A Structural and Mechanistic Study of Two Members of Cupin Family Protein

Liu, Fange

18 June 2013

is a functionally diverse large group of proteins sharing a jelly roll β-barrel fold. An enzymatic member 3-hydroxyanthranilate-3,4-dioxygenase (HAO) and a non-enzymatic member pirin, which is a human nuclear metalloprotein of unknown function present in all human tissues, were selected for structural and functional studies in this dissertation work. HAO is an important enzyme for tryptophan catabolism and for 2-nitrobenzoic acid biodegradation. In this work, seven catalytic intermediate were captured in HAO single crystals, enabling for the first time a nearly complete structural snapshot viewing of the entire molecular oxygen activation and insertion mechanism in an iron- and O2-depedent enzyme. The rapid catalytic turnover rate was found achieved in large part by protein dynamics that facilitates O2 binding to the catalytic iron, which is bound to the enzyme by a facile 2-His-1-carboxylate ligand motif. An iron storage and chaperon mechanism was also discovered in the bacterial source of this enzyme, which led to a proposed novel biological function of a mononuclear iron-sulfur center. Although human pirin protein shares the same structural fold with HAO, its iron ion is coordinated by a 3-His-1-carboxylate ligand motif. Pirin belongs to a subset of proteins whose members are playing regulatory functions in the superfamily. In this work, pirin is shown to act as a redox sensor for the NF-κB transcription factor, a critical mediator of intracellular signaling that has been linked to cellular responses to pro-inflammatory signals which controls the expression of a vast array of genes involved in immune and stress responses.

Metalloprotein

Oxygen activation

Catalytic mechanism

Signaling transduction activation

Regulation of gene transcription

The Nickel-responsive Binding and Regulation of Two Novel Helicobacter pylori NikR–targeted Genes

Ademi, Irsa

11 July 2013

Nickel is an essential transition metal for the virulence and survival of Helicobacter pylori in the acidic human stomach. The nickel– and proton– dependent transcriptional regulator HpNikR is important for maintaining nickel homeostasis inside the cytosol by regulating multiple H. pylori genes. A previous ChIP-sequencing experiment with H. pylori G27 and HpNikR identified two novel genes currently annotated as putative iron-transporters, HpG27_866 and HpG27_1499. In vitro DNA-binding assays with the promoter sequences of the two genes revealed nickel-dependent HpNikR binding with an affinity of ~10-7 M. The recognition site of HpNikR was identified on HpG27_1499 by footprinting assays, which loosely correlates with the HpNikR pseudo-consensus sequence. Furthermore, HpG27_1499 transcription showed nickel-dependent repression in WT H. pylori, and no changes in an isogenic ΔnikR strain. These data suggest that HpG27_1499 could be a nickel importer that is regulated by HpNikR in a nickel-responsive manner.

Helicobacter pylori

nickel

HpNikR

DNaseI footprinting

DNA mobility shift assay

qRT-PCR

transcription factor

metalloprotein

0487

The Nickel-responsive Binding and Regulation of Two Novel Helicobacter pylori NikR–targeted Genes

Ademi, Irsa

11 July 2013

Nickel is an essential transition metal for the virulence and survival of Helicobacter pylori in the acidic human stomach. The nickel– and proton– dependent transcriptional regulator HpNikR is important for maintaining nickel homeostasis inside the cytosol by regulating multiple H. pylori genes. A previous ChIP-sequencing experiment with H. pylori G27 and HpNikR identified two novel genes currently annotated as putative iron-transporters, HpG27_866 and HpG27_1499. In vitro DNA-binding assays with the promoter sequences of the two genes revealed nickel-dependent HpNikR binding with an affinity of ~10-7 M. The recognition site of HpNikR was identified on HpG27_1499 by footprinting assays, which loosely correlates with the HpNikR pseudo-consensus sequence. Furthermore, HpG27_1499 transcription showed nickel-dependent repression in WT H. pylori, and no changes in an isogenic ΔnikR strain. These data suggest that HpG27_1499 could be a nickel importer that is regulated by HpNikR in a nickel-responsive manner.

Helicobacter pylori

nickel

HpNikR

DNaseI footprinting

DNA mobility shift assay

qRT-PCR

transcription factor

metalloprotein

0487

Bottom-Up Design of Synthetic Photoactive Metalloproteins

Fan, Jiufeng

01 December 2009

No description available.

Chemistry

de novo design

metalloprotein

electron transfer

peptide

coiled coil

oligomerization state

Analyses and Applications of Metalloprotein Complexes

Kirberger, Michael Patrick

04 August 2008

The structural characteristics associated with the binding of beneficial metals (i.e. - Mg2+, Zn2+ and Ca2+) to natural proteins has typically received more attention than competitive binding by toxic metals (e.g. – Pb2+, Hg2+, Cd2+, La3+, etc.). In this thesis, a statistical analysis of Pb2+-binding in crystallized protein structures indicates that Pb2+ does not bind preferentially with nitrogen, as generally assumed, but binds predominantly with oxygen, and to a lesser degree, sulfur. A comparison of Ca2+ and Pb2+ indicates that Pb2+ binds with a wider range of coordination numbers, with less formal change, and with less defined structure than Ca2+. The Pb2+ ion also appears to displace Ca2+ with little conformational stress in calcium binding proteins (CaBP’s). Experimental data from the binding of metals with engineered fluorescent proteins indicate that both Pb2+ and Gd3+ will occupy grafted calcium-binding sites with greater affinity than Ca2+, and strong evidence is presented to support the hypothesis that Pb2+ and Gd3+ will bind non-specifically on the protein surface. These results suggest that toxicity is associated with two binding mechanisms: displacement of the metal cofactor which disrupts protein function, and non-specific binding which maintains higher solubility of the metal.

metalloprotein

metal

calcium binding protein

CaBP

enhanced green fluorescent protein

EGFP

Ca2+

Pb2+

Gd3+

database

sequence analysis

prediction

binding geometry

metal toxicity.

Les avancées de la modélisation en biochimie : des méthodes mixtes QM/MM à la métadynamique / Modeling biochemical systems : from QM/MM methods to metadynamics

Gouron, Aurélie

06 October 2014

Les structures cristallographiques de macromolécules comme les protéines, obtenues par la biologie structurale sont des modèles statiques. Or, c'est la flexibilité et la dynamique de ces macromolécules qui sont généralement responsables de leurs fonctions. La simulation permet d'explorer cette flexibilité lors de différents phénomènes qui ont lieu dans ces systèmes : une réaction chimique, des interactions avec une petite molécule… Simuler de tels phénomènes est un défi car la dynamique moléculaire classique ne permet pas de les observer. Des algorithmes permettent d'accélérer l'échantillonnage des dynamiques pour lever cette limitation et de calculer les barrières d'activation pour de tels phénomènes. Simultanément, le choix du niveau de calcul est crucial car il faut concilier la taille importante des systèmes, la nature des interactions et les phénomènes électroniques impliqués. Dans ce travail, différentes méthodes, dont principalement la métadynamique soit au niveau classique ou quantique, ou encore en combinant les deux niveaux quantique/classique, seront utilisées pour modéliser quatre processus complexes : des changements de conformations d'une protéine, des interactions entre métalloprotéine et inhibiteur, des réactions en solution et dans une enzyme. / Crystallographic structures of macromolecules, such as proteins, obtained by structural biology are static models. However, flexibility and dynamics of macromolecules are generally responsible for their functions. Modeling allows us to explore this flexibility in different phenomena that take place in these systems: a chemical reaction, interaction with a small molecule... Modeling such phenomena is a challenge because they cannot be observed by classical molecular dynamics. Algorithms can accelerate sampling of dynamics to simulate these events and calculate their activation barriers. Simultaneously, the choice of the level of calculation is crucial because it must merge with the size of the systems, the nature of interactions and the electronic phenomena involved.In this thesis, some methods, mainly metadynamics at classical level, quantum or the hybrid quantum/classical level, will be used to model four complex processes: conformational changes of proteins, metalloprotein/inhibitor interactions, reactivity in solution and enzymatic reactivity.

Métadynamique

Energie libre

QM/MM

Interaction métalloprotéine/ligand

Réactivité

Metadynamics

Free energy

QM/MM

Conformational changes of proteins

Metalloprotein/ligand interaction

Reactivity

540

Proton pathways in energy conversion : K-pathway analogs in O2- and NO-reductases

Gonska, Nathalie

January 2017

Oxygen and nitric oxide reductases are enzymes found in aerobic and anaerobic respiration, respectively. Both enzyme groups belong to the superfamily of Heme-Copper Oxidases, which is further divided into several subgroups: oxygen-reducing enzymes into A-, B- and C-type and nitric oxide reductases into qNORs and cNORs. Oxygen reducing enzymes use the energy released from oxygen reduction to take up electrons and protons from different sides of the membrane. Additionally, protons are pumped. These processes produce a membrane potential, which is used by the ATP-synthase to produce ATP, the universal energy currency of the cell. Nitric oxide reductases are not known to conserve the energy from nitric oxide reduction, although the reaction is highly exergonic. Here, the detailed mechanism of a B-type oxidase is studied with special interest in an element involved in proton pumping (proton loading site, PLS). The study supports the hypothesis that the PLS is protonated in one and deprotonated in the consecutive step of the oxidative catalytic cycle, and that a proton is pumped during the final oxidation phase. It further strengthens the previous suggestion that the PLS is a cluster instead of a single residue or heme propionate. Additionally, it is proposed that the residue Asp372, which is in vicinity of the heme a3 propionates previously suggested as PLS, is part of this cluster. In another study, we show that the Glu15II at the entry of the proton pathway in the B-type oxidase is the only crucial residue for proton uptake, while Tyr248 is or is close to the internal proton donor responsible for coupling proton pumping to oxygen reduction. The thesis also includes studies on the mechanism and electrogenicity of qNOR. We show that there is a difference in the proton-uptake reaction between qNOR and the non-electrogenic homolog cNOR, hinting at a different reaction mechanism. Further, studies on a qNOR from a different host showed that qNOR is indeed electrogenic. This surprising result opens up new discussions on the evolution of oxygen and nitric oxide reductases, and about how energy conservation can be achieved. / <p>At the time of the doctoral defense, the following paper was unpublished and had a status as follows: Paper 4: Manuscript.</p>

heme-copper oxidase

cytochrome c oxidase

membrane protein

respiration

electron transfer

proton transfer

redox reaction

metalloprotein

non-heme iron

cytochrome ba3

flow-flash

carbon monoxide

liposome

respiratory control ratio

Biochemistry and Molecular Biology

Biokemi och molekylärbiologi

Ultrafast Structural and Electron Dynamics in Soft Matter Exposed to Intense X-ray Pulses

Jönsson, Olof

January 2017

Investigations of soft matter using ultrashort high intensity pulses have been made possible through the advent of X-ray free-electrons lasers. The last decade has seen the development of a new type of protein crystallography where femtosecond dynamics can be studied, and single particle imaging with atomic resolution is on the horizon. The pulses are so intense that any sample quickly turns into a plasma. This thesis studies the ultrafast transition from soft matter to warm dense matter, and the implications for structural determination of proteins.                    We use non-thermal plasma simulations to predict ultrafast structural and electron dynamics. Changes in atomic form factors due to the electronic state, and displacement as a function of temperature, are used to predict Bragg signal intensity in protein nanocrystals. The damage processes started by the pulse will gate the diffracted signal within the pulse duration, suggesting that long pulses are useful to study protein structure. This illustrates diffraction-before-destruction in crystallography. The effect from a varying temporal photon distribution within a pulse is also investigated. A well-defined initial front determines the quality of the diffracted signal. At lower intensities, the temporal shape of the X-ray pulse will affect the overall signal strength; at high intensities the signal level will be strongly dependent on the resolution. Water is routinely used to deliver biological samples into the X-ray beam. Structural dynamics in water exposed to intense X-rays were investigated with simulations and experiments. Using pulses of different duration, we found that non-thermal heating will affect the water structure on a time scale longer than 25 fs but shorter than 75 fs. Modeling suggests that a loss of long-range coordination of the solvation shells accounts for the observed decrease in scattering signal. The feasibility of using X-ray emission from plasma as an indicator for hits in serial diffraction experiments is studied. Specific line emission from sulfur at high X-ray energies is suitable for distinguishing spectral features from proteins, compared to emission from delivery liquids. We find that plasma emission continues long after the femtosecond pulse has ended, suggesting that spectrum-during-destruction could reveal information complementary to diffraction.

Biophysics

Biofysik

Purification, functional characterization and crystallization of the PerR peroxide sensor from Saccharopolyspora erythraea

Elison Kalman, Grim

January 2019

This report summarizes the work on the cloning, expression, and purification of PerR, a metal sensing regulator from Saccharopolyspora erythraea and the subsequent characterization using small angle X-ray scattering and other biochemical methods. The report aims to provide an insight into prokaryotic metal homeostasis, provide a better understanding of how PerR works and provide valuable information for the continued work on the crystallization of PerR.

structural biology

cell culture

protein expression

genetic engineering

spectroscopy

X-ray crystallography

small angle X-ray scattering

SAXS

transcription factor

PerR

metal binding

antibiotics

Saccharopolyspora erythraea

S. erythraea

soil bacterium

actinobacteria

actinomycetes

oxidative stress

peroxide stress

structure determination

characterization

stabilization

peroxide sensor

iron sensor

manganese sensor

metalloprotein

metal ion homeostasis

metal ion

prokaryotic

strukturbiologi

cellodling

proteinuttryck

genteknik

spektroskopi

röntgenkristallografi

småvinkel-röntgenspridning

SAXS

transkriptionsfaktor

PerR

metallbindande

antibiotika

Saccharopolyspora erythraea

S. erythraea

jordartsbakterie

Aktinobakterier

Actinobacteria

Actinomycetes

oxidativ stress

peroxid stress

strukturbestämning

karaktärisering

stabilisering

peroxidsensor

järnsensor

mangansensor

metalljonshomeostas

metalljoner

prokaryot

Structural Biology

Strukturbiologi