Folding mechanism of Glutaredoxin 2

Gildenhuys, Samantha

19 May 2008

ABSTRACT Equilibrium unfolding, single- and double-jump kinetic studies were conducted to determine the unfolding and refolding pathway of glutaredoxin 2. Structural changes for wild-type glutaredoxin 2 were monitored by far-ultraviolet circular dichroism and intrinsic tryptophan fluorescence for equilibrium unfolding and intrinsic tryptophan fluorescence for single- and double-jump kinetics studies. Glutaredoxin 2 possesses two tryptophan residues in domain 2. In order to monitor changes in domain 1, cysteine 9 at the active site cysteines, situated in domain 1, was labelled with an extrinsic fluorophore, AEDANS, and a mutant was created (Y58W glutaredoxin 2). The AEDANS labelled protein displayed decreased alpha-helical secondary structure and conformational stability. A high degree of cooperativity and similar conformational stability was observed during the two-state transition of the urea-induced equilibrium unfolding of both the wild-type and Y58W glutaredoxin 2 proteins therefore Y58W glutaredoxin 2 could be used to assess structural changes in the local environment of domain 1 during unfolding and refolding. Two phases of unfolding, the fast and slow phase, occurred for both the wild-type and Y58W proteins. The slow phase involves structural rearrangements that expose small amounts of surface area while the fast phase represents gross structural unfolding exposing large amounts of surface area. The isomerization of the Val48-Pro49 peptide bond to the trans conformation occurs during the slow phase and this isomerization is coupled to conformational unfolding of the protein. The structural separation of these phases could be represented by two structural units (unit x and unit y), these units do not represent domain 1 and 2. The units could also result in parallel refolding pathways with the folding of the x unit involving the fast and slow refolding phases and the folding of the y unit of structure is represented by the medium phase of refolding. The fast and slow phases are further separated as the fast phase represents the gross structural folding of glutaredoxin 2 for species with the Val48-Pro49 peptide bond in the native cis conformation. The development of the slow phase after extended unfolding delay periods during double-jump refolding studies, as well as the acceleration of the rate of the phase by the peptidyl prolyl isomerase hFKBP-12 proved that the phase involves a proline peptide bond iv isomerization. This phase represents a slow isomerization coupled with conformational folding similar to the slow unfolding phase. Complex unfolding and refolding kinetics indicated the involvement of kinetic intermediates during (un)folding.

protein folding

Thioredoxin

Glutathione-S-transferases

Glutaredoxin 2

cis-trans Isomerization

Responsive Azobenzene-Containing Polymers and Gels

Deshmukh, Smeet, Bromberg, Lev, Hatton, T. Alan

01 1900

The photoviscosity effect in aqueous solutions of novel poly(4-methacryloyloxyazobenzene-co-N,N-dimethyl acrylamide) (MOAB-DMA) was demonstrated. The observed significant reduction in the zero-shear viscosity upon UV-irradiation of MOAB-DMA aqueous solutions was due to the dissociation of the interchain azobenzene aggregates. Such phenomena can be advantageously used in photoswitchable fluidic devices and in protein separation. Introduction of enzymatically degradable azo cross-links into Pluronic-PAA microgels allowed for control of swelling due to degradation of the cross-links by azoreductases from the rat intestinal cecum. Dynamic changes in the cross-link density of stimuli-responsive microgels enable novel opportunities for the control of gel swelling, of importance for drug delivery and microgel sensoric applications. / Singapore-MIT Alliance (SMA)

Responsive gels

trans-4-methacryloyloxy azobenzene

4,4’-di(methacryloylamino) azobenzene

cis-trans transitions

UV irradiation

Controlling Factors of Cis/Trans Geometry in Ni and Co Diketonato Complexes

Weng, Tzu-Yu

03 September 2003

Metal diketonato complexes are populate in recent ten years, because of diketone compound is easy to get and cheap and also have good volatility to be the precursor of MOCVD, they usually can be the materials of wafer processing by high technology electronics industries. Many scientists are trying to synthesis these diketonato complexes, and find out the better reactivity compounds to be the precursor of MOCVD. In order to knowing the decompose activities of these complexes, we are trying to compare the metal-oxygen bonds of these diketonato complexes in this paper. By the way, these diketonato complexes have difference geometry in cis and trans form, and also have conformation isomers between syn and anti form. We will compare and discuss the structures and controlling factors in these kinds of diketonato complexes in this paper.

Metal diketonato complexes

Cis/Trans Geometry

Metal Organic Chemical Vapor Deposition

MOCVD

Structure and function relationship among the peptidyl prolyl cis/trans isomerases

Chaturvedi, Vandana,

January 2007

Thesis (Ph.D.)--Mississippi State University. Department of Biological Sciences. / Title from title screen. Includes bibliographical references.

Expression von Peptidyl-prolyl cis/trans isomerase NIMA-interacting 1 (PIN1) in Blasten von Patienten mit akuter myeloischer Leukämie / Expression of peptidyl-prolyl cis/trans isomerase NIMA-interacting 1 (PIN1) in blasts of patients with acute myeloid leukemia

Hangen, Hanne

05 July 2011

No description available.

610 Medizin, Gesundheit

Medicine

AML

Leukämie

Akute Myeloische Leukämie

Pin1

Cis-Trans-Isomerase

Peptidyl-prolyl Isomerase

Konformationsänderung

AML

acute myeloid leukemia

Pin1

Cis-Trans-Isomerase

Peptidyl-prolyl-Isomerase

conformational change

postphosphorylation regulation

44.81

44.86

MED 424: Onkologie

MED 417: Hämatologie

Computational Perspective on Intricacies of Interactions, Enzyme Dynamics and Solvent Effects in the Catalytic Action of Cyclophilin A

Tork Ladani, Safieh

11 May 2015

Cyclophilin A (CypA) is the well-studied member of a group of ubiquitous and evolutionarily conserved families of enzymes called peptidyl–prolyl isomerases (PPIases). These enzymes catalyze the cis-trans isomerization of peptidyl-prolyl bond in many proteins. The distinctive functional path triggered by each isomeric state of peptidyl-prolyl bond renders PPIase-catalyzed isomerization a molecular switching mechanism to be used on physiological demand. PPIase activity has been implicated in protein folding, signal transduction, and ion channel gating as well as pathological condition such as cancer, Alzheimer’s, and microbial infections. The more than five order of magnitude speed-up in the rate of peptidyl–prolyl cis–trans isomerization by CypA has been the target of intense research. Normal and accelerated molecular dynamic simulations were carried out to understand the catalytic mechanism of CypA in atomistic details. The results reaffirm transition state stabilization as the main factor in the astonishing enhancement in isomerization rate by enzyme. The ensuing intramolecular polarization, as a result of the loss of pseudo double bond character of the peptide bond at the transition state, was shown to contribute only about −1.0 kcal/mol to stabilizing the transition state. This relatively small contribution demonstrates that routinely used fixed charge classical force fields can reasonably describe these types of biological systems. The computational studies also revealed that the undemanding exchange of the free substrate between β- and α-helical regions is lost in the active site of the enzyme, where it is mainly in the β-region. The resultant relative change in conformational entropy favorably contributes to the free energy of stabilizing the transition state by CypA. The isomerization kinetics is strongly coupled to the enzyme motions while the chemical step and enzyme–substrate dynamics are in turn buckled to solvent fluctuations. The chemical step in the active site of the enzyme is therefore not separated from the fluctuations in the solvent. Of special interest is the nature of catalysis in a more realistic crowded environment, for example, the cell. Enzyme motions in such complicated medium are subjected to different viscosities and hydrodynamic properties, which could have implications for allosteric regulation and function.

Cyclophilin A (CypA)

Accelerated molecular dynamics

Cis-trans isomerization

Enzyme dynamics

Solvent effects

Kramers rate theory

Peptidyl-Prolyl-cis-trans-Isomerasen in Streptomyces Lividans Herstellung von Knockout-Mutanten der Cyclophiline A1 und A2 durch homologe Rekombination /

Strube, Katharina.

Unknown Date

Frankfurt (Main), Universiẗat, Diss., 2008. / Erscheinungsjahr an der Haupttitelstelle: 2007.

Coordination chemistry of arylphosphanes:binding and interligand interactions in chromium, molybdenum and tungsten carbonyl complexes

Hirsivaara, L. (Leeni)

14 May 2001

Abstract The first part of this work consisted of a study of the coordination chemistry of aromatic (P,S) and (P,O) heterodonor phosphanes with Cr(CO) 6 , Mo(CO) 6 and W(CO) 6 . The (P,S) donor ligands having one or two o -thiomethoxyphenyl groups, preferred bidentate coordination mode, while the (P,O) donor ligands, having one, two or three o -methoxyphenyls, formed monodentate phosphorus bound complexes. Steric and electronic parameters affecting the coordination chemistry of the phosphanes are discussed for the monodentate complexes. In the second part, triphenylphosphane and 2- and 4-pyridyldiphenylphosphane substituted tungsten tetracarbonyl derivatives was prepared, and attractive intramolecular interactions between the phosphane ligands were studied for both the neutral and the protonated complexes. Hydrogen bonding, π -stacking and cation-π bonding interactions were established, and observed to influence the cis/trans isomerism of the complexes. Cis/trans isomerism could be tuned by protonation, and deprotonation of the pyridyldiphenylphosphane derivatives. All the complexes were characterised by 1 H, 13 C-{ 1 H} and 31 P-{ 1 H} NMR spectroscopy, X-ray crystallography, IR spectroscopy, and either elemental analysis or mass spectroscopy.

<em>cis/trans</em> isomerism

NMR Spectroscopy

heterodonor phosphanes

intramolecular interactions

Evolution of Hybrid Incompatibilities in Gene Regulatory Networks

Tulchinsky, Alexander Y.

01 September 2013

Under the Dobzhansky-Muller model, postzygotic isolation results from incompatibility between interacting genes. Evidence points to regulatory networks as a rich source of incompatibilities that impact hybrid fitness. Pleiotropy is a natural feature of regulatory networks because regulatory elements generally have multiple targets. Both pleiotropy and hybrid incompatibility arise due to genetic interactions; therefore we can expect an intimate association between them. In the following chapters, I investigate the relationship between pleiotropy and hybrid incompatibility in the context of regulatory networks. In chapter one, I extend a general network-based study of hybrid incompatibility by incorporating a sequence-based thermodynamic model of transcriptional regulation. In the absence of pleiotropy, hybrid misregulation of a positively selected trait evolves quickly as a consequence of non-recognition or spurious binding in regulatory interactions across species boundaries. In a conserved trait, hybrid incompatibility evolves much slower as a product of compensatory drift. In chapter two, I show that pleiotropy can promote or constrain the evolution of hybrid incompatibility in a regulatory network depending on its fitness landscape, which emerges from the thermodynamic properties of molecular binding. Pleiotropy may promote hybrid incompatibility in accordance with the "selection, pleiotropy, and compensation model" of evolution, in which compensation for the pleiotropic side-effects of adaptation accelerates incompatibility in conserved traits. Pleiotropy can limit the evolution of hybrid incompatibility by constraining change in trans-acting regulatory elements in favor of adaptation at less pleiotropic downstream cis-regulatory targets. Without change in both interactors, incompatibility does not occur under the Dobzhansky-Muller model. In chapter three, I evaluate the hypothesis that pleiotropy facilitates the onset of hybrid incompatibility under antagonistic coevolution, an ubiquitous and persistent source of natural selection. When infectivity and resistance in a host-parasite system are determined epistatically by network interactions, reciprocal selective pressure results in a genotypic chase. This causes pleiotropic mutations to accumulate and be compensated over time, producing intrinsic hybrid incompatibility in both species independent of local adaptation. Thus, cyclical antagonistic coevolution eventually overcomes constraint on pleiotropic loci, facilitating the evolution of regulatory incompatibilities commonly observed in hybrids.

antagonistic coevolution

cis-trans coevolution

compensatory evolution

parasitism

pleiotropy

speciation

Biology

Genetics

Understanding Hydrogen Bonding in Photoenolization

Scott, Tianeka S.

18 October 2013

No description available.

Chemistry

photoenolization

hydrogen bonding in photoenolization

photoremovable protecting groups

laser flash photolysis

phosphorescence

cis-trans isomerization