p><p>that can be excreted. The most efficient photoreaction is the isomerisation</p><p>around a double bond (Z-E-isomerisation), which results in more soluble</p><p>photoproducts.</p><p>The work presented in this thesis shows results of a femtosecond optical</p><p>spectroscopy study, combined with quantum-mechanical investigations, of</p><p>the mechanism of isomerisation of bilirubin. The spectroscopic research was</p><p>conducted with bilirubin in organic solvents, and in buffer complexed by</p><p>human serum albumin. This albumin complex is present in the blood, and</p><p>has thus medical importance. Quantum-chemical calculations (CASSCF) on</p><p>a bilirubin model were used to explain experimental results.</p><p>The fluorescence decay observed with femtosecond spectroscopy shows an</p><p>ultrafast component (~120 fs), which is explained by exciton localisation,</p><p>followed by processes with a lifetime of about 1-3 ps. These are interpreted</p><p>as the formation of a twisted intermediate, which decays with a lifetime of</p><p>10-15 ps back to the ground state, as observed by absorption spectroscopy.</p><p>CASSCF calculations, in combination with the experimental results, suggest</p><p>the ca. 1-3 ps components to be relaxation to the twisted S1 minimum, followed</p><p>by the crossing of a barrier, from where further relaxation takes place</p><p>through a conical intersection back to the ground state.</p><p>Time-dependent DFT calculations were utilised to analyse the absorption</p><p>spectrum of bilirubin. Good agreement with the measured spectrum was</p><p>achieved, and low-lying states were observed, that need further investigation.</p><p>The theoretically obtained CD spectrum provides direct evidence that</p><p>bilirubin preferentially binds to human serum albumin in the enantiomeric</p><p>P-form at neutral pH.</p> / <p>Bilirubin är en nedbrytningsprodukt av hem som ständigt bildas hos alla</p><p>däggdjur. En förhöjd bilirubinkoncentration i den mänskliga kroppen kan</p><p>leda till gulsot, något som är mycket vanligt under de första dagarna efter</p><p>födelsen (neonatal gulsot). Fototerapi används rutinmässigt som säker behandlingsmetod,</p><p>under vilken bilirubin genomgår en fotoreaktion till en</p><p>isomer som kan utsöndras. Den mest effektiva fotoreaktionen är en Z-Eisomerisation,</p><p>vilken leder till lösligare fotoprodukter.</p><p>Arbetet som presenteras i denna avhandling visar resultaten av en kombinerad</p><p>femtosekund optisk-spektroskopisk och kvantmekanisk undersökning</p><p>av mekanismen bakom bilirubins isomerisation. Den spektroskopiska</p><p>studien genomfördes med bilirubin, löst i organiska lösningsmedel och i</p><p>buffert i komplex med humant serumalbumin. Detta albuminkomplex finns i</p><p>blodet, och är därför av medicinskt intresse. Kvantmekanistiska CASSCFberäkningar</p><p>på en bilirubinmodell användes för att förklara de experimentella</p><p>resultaten.</p><p>Det uppmätta fluorescence sönderfallet visar ultrasnabba komponenter</p><p>(~120 fs). Dessa tolkas som excitonlokalisering, som följs av bildandet av</p><p>ett vridet intermediat med en hastighetskonstant på ca. 1 ps-1(beroende på</p><p>lösningsmedlet). Absorptionsmätningar visar att detta intermediat sönderfaller</p><p>tillbaka till grundtillståndet med en livstid på 10-15 ps.</p><p>CASSCF beräkningar, i kombination med de experimentella resultaten, tyder</p><p>på att sönderfallet med livslängden på ca. 1 ps är en relaxation till det</p><p>vridna S1-tillståndet. Reaktionsvägen därifrån antas passera en barriär till en</p><p>konisk genomskärning, som möjliggör snabb relaxation till grundtillståndet.</p><p>Tidsberoende DFT-beräkningar användes för att analysera bilirubins absorptionsspektrum,</p><p>vilket gav bra överensstämmelse med uppmätta data. Dessutom</p><p>hittades ett tillstånd med låg excitationsenergi, som kräver ytterligare</p><p>studier. Med hjälp av det beräknade CD-spectret kunde det visas att bilirubin</p><p>binder till albumin i P-formen vid neutralt pH.</p>

Bilirubin

Phototherapy

Neonatal Jaundice

Femtosecond Spectroscopy

CASSCF

TD-DFT

Isomerisation Dynamics

Biophysical chemistry

Biofysikalisk kemi

An Ultrafast Spectroscopic and Quantum-Chemical Study of the Photochemistry of Bilirubin : Initial Processes in the Phototherapy for Neonatal Jaundice

Zietz, Burkhard

January 2006

Bilirubin is a degradation product of haem, which is constantly formed in all mammals. Increased levels of bilirubin in humans lead to jaundice, a condition that is very common during the first days after birth. This neonatal jaundice can routinely be treated by phototherapy without any serious side effects. During this treatment, bilirubin undergoes a photoreaction to isomers that can be excreted. The most efficient photoreaction is the isomerisation around a double bond (Z-E-isomerisation), which results in more soluble photoproducts. The work presented in this thesis shows results of a femtosecond optical spectroscopy study, combined with quantum-mechanical investigations, of the mechanism of isomerisation of bilirubin. The spectroscopic research was conducted with bilirubin in organic solvents, and in buffer complexed by human serum albumin. This albumin complex is present in the blood, and has thus medical importance. Quantum-chemical calculations (CASSCF) on a bilirubin model were used to explain experimental results. The fluorescence decay observed with femtosecond spectroscopy shows an ultrafast component (~120 fs), which is explained by exciton localisation, followed by processes with a lifetime of about 1-3 ps. These are interpreted as the formation of a twisted intermediate, which decays with a lifetime of 10-15 ps back to the ground state, as observed by absorption spectroscopy. CASSCF calculations, in combination with the experimental results, suggest the ca. 1-3 ps components to be relaxation to the twisted S1 minimum, followed by the crossing of a barrier, from where further relaxation takes place through a conical intersection back to the ground state. Time-dependent DFT calculations were utilised to analyse the absorption spectrum of bilirubin. Good agreement with the measured spectrum was achieved, and low-lying states were observed, that need further investigation. The theoretically obtained CD spectrum provides direct evidence that bilirubin preferentially binds to human serum albumin in the enantiomeric P-form at neutral pH. / Bilirubin är en nedbrytningsprodukt av hem som ständigt bildas hos alla däggdjur. En förhöjd bilirubinkoncentration i den mänskliga kroppen kan leda till gulsot, något som är mycket vanligt under de första dagarna efter födelsen (neonatal gulsot). Fototerapi används rutinmässigt som säker behandlingsmetod, under vilken bilirubin genomgår en fotoreaktion till en isomer som kan utsöndras. Den mest effektiva fotoreaktionen är en Z-Eisomerisation, vilken leder till lösligare fotoprodukter. Arbetet som presenteras i denna avhandling visar resultaten av en kombinerad femtosekund optisk-spektroskopisk och kvantmekanisk undersökning av mekanismen bakom bilirubins isomerisation. Den spektroskopiska studien genomfördes med bilirubin, löst i organiska lösningsmedel och i buffert i komplex med humant serumalbumin. Detta albuminkomplex finns i blodet, och är därför av medicinskt intresse. Kvantmekanistiska CASSCFberäkningar på en bilirubinmodell användes för att förklara de experimentella resultaten. Det uppmätta fluorescence sönderfallet visar ultrasnabba komponenter (~120 fs). Dessa tolkas som excitonlokalisering, som följs av bildandet av ett vridet intermediat med en hastighetskonstant på ca. 1 ps-1(beroende på lösningsmedlet). Absorptionsmätningar visar att detta intermediat sönderfaller tillbaka till grundtillståndet med en livstid på 10-15 ps. CASSCF beräkningar, i kombination med de experimentella resultaten, tyder på att sönderfallet med livslängden på ca. 1 ps är en relaxation till det vridna S1-tillståndet. Reaktionsvägen därifrån antas passera en barriär till en konisk genomskärning, som möjliggör snabb relaxation till grundtillståndet. Tidsberoende DFT-beräkningar användes för att analysera bilirubins absorptionsspektrum, vilket gav bra överensstämmelse med uppmätta data. Dessutom hittades ett tillstånd med låg excitationsenergi, som kräver ytterligare studier. Med hjälp av det beräknade CD-spectret kunde det visas att bilirubin binder till albumin i P-formen vid neutralt pH.

Bilirubin

Phototherapy

Neonatal Jaundice

Femtosecond Spectroscopy

CASSCF

TD-DFT

Isomerisation Dynamics

Biophysical chemistry

Biofysikalisk kemi

Membrane mediated aggregation of amyloid-β protein : a potential key event in Alzheimer's disease

Bokvist, Marcus

January 2007

The pathogenesis of Alzheimer’s disease (AD), the most common senile dementia, is a complex process. A crucial event in AD is the aggregation of amyloid-β protein (Aβ), a cleavage product from the Amyloid Precursor Protein (APP). Aβ40, a common component in amyloid plaques found in patients, aggregates in vitro at concentrations, much higher than the one found in vivo. But in the presence of charged lipid membranes, aggregations occurs at much lower concentration in vitro compared to the membrane-free case. This can be understood due to the ability of Aβ to get electrostatically attracted to target membranes with a pronounced surface potential. This electrostatically driven process accumulates peptide at the membrane surface at concentrations high enough for aggregation while the bulk concentration still remains below threshold. Here, we elucidated the molecular nature of this Aβ-membrane process and its consequences for Aβ misfolding by Circular Dichroism Spectroscopy, Differential Scanning Calorimetry and Nuclear Magnetic Resonance Spectroscopy. First, we revealed by NMR that Aβ40 peptide does indeed interact electrostatically with membranes of negative and positive surface potential. Surprisingly, it even binds to nominal neutral membranes if these contain lipids of opposite charge. Combined NMR and CD studies also revealed that the peptide might be shielded from aggregation when incorporated into the membrane. Moreover, CD studies of Aβ40 added to charged membranes showed that both positively and negatively membranes induce aggregation albeit at different kinetics and finally that macromolecular crowding can both speed up and slow down aggregation of Aβ.

Alzheimer’s Disease

Aβ40

Circular Dichroism

NMR

Amyloids

Crowding

Peptide-Lipid Interaction

Biophysical chemistry

Biofysikalisk kemi

On the mechanism of Urea-induced protein denaturation

Lindgren, Matteus

January 2010

It is well known that folded proteins in water are destabilized by the addition of urea. When a protein loses its ability to perform its biological activity due to a change in its structure, it is said to denaturate. The mechanism by which urea denatures proteins has been thoroughly studied in the past but no proposed mechanism has yet been widely accepted. The topic of this thesis is the study of the mechanism of urea-induced protein denaturation, by means of Molecular Dynamics (MD) computer simulations and Nuclear Magnetic Resonance (NMR) spectroscopy. Paper I takes a thermodynamic approach to the analysis of protein – urea solution MD simulations. It is shown that the protein – solvent interaction energies decrease significantly upon the addition of urea. This is the result of a decrease in the Lennard-Jones energies, which is the MD simulation equivalent to van der Waals interactions. This effect will favor the unfolded protein state due to its higher number of protein - solvent contacts. In Paper II, we show that a combination of NMR spin relaxation experiments and MD simulations can successfully be used to study urea in the protein solvation shell. The urea molecule was found to be dynamic, which indicates that no specific binding sites exist. In contrast to the thermodynamic approach in Paper I, in Paper III we utilize MD simulations to analyze the affect of urea on the kinetics of local processes in proteins. Urea is found to passively unfold proteins by decreasing the refolding rate of local parts of the protein that have unfolded by thermal fluctuations. Based upon the results of Paper I – III and previous studies in the field, I propose a mechanism in which urea denatures proteins mainly by an enthalpic driving force due to attractive van der Waals interactions. Urea interacts favorably with all the different parts of the protein. The greater solvent accessibility of the unfolded protein is ultimately the factor that causes unfolded protein structures to be favored in concentrated urea solutions.

Chemical denaturation

Protein unfolding

urea

MD simulations

NMR spectroscopy

Biophysical chemistry

Biofysikalisk kemi

NMR studies of protein dynamics and structure

Ådén, Jörgen

January 2010

Enzymes are extraordinary molecules that can accelerate chemical reactions by several orders of magnitude. With recent advancements in structural biology together with classical enzymology the mechanism of many enzymes has become understood at the molecular level. During the last ten years significant efforts have been invested to understand the structure and dynamics of the actual catalyst (i. e. the enzyme). There has been a tremendous development in NMR spectroscopy (both hardware and pulse programs) that have enabled detailed studies of protein dynamics. In many cases there exists a strong coupling between enzyme dynamics and function. Here I have studied the conformational dynamics and thermodynamics of three model systems: adenylate kinase (Adk), Peroxiredoxin Q (PrxQ) and the structural protein S16. By developing a novel chemical shift-based method we show that Adk binds its two substrates AMP and ATP with an extraordinarily dynamic mechanism. For both substrate-saturated states the nucleotide-binding subdomains exchange between open and closed states, with the populations of these states being approximately equal. This finding contrasts with the traditional view of enzyme-substrate complexes as static low entropy states. We are also able to show that the individual subdomains in Adk fold and unfold in a non-cooperative manner. This finding is relevant from a functional perspective, since it allows a change in hydrogen bonding pattern upon substrate-binding without provoking global unfolding of the entire enzyme (as would be expected from a two-state folding mechanism). We also studied the structure and dynamics of the plant enzyme PrxQ in both reduced and oxidized states. Experimentally validated structural models were generated for both oxidation states. The reduced state displays unprecedented μs-ms conformational dynamics and we propose that this dynamics reflects local and functional unfolding of an α-helix in the active site. Finally, we solved the structure of S16 from Aquifex aeolicus and propose a model suggesting a link between thermostability and structure for a mesophilic and hyperthermophilic protein pair. A connection between the increased thermostability in the thermophilic S16 and residual structure in its unfolded state was discovered, persistent at high denaturant concentrations, thereby affecting the difference in heat capacity difference between the folded and unfolded state. In summary, we have contributed to the understanding of protein dynamics and to the coupling between dynamics and catalytic activity in enzymes.

NMR

protein dynamics

relaxation

protein folding

Biochemistry

Biokemi

Biophysical chemistry

Biofysikalisk kemi

Molecular aspects of biomolecule structure and function

Rodger, Alison

January 2002

All biological processes are fundamentally inter-molecular interactions. In order to understand, and hence control, biomolecular structure and function, methods are required that probe biological systems at the molecular level, ideally with those molecules being in their native environment. The research summarized herein has at its core the development and application of ultra violet (UV)-visible spectrophotometric techniquies for this prupose, in particular circular dichrosim (CD) and linear dichrosim (LD) but also absorbance, fluorescence and resonance light scattering. The spectroscopy is complemented by fundamental theoretical work on molecular structure and reactivity that forms the basis for designing molecules to bind to biomolecules for a particular structural or functional effect. A brief summary of the contributions of the listed publications to our understanding of 'Molecular aspects of biololecule structure and function' is given below under five headings: Circular dichroism theory Molecular geometry and reactivity Small molecule-macromolecule interactions: spectroscopic probes of inter-molecular geometries Molecular design for nucleic acid structure and control Spectroscopic probes of biomolecule structure: instrumentation and application In general terms these correspond to successive phases of the research programme, however, all areas have been present since the first publications in 1983 and can be traced weaving through all subsequent activity.

Molecular mechanisms of protein self-assembly and aggregation

Bellaiche, Mathias Moussine Jacques

January 2018

In this thesis, we investigate the mechanisms driving the self-assembly of peptides and proteins using computational and theoretical tools, always validating our results with experimental measures when possible. In the first part, Chapters 2-5, we focus on the Aβ system, a peptide whose aggregation is intimately linked with the development of Alzheimer's Disease. We begin by simulating the major alloforms of the peptide, Aβ_40 and Aβ_42, demonstrating that the two populate similar disordered ensembles and matching experimental data. Next we investigate how disordered Aβ_42 monomers interact with each other, finding that oligomerisation into amorphous aggregates is driven largely by hydrophobic, non-specific forces. We then move on to probing the aggregation of Aβ_42 into amyloid structures using a native-centric coarse-grained model, and explain the results with a novel Markov state analysis from which we are able to extract structural, kinetic and thermodynamic information on elongation reactions. Finally, we probe the interactions of Aβ_42 monomers with Aβ_42 fibrillar surfaces using a specially designed enhanced sampling scheme, which allows us to obtain enthalpy-driven binding thermodynamics consistent with experiments and to propose major polar binding modes. In the second part of the thesis, Chapters 6 and 7, we model the aggregation of two other self-assembling systems, viruses and a truncated form of the molecular chaperone Hsp70. We first develop a data analysis platform to extract information on the microscopic mechanisms of viral capsid self-assembly from experimental data, synthesising the results from several different systems to draw general evolutionary conclusions about the assembly mechanism. Finally, we model the oligomerisation of Hsp70 thermodynamically and kinetically, showing that its self-assembly is a highly cooperative reaction that is under strong structural constraints.

Thermodynamics and Kinetics of Ligand Photodissociation in Heme Proteins and Formation of DNA i-Motif

Butcher, David S

01 March 2017

Heme proteins carry out a diverse array of functions in vivo while maintaining a well-conserved 3-over-3 α-helical structure. Human hemoglobin (Hb) is well-known for its oxygen transport function. Type 1 non-symbiotic hemoglobins (nsHb1) in plants and bacterial flavohemoglobins (fHb) from a variety of bacterial species have been predicted to carry out a nitric oxide dioxygenase function. In nsHb1 and fHb this function has been linked to protection from nitrosative stress. Herein, I combine photoacoustic calorimetry (PAC), transient absorption spectroscopy (TA), and classical molecular dynamics (cMD) simulations to characterize molecular mechanism of diatomic ligand interactions with a hexa-coordinate globin from plant (rice hemoglobin), bacterial flavohemoglobins and human hemoglobin. In rice type 1 non-symbiotic hemoglobin (rHb1), the dynamics and energetics of structural changes associated with ligand photodissociation is strongly impacted by solvent and temperature, namely CO escape from the protein matrix is slower at pH = 6.0 compare to neutral pH (ns) due to the CD loop reorganization which forms a pathway for ligand escape. In human hemoglobin, exogenous allosteric effectors modulate energetics of conformational changes associated with the CO and O2 escape although the effectors impact on rate constants for ligand association is small. The conformational dynamics associated with ligand photorelease from fHbs from Cupriavidus necator (FHP) and Staphylococcus aureus (HMPSa) are strongly modulated by the presence of azole drugs indicating that drug association modulates structural properties of the heme binding pocket. In addition, we carried out a study of the formation of the DNA intercalated motif (i-motif). The formation of the structure is strongly favored at acidic pH; therefore, PAC was combined with a 2-nitrobenzaldehyde pH-jump to probe formation of the i-motif on fast timescales. i-Motif folding is two-step process with the initial protonation of cytosine residues being endothermic with ΔHfast=8.5 ± 7.0 kcal mol-1 and ΔVfast=10.4 ± 1.6 mL mol-1 and subsequent nucleation/i-motif folding (τ = 140 ns) with ΔHslow=-51.5 ± 4.8 kcal mol-1 and ΔVslow=-6.6 ± 0.9 mL mol-1. The above results indicate that PAC can be employed to study diverse biochemical reactions such as DNA folding, drug binding and ligand photorelease from proteins.

heme

heme protein

hemoglobin

photoacoustic

photoacoustic calorimetry

biophysical chemistry

i-motif

flavohemoglobin

non-symbiotic

Biochemistry

Biophysics