Theoretical Modeling of Enzyme Catalysis with Focus on Radical Chemistry

Pelmenschikov, Vladimir

January 2005

Hybrid density functional theory (DFT) B3LYP method is applied to study the four diverse enzyme systems: zinc-containing peptidases (thermolysin and stromelysin), methyl-coenzyme M reductase, ribonucleotide reductases (classes I and III), and superoxide dismutases (Cu,Zn- and Ni-dependent enzymes). Powerfull tools of modern quantum chemistry are used to address the questions of biological pathways at their molecular level, proposing a novel mechanism for methane production by methyl-coenzyme M reductase and providing additional insights into hydrolysis by zinc peptidases, substrate conversion by ribonucleotide reductases, and biological superoxide dismutation. Catalysis by these enzymes, with the exception of zinc peptidases, involves radical chemistry.

density functional theory

enzyme catalysis

radical chemistry

zinc-containing peptidase

methyl-coenzyme M reductase

ribonucleotide reductase

superoxide dismutase

Quantum chemistry

Kvantkemi

Hydrogen Bonds and Electrostatic Environment of Radical Intermediates in Ribonucleotide Reductase Ia

Nick, Thomas Udo

29 June 2015

No description available.

540

ribonucleotide reductase

DNA-Synthesis

PCET

pi-stacking

electron transfer mechanism

high-field EPR

high-field ENDOR

multifrequency

hydrogen-bonding

3-aminotyrosyl radical

unnatural amino acid radicals

protein interface

Chemie  (PPN62138352X)

Un criblage ciblant de nouveaux facteurs impliqués dans l’assemblage mitotique des chromosomes dans le nématode C. elegans

Ranjan, Rajesh

04 1900

La division cellulaire est un processus fondamental des êtres vivants. À chaque division cellulaire, le matériel génétique d'une cellule mère est dupliqué et ségrégé pour produire deux cellules filles identiques; un processus nommé la mitose. Tout d'abord, la cellule doit condenser le matériel génétique pour être en mesure de séparer mécaniquement et également le matériel génétique. Une erreur dans le niveau de compaction ou dans la dynamique de la mitose occasionne une transmission inégale du matériel génétique. Il est suggéré dans la littérature que ces phénomènes pourraient causé la transformation des cellules cancéreuses. Par contre, le mécanisme moléculaire générant la coordination des changements de haut niveau de la condensation des chromosomes est encore incompris. Dans les dernières décennies, plusieurs approches expérimentales ont identifié quelques protéines conservées dans ce processus. Pour déterminer le rôle de ces facteurs dans la compaction des chromosomes, j'ai effectué un criblage par ARNi couplé à de l'imagerie à haute-résolution en temps réel chez l'embryon de C. elegans. Grâce à cette technique, j'ai découvert sept nouvelles protéines requises pour l'assemblage des chromosomes mitotiques, incluant la Ribonucléotide réductase (RNR) et Topoisomérase II (topo-II). Dans cette thèse, je décrirai le rôle structural de topo-II dans l'assemblage des chromosomes mitotiques et ces mécanismes moléculaires. Lors de la condensation des chromosomes, topo-II agit indépendamment comme un facteur d'assemblage local menant par la suite à la formation d'un axe de condensation tout au long du chromosome. Cette localisation est à l'opposé de la position des autres facteurs connus qui sont impliqués dans la condensation des chromosomes. Ceci représente un nouveau mécanisme pour l'assemblage des chromosomes chez C. elegans. De plus, j'ai découvert un rôle non-enzymatique à la protéine RNR lors de l'assemblage des chromosomes. Lors de ce processus, RNR est impliqué dans la stabilité des nucléosomes et alors, permet la compaction de haut niveau de la chromatine. Dans cette thèse, je rapporte également des résultats préliminaires concernant d'autres nouveaux facteurs découverts lors du criblage ARNi. Le plus important est que mon analyse révèle que la déplétion des nouvelles protéines montre des phénotypes distincts, indiquant la fonction de celles-ci lors de l'assemblage des chromosomes. Somme toute, je conclus que les chromosomes en métaphase sont assemblés par trois protéines ayant des activités différentes d'échafaudage: topoisomérase II, les complexes condensines et les protéines centromériques. En conclusion, ces études prouvent le mécanisme moléculaire de certaines protéines qui contribuent à la formation des chromosomes mitotiques. / Cell division is a fundamental process that continuously happens in all living organisms. In each cell division, genetic material of the parent cell duplicates and segregates to produce genetically identical daughter cells in a process called mitosis. Cells need to condense their genetic material to be able to partition them equally. Any subtle defects, either timing or compaction level, could lead to the unequal inheritance of genetic material, a phenomenon that is believed to be the leading cause of cancerous transformation. However, the precise molecular mechanisms underlying the coordinated changes of higher-order chromosome structure are poorly understood. In the last two decades, various approaches have identified several conserved factors required for chromosome condensation. To define the roles of known and novel factors in this process, I performed an RNAi based screen using high-resolution live imaging of the C. elegans one-cell embryo. Importantly, using an in vivo approach, I discovered seven novel factors required for mitotic chromosome assembly, including Ribonulceotide reducatase (RNR) and DNA topoisomerase II (topo-II). In this thesis, I report a structural role for topo-II in mitotic chromosome assembly and underlying molecular mechanisms. During chromosome condensation process, topo-II acts independently as a local assembly factor leading to global chromosome axis formation, contradicting models that chromosomes organize around preassembled scaffolds, thus representing a novel pathway for chromosome assembly in C. elegans. Furthermore, I also discovered a non-enzymatic role of RNR in the mitotic chromosome assembly process. During this process, RNR is involved in nucleosome stability, and thereby, it allows higher-order chromatin assembly. In this thesis, I also report preliminary data for other novel factors that I discovered in the RNAi based screen for factors involved in chromosome condensation. Importantly, my analyses revealed that the depletion of several proteins results in distinct chromosome condensation phenotypes, indicating that they function in discrete events during mitotic chromosome assembly. In sum, I conclude that metaphase chromosomes are built by the distinct scaffolding activities of three proteins: DNA topoisomerase II, condensin complexes and centromere proteins. Taken together, these studies provide underlying molecular mechanisms contributing to the mitotic chromosome formation.

Division Cellulaire

Condensation des Chromosomes

Ribonucléotide Réductase (RNR)

Topoisomérase II (topo-II)

Cell Division

Chromosome Condensation

Topoisomerase II (topo-II)

Ribonucleotide Reductase (RNR)

Functional Genetic Analysis Reveals Intricate Roles of Conserved X-box Elements in Yeast Transcriptional Regulation

Voll, Sarah

13 November 2013

Understanding the functional impact of physical interactions between proteins and DNA on gene expression is important for developing approaches to correct disease-associated gene dysregulation. I conducted a systematic, functional genetic analysis of protein-DNA interactions in the promoter region of the yeast ribonucleotide reductase subunit gene RNR3. I measured the transcriptional impact of systematically perturbing the major transcriptional regulator, Crt1, and three X-box sites on the DNA known to physically bind Crt1. This analysis revealed interactions between two of the three X-boxes in the presence of Crt1, and unexpectedly, a significant functional role of the X-boxes in the absence of Crt1. Further analysis revealed Crt1- independent regulators of RNR3 that were impacted by X-box perturbation. Taken together, these results support the notion that higher-order X-box-mediated interactions are important for RNR3 transcription, and that the X-boxes have unexpected roles in the regulation of RNR3 transcription that extend beyond their interaction with Crt1.

functional genetic analysis

transcription factor (TF)

cis-regulatory element (CRE)

binary interaction

higher order interaction

multiple linear regression

additive

multiplicative

synthetic genetic array (SGA)

green fluorescent protein (GFP)

ribonucleotide reductase (RNR)

yeast

X-box

transcriptional regulation

RNR3

Functional Genetic Analysis Reveals Intricate Roles of Conserved X-box Elements in Yeast Transcriptional Regulation

Voll, Sarah

January 2013

Understanding the functional impact of physical interactions between proteins and DNA on gene expression is important for developing approaches to correct disease-associated gene dysregulation. I conducted a systematic, functional genetic analysis of protein-DNA interactions in the promoter region of the yeast ribonucleotide reductase subunit gene RNR3. I measured the transcriptional impact of systematically perturbing the major transcriptional regulator, Crt1, and three X-box sites on the DNA known to physically bind Crt1. This analysis revealed interactions between two of the three X-boxes in the presence of Crt1, and unexpectedly, a significant functional role of the X-boxes in the absence of Crt1. Further analysis revealed Crt1- independent regulators of RNR3 that were impacted by X-box perturbation. Taken together, these results support the notion that higher-order X-box-mediated interactions are important for RNR3 transcription, and that the X-boxes have unexpected roles in the regulation of RNR3 transcription that extend beyond their interaction with Crt1.

functional genetic analysis

transcription factor (TF)

cis-regulatory element (CRE)

binary interaction

higher order interaction

multiple linear regression

additive

multiplicative

synthetic genetic array (SGA)

green fluorescent protein (GFP)

ribonucleotide reductase (RNR)

yeast

X-box

transcriptional regulation

RNR3

High-field EPR and ENDOR spectroscopy for proton-coupled electron transfer investigations in E.coli ribonucleotide reductase / Hochfeld EPR und ENDOR Untersuchungen für den Protonen gekoppelten Elektronentransfer in der E.coli Ribonukleotidreduktase

Argirevic, Tomislav

17 November 2011

No description available.

000 Allgemeines

Wissenschaft

Chemistry

Ribonukleotidreduktase

DNA-Synthese

PCET

alpha2

beta2

Elektronentransfermechanismus

Hochfeld-EPR

Hochfeld-ENDOR

Multifrequenz

Wasserstoffbrücken

Wassermolekül

3-Aminotyrosyl Radikal

ribonucleotide reductase

DNA-Synthesis

PCET

alpha2

beta2

electron transfer mechanism

high-field EPR

high-field ENDOR

multifrequency

hydrogen-bond

water molecule

3-aminotyrosyl radical

35.71

Transcriptional regulation of mouse ribonucleotide reductase

Elfving, Anna

January 2011

All living organisms are made of cells and they store their hereditary information in the form of double stranded DNA. In all organisms DNA replication and repair is essential for cell division and cell survival. These processes require deoxyribonucleotides (dNTPs), the building blocks of DNA. Ribonucleotide reductase (RNR) is catalyzing the rate limiting step in the de novo synthesis of dNTPs. Active RNR is a heterodimeric protein complex. In S phase cells, the mouse RNR consists of the R1 and the R2 proteins. The R1/R2 RNR-complex supplies the cell with dNTPs required for DNA replication. Outside S-phase or in non-proliferating cells RNR is composed of R1 and p53R2 proteins. The R1/p53R2 RNR-complex supplies cells with dNTPs required for mitochondrial DNA replication and for DNA repair. An undisturbed dNTP regulation is important since unbalanced dNTP pools results in DNA mutations and cell death. Since unbalanced pools are harmful to the cell, RNR activity is regulated at many levels. The aim of this thesis is to study how the mouse RNR genes are regulated at a transcriptional level. We have focused on the promoter regions of all three mouse RNR genes. Primer extension experiments show that the transcription start of the TATA-less p53R2 promoter colocalizes with an earlier unidentified initiator element (Inr-element). This element is similar to the known Inr-element in the mouse R1 promoter. Furthermore, functional studies of the R1 promoter revealed a putative E2F binding element. This result suggests that the S phase specific transcription of the R1 gene is regulated by a similar mechanism as the R2 promoter which contains an E2F binding site. Finally we have established a method to partially purify the transcription factor(s) binding the upstream activating region in the mouse R2 promoter by phosphocellulose chromatography and affinity purification using oligonucleotides immobilized on magnetic beads. This method will allow us to further study the transcription factors responsible for activating expression of the R2 protein. This method has a potential to be utilized as a general method when purifying unknown transcription factors.