UNDERSTANDING INHIBITION OF A BIODESULFURIZATION ENZYME TO IMPROVE SULFUR REMOVAL FROM PETROLEUM

Yu, Yue

01 January 2018

The biodesulfurization 4S-pathway is a promising complementary enzymatic approach to remove sulfur from recalcitrant thiophenic derivatives in petroleum products that remain from conventional hydrodesulfurization method without diminishing the calorific value of oil. The final step of this pathway involves the carbon-sulfur bond cleavage from HBPS, and the production of the final products 2-hydroxybiphenyl (HBP) and sulfite, has been recognized as the rate-limiting step, partially as a result of product inhibition. However, the mechanisms and factors responsible for product inhibition in the last step have not been fully understood. In this work, we proposed a computational investigation using molecular dynamic simulations and free energy calculations on 2’-hydroxybiphenyl-2-sulfinate (HBPS) desulfinase (DszB) with different bound ligands as well as different solvent conditions to develop a fundamental understanding of the molecular-level mechanism responsible for product inhibition. Based on available crystal structures of DszB and biochemical characterization, we proposed a “gate” area close to substrate binding site of DszB is responsible for ligand egress and plays a role in product inhibition. We have conducted biphasic molecular dynamic simulations to evaluate the proposed gate area functionality. Non-bonded interaction energy analysis shows that hydrophobic residues around the gate area produce van der Waals interactions inhibiting translocation through the gate channel, and therefore, the molecules are easily trapped inside the binding site. Umbrella sampling molecular dynamics was performed to obtain the energy penalty associated with gate conformational change from open to close, which was 2.4 kcal/mol independent of solvent conditions as well as bound ligands. Free energy perturbation calculations were conducted for a group of six selected molecules bound to DszB. The selections were based on functional group representation and to calculate binding free energies that were directly comparable to experimental inhibition constants, KI. Our work provides a fundamental molecular-level analysis on product inhibition for the biodesulfurization 4S-pathway.

Oil-refinery

Product Inhibition

Competitive Inhibition

Free Energy

Molecular Dynamic

Biochemical and Biomolecular Engineering

Petroleum Engineering

Thermodynamics

Separate Hydrolysis and Fermentation of Pretreated Spruce

Axelsson, Josefin

January 2011

Bioethanol from lignocellulose is expected to be the most likely fuel alternative in the near future. SEKAB E-Technology in Örnsköldsvik, Sweden develops the technology of the 2nd generation ethanol production; to produce ethanol from lignocellulosic raw material. The objective of this master’s thesis was to achieve a better knowledge of the potential and limitations of separate hydrolysis and fermentation (SHF) as a process concept for the 2nd generation ethanol production. The effects of enzyme concentration, temperature and pH on the glucose concentration in the enzymatic hydrolysis were investigated for pretreated spruce at 10% DM using a multiple factor design. Enzyme concentration and temperature showed significant effects on the glucose concentration, while pH had no significant effect on the concentration in the tested interval of pH 4.5-5.5. To obtain the maximum glucose concentration (46.4 g/l) for a residence time of 48 h, the optimal settings within the studied parameter window are a temperature of 45.7⁰C and enzyme concentration of 15 FPU/g substrate. However, a higher enzyme concentration would probably further increase the glucose concentration. If enzymatic hydrolysis should be performed for very short residence times, e.g. 6 h, the temperature should be 48.1⁰C to obtain maximum glucose concentration. The efficiency of the enzymes was inhibited when additional glucose was supplied to the slurry prior to enzymatic hydrolysis. It could be concluded that end product inhibition by glucose occurs and results in a distinct decrease in glucose conversion. No clear conclusions could be drawn according to different techniques for slurry and enzymes, i.e. batch and fed-batch, in the enzymatic hydrolysis process. Investigations of the fermentability of the hydrolysate revealed that the fermentation step in SHF is problematic. Inhibition of the yeast decrease the fermentation efficiency and it is therefore difficult to achieve the 4% ethanol limit. Residence time for enzymatic hydrolysis (48 h) and fermentation (24 h) need to be prolonged to achieve a sufficient SHF process. However, short processing times are a key parameter to an economically viable industrial process and to prolong the residence times should therefore not be seen as a desirable alternative. SHF as a process alternative in an industrial bioethanol plant has both potential and limitations. The main advantage is the possibility to separately optimize the process steps, especially to be able to run the enzymatic hydrolysis at an optimal temperature. Although, it is important to include all the process steps in the optimization work. The fermentation difficulties together with the end product inhibition are two limitations of the SHF process that have to be improved before SHF is a preferable alternative in a large scale bioethanol plant.

lignocellulosic ethanol

softwood

SHF

enzymatic hydrolysis

cellulases

end product inhibition

Bioengineering

Bioteknik

Crystallographic determination of wild type, mutant and substrate-analogue inhibited structures of bacterial members of a family of superoxide dismutases : submitted as part of the requirements for the degree of Doctor of Philosophy, Institute of Fundamental Sciences, Chemistry, Massey University, New Zealand

Oakley, Simon Hardie

January 2009

The iron and manganese superoxide dismutases are a family of metallo-enzymes with highly conserved protein folds, active sites and dimer interfaces. They catalyse the elimination of the cytotoxic free radical superoxide to molecular oxygen and hydrogen peroxide by alternate reduction then oxidation of the activesite with the concomitant transfer of protons from the solvent. There are many key aspects of enzymatic function that lack a structural explanation. The focus of this study is on three crystal structures. The iron-substituted manganese superoxide dismutase from Escherichia coli complexed with azide, a substrate-mimicking inhibitor, was solved to 2.2 Å. This “wrong” metal form shows a binding pattern seen previously in the manganese superoxide dismutase from Thermus thermophilus. Wild-type manganese specific superoxide dismutase from the extremophile Deinococcus radiodurans was solved to 2.0 Å and has an active site reminiscent of other solved manganese superoxide dismutases despite a lack of product inhibition. The azide-inhibited manganese superoxide dismutase from Deinococcus radiodurans was determined to a resolution of 2.0 Å and showed binding of azide, and by inference superoxide, different to that seen in Thermus thermophilus, but reminiscent of that seen in azide-inhibited iron superoxide dismutases. These results indicate that the azide ion, and by inference superoxide, bind to the metal centre of manganese superoxide dismutases in two modes, and transition between the two modes may be entropy dependent. These structures, integrated with knowledge from other structures, known biochemistry and various spectra, provide insight into catalytic function. An outer-sphere mechanism of proton transfer that does not rely on through-peptide proton uptake is proposed and compared to a previously proposed inner-sphere mechanism. This is based on the observation that a water molecule moves into the active site of the manganese superoxide dismutase from Deinococcus radiodurans upon azide binding, providing a Grötthus pathway for rapid proton transfer to the active site from the bulk solvent. Also presented in this study are the partially refined structures of four point mutants (S82T, L83M, L133V, and M164L/L166V) of the manganese superoxide dismutase from Escherichia coli all solved to roughly 2 Å resolution, designed to investigate product inhibition which varies across species.

crystal structures

azide

catalytic function

product inhibition

Templatgesteuerte Reaktionen von Peptidnukleinsäuren

Roloff, Alexander

28 May 2014

Reaktionen zwischen reaktiven Oligonukleotiden, die durch komplementäre Nukleinsäuretemplate in hoher effektiver Molarität angeordnet werden, haben auf dem Gebiet der Nukleinsäurediagnostik an Bedeutung gewonnen. Sie bieten die Möglichkeit zur Erzeugung von mehreren Signalmolekülen pro Templat, wenn die templatgebundenen Produkte durch neue Reaktanden verdrängt werden. Da die Produkte ebenfalls hohe Templataffinitäten aufweisen, schränken sie jedoch die katalytische Templataktivität ein (Produktinhibierung). In der vorliegenden Arbeit wurde zunächst ein neuer Ansatz zur Umgehung der Produktinhibierung entwickelt. Dazu wurde eine DNA-vermittelte PNA-Verknüpfungsreaktion in eine PCR integriert. Die Reaktion wurde direkt durch das während der PCR vervielfältigte Templat ausgelöst und erfolgreich in der einzelbasenspezifischen Genotypisierung von genomischer DNA eingesetzt. Die Nachweisgrenze war mit 30 Templatmolekülen im Vergleich zu bisherigen templatgesteuerten Reaktionen um etliche Größenordnungen niedriger. Ein alternativer Ansatz widmete sich neuen Strategien zur Verminderung der Produktinhibierung. Templatgesteuerte Verknüpfungs-Zyklisierungsreaktionen lieferten zyklische Verknüpfungsprodukte, welche gegenüber ihren linearen Pendants durch deutlich geringere Templataffinitäten gekennzeichnet waren. Daher überstiegen die Ausbeuten jene von Verknüpfungsreaktionen ohne Zyklisierung. Die Zunahme der Templataffinität in Folge der Verknüpfung wurde jedoch durch die Zyklisierung nicht vollständig kompensiert. Daher wurden templatgesteuerte Transferreakionen entwickelt, bei denen das DNA-Templat die Zyklisierung von nicht verknüpften Reaktionsprodukten steuert. Diese waren durch geringere Templataffinitäten als die linearen Reaktanden gekennzeichnet. Die Transfer-Zyklisierungsreaktionen lieferten bei fortgeschrittener Reaktion höhere Ausbeuten als Transferreaktionen ohne Zyklisierungsschritt. Dies bestätigte die erfolgreiche Verminderung der Produktinhibierung. / Reactions between reactive oligonucleotides that are aligned by complementary nucleic acid templates at high effective molarities have gained considerable attention in the field of nucleic acid diagnostics. They are capable of generating multiple signaling molecules per target, if the template-bound products are replaced by fresh reactants. However, since product molecules usually exhibit high template affinities, they impede the catalytic activity of the template (product inhibition). This work initially describes the development of a new approach that bypasses product inhibiton. To this end, a DNA-mediated PNA-ligation reaction was integrated in a PCR. The reaction was directly triggered by the template which was amplified during PCR. Furthermore, the reaction was successfully applied in single base-specific genotyping of genomic DNA. The limit of detection (30 template molecules) was several magnitudes lower compared to previous template-controlled reactions. In an alternative approach, new strategies to reduce product inhibition were developed. Template-mediated ligation-cyclization (“cycligation”) reactions generated cyclic ligation products that were characterized by significantly lower template affinities compared to their linear counterparts. The yields upon cycligation were higher than those from ligation reactions without cyclization. However, the increase in template affinity gained upon ligation of the reactants could not be completely compensated through product cyclization. Therefore, template-mediated transfer reactions were designed in which the DNA-template actuates the cyclization of non-ligated products. These were characterized by reduced template affinities compared to the linear reactants. The transfer-cyclization reactions produced higher yields than transfer reactions without a cyclization step, thereby confirming the successful reduction of product inhibition.

DNA-Templat

native chemische Verknüpfung

Peptidnukleinsäuren

Produktinhibierung

Zyklisierung

native chemical ligation

cyclization

DNA template

peptide nucleic acids

product inhibition

540 Chemie

30 Chemie

VK 8577

ddc:540

Structure-Function Studies of Enzymes from Ribose Metabolism

Andersson, C. Evalena

January 2004

<p>In the pentose phosphate pathway, carbohydrates such as glucose and ribose are degraded with production of reductive power and energy. Another important function is to produce essential pentoses, such as ribose 5-phosphate, which later can be used in biosynthesis of nucleic acids and cofactors. </p><p>This thesis presents structural and functional studies on three enzymes involved in ribose metabolism in <i>Escherichia coli</i>. </p><p>Ribokinase is an enzyme that phosphorylates ribose in the presence of ATP and magnesium, as the first step of exogenous ribose metabolism. Two important aspects of ribokinase function, not previously known, have been elucidated. Ribokinase was shown to be activated by monovalent cations, specifically potassium. Structural analysis of the monovalent ion binding site indicates that the ion has a structural rather than catalytic role; a mode of activation involving a conformational change has been suggested. Product inhibition studies suggest that ATP is the first substrate to bind the enzyme. Independent K_d measurements with the ATP analogue AMP-PCP support this. The results presented here will have implications for several enzymes in the protein family to which ribokinase belongs, in particular the medically interesting enzyme adenosine kinase. </p><p>Ribose 5-phosphate isomerases convert ribose 5-phosphate into ribulose 5-phosphate or <i>vice versa</i>. Structural studies on the two genetically distinct isomerases in <i>E. coli</i> have shown them to be fundamentally different in many aspects, including active site architecture. However, a kinetic study has demonstrated both enzymes to be efficient in terms of catalysis. Sequence searches of completed genomes show ribose 5-phosphate isomerase B to be the sole isomerase in many bacteria, although ribose 5-phosphate isomerase A is a nearly universal enzyme. All genomes contain at least one of the two enzymes. These results confirm that both enzymes must be independently capable of supporting ribose metabolism, a fact that had not previously been established.</p>

Molecular biology

activation

isomerase

kinase

potassium

product inhibition

ribose

ribose 5-phosphate

x-ray crystallography

enzyme kinetics

fluorescence spectroscopy

protein structure

Molekylärbiologi

Molecular biology

Molekylärbiologi

Structure-Function Studies of Enzymes from Ribose Metabolism

Andersson, C. Evalena

January 2004

In the pentose phosphate pathway, carbohydrates such as glucose and ribose are degraded with production of reductive power and energy. Another important function is to produce essential pentoses, such as ribose 5-phosphate, which later can be used in biosynthesis of nucleic acids and cofactors. This thesis presents structural and functional studies on three enzymes involved in ribose metabolism in Escherichia coli. Ribokinase is an enzyme that phosphorylates ribose in the presence of ATP and magnesium, as the first step of exogenous ribose metabolism. Two important aspects of ribokinase function, not previously known, have been elucidated. Ribokinase was shown to be activated by monovalent cations, specifically potassium. Structural analysis of the monovalent ion binding site indicates that the ion has a structural rather than catalytic role; a mode of activation involving a conformational change has been suggested. Product inhibition studies suggest that ATP is the first substrate to bind the enzyme. Independent Kd measurements with the ATP analogue AMP-PCP support this. The results presented here will have implications for several enzymes in the protein family to which ribokinase belongs, in particular the medically interesting enzyme adenosine kinase. Ribose 5-phosphate isomerases convert ribose 5-phosphate into ribulose 5-phosphate or vice versa. Structural studies on the two genetically distinct isomerases in E. coli have shown them to be fundamentally different in many aspects, including active site architecture. However, a kinetic study has demonstrated both enzymes to be efficient in terms of catalysis. Sequence searches of completed genomes show ribose 5-phosphate isomerase B to be the sole isomerase in many bacteria, although ribose 5-phosphate isomerase A is a nearly universal enzyme. All genomes contain at least one of the two enzymes. These results confirm that both enzymes must be independently capable of supporting ribose metabolism, a fact that had not previously been established.

Molecular biology

activation

isomerase

kinase

potassium

product inhibition

ribose

ribose 5-phosphate

x-ray crystallography

enzyme kinetics

fluorescence spectroscopy

protein structure

Molekylärbiologi

Molecular biology

Molekylärbiologi