Maturation de sites métalliques de protéines par les machineries d'assemblage des centres fer-soufre ISC et Hyd / Maturation of protein active sites containing metals by the iron-sulfur cluster biogenesis ISC and Hyd systems

Pagnier, Adrien

02 November 2015

De nombreuses protéines possèdent des cofacteurs inorganiques contenant des métaux de transition. Les propriétés physico-chimiques de ces métaux permettent aux enzymes qui les portent de catalyser des réactions impossibles par l'utilisation des seules potentialités chimiques des vingt-deux acides aminés. Cependant, ces métaux sont toxiques pour la cellule lorsqu'ils sont libres. La synthèse et l'incorportion de ces cofacteurs dans les enzymes nécessitent alors des machineries protéiques complexes d'assemblage. Au cours de cette thèse, les mécanismes de synthèse des centres FeS par les machineries ISC (Iron-Sulfur Cluster) et Hyd (Hydrogenase) ont été étudiés. Le système ISC correspond à la machinerie primaire d'assemblage des centres FeS chez les bactéries, et un système équivalent existe chez les eucaryotes au niveau de la mitochondrie. Le système Hyd est la machinerie de maturation de l'hydrogénase à FeFe chez plusieurs eucaryotes inférieurs (algues et protistes) et dans une grande variété de bactéries. Dans un premier temps, nous nous sommes intéressés à la machinerie ISC d'Archaeoglobus fulgidus dont le coeur est composé de la cystéine désulfurase IscS et de la protéine échafaudage IscU ; IscS apportant le soufre nécessaire à l'assemblage du centre FeS sur IscU. Au cours de cette étude, il est apparu que IscS d'Archaeoglobus fulgidus ne possède pas d'activité cystéine désulfurase, mais qu'elle joue tout de même un rôle fondamental dans la synthèse du centre FeS sur le complexe IscSU en fournissant sa cystéine active en tant que ligand de l'agrégat. Dans un second temps, nous avons étudié la protéine à radical S-adénosyl-L-méthionine HydG, responsable de la synthèse des ligands CN- et CO du sous-agrégat à 2 Fe des hydrogénases à FeFe, qui était la seule maturase du système Hyd dont la structure n'était pas connue. Nos résultats structuraux et fonctionnels suggèrent que HydG synthétise successivement le ligand CN- dans un site actif basique, puis le ligand CO sur le cinquième Fe de son agrégat [5Fe-4S] C-terminal. Ce dernier pourrait être stabilisé par un ligand cystéine ou homocystéine. / Many proteins have inorganic cofactors containing transition metals. The physicochemical properties of these metals allow the enzymes, which carry them to catalyze reactions not possible when only using the chemical properties of the twenty-two amino acids. However, these metals are toxic to the cell when they are free. Consequently, the synthesis and incorporation of these cofactors into enzymes requires complex protein assembles. In this thesis, the FeS clusters synthesis mechanisms by the ISC (Iron-Sulfur Cluster) and Hyd (Hydrogenase) machineries were studied. The ISC system corresponds to the primary FeS clusters assembly machinery in bacteria, and a homologous system exists in mitochondria. The Hyd system is FeFe-hydrogenase active site maturation machinery found in several lower eukaryotes (algae and protists) and in a wide variety of bacteria. Initially, we studied the ISC machinery from Archaeoglobus fulgidus whose core is composed of the cysteine desulfurase IscS and the scaffold protein IscU; IscS delivers the sulfur needed for the FeS assembly to IscU. From this study we conclude that IscS from Archaeoglobus fulgidus has no cysteine desulfurase activity, but it still plays a fundamental role in FeS cluster synthesis by IscSU complex by providing a cysteine ligand to the nascent cluster. Secondly, we studied the radical S-adenosyl-L-methionine HydG, responsible for the synthesis of CN- and CO ligand of the active site [FeFe] subcluster, which was the only Hyd system maturase for which the structure was unknown. Our structural and functional results suggest that HydG successively synthesizes the CN- ligand at a basic site, and then the CO ligand at the unique fifth Fe ion of its C-terminal [5Fe-4S] cluster. The latter could be stabilized by either a cysteine or a homocysteine ligand.

Centres Fer-Soufre

Machinerie ISC

Métalloprotéines

Machinerie Hyd

Protéines à radical SAM

Cristallographie

Iron-Sulfur clusters

ISC machinerie

Metalloproteins

Hyd machinerie

Radical SAM proteins

Cristallography

570

Regulation of sodium transport across epithelia derived from human mammary gland

Wang, Qian

January 1900

Doctor of Philosophy / Department of Anatomy and Physiology / Bruce D. Schultz / The first aim of this project is to define the cellular mechanisms that account for the low Na[superscript]+ concentration in human milk. MCF10A cells, which were derived from human mammary epithelium and grown on permeable supports, exhibit amiloride- and benzamil-sensitive short circuit current (I[subscript]sc), suggesting activity of the epithelial Na[superscript]+ channel, ENaC. When cultured in the presence of cholera toxin (Ctx), MCF10A cells exhibit greater amiloride sensitive I[subscript]sc at all time points tested, an effect that is not reduced with Ctx washout for 12 hours or by cytosolic pathways inhibitors. Ctx increases the abundance of both beta and gamma-ENaC in the apical membrane and increases its monoubiquitination but without changing total protein and mRNA levels. Additionally, Ctx increases the levels of both the phosphorylated and the nonphosphorylated forms of Nedd4-2, a ubiquitin-protein ligase that regulates ENaC degradation. The results reveal a novel mechanism in human mammary gland epithelia by which Ctx regulates ENaC-mediated Na[superscript]+ transport. The second project aim is to develop a protocol to isolate mammary gland epithelia for subsequent in vitro culture. Caprine (1[superscript]0CME) and bovine mammary epithelia (1[superscript]0BME) were isolated and cultured on permeable supports to study hormone- and neurotransmitter-sensitive ion transport. Both 1[superscript]0CME and 1[superscript]0BME cells were passed for multiple subcultures and all passages formed electrically tight barriers. 1[superscript]0CME were cultured in the presence of hydrocortisone and exhibited high electrical resistance and amiloride-sensitive I[subscript]sc, suggesting the presence of ENaC-mediated Na[superscript]+ transport. 1[superscript]0BME were grown in a complex media in the presence or absence of dexamethasone. In contrast to 1[superscript]0CME, 1[superscript]0BME exhibited no detectable amiloride-sensitive I[subscript]sc in either culture condition. However, 1[superscript]0BME monolayers responded to an adrenergic agonist, norepinephrine, and a cholinergic agonist, carbamylcholine, with rapid increases in I[subscript]sc. Thus, this protocol for isolation and primary cell culture can be used for future studies that focus on mammary epithelial cell regulation and functions. In conclusion, the results from these projects demonstrate that mammary epithelial cells form electrically tight monolayers and can exhibit neurotransmitter- and/or hormone-induced net ion transport. The mechanisms that regulate Na[superscript]+ transport across mammary gland may provide clues to prevent or treat mastitis.

Epithelial sodium channel (ENaC)

Sodium transport

Mamamry epithelia

Cholera toxin

Short circuit current Isc

Physiology (0719)

A multi-component indicator of stream condition for waterway managers: balancing scientific rigour with the need for utility

Ladson, Anthony Richard

Unknown Date

Measuring the environmental condition of waterways is of interest to river managers, governments and the community. In the State of Victoria, Australia and elsewhere, there is concern that environmental values of streams are declining and that information about the environment, needs to be considered when river management decisions are being made. / This thesis explores the use of environmental indicators as a tool to assist management of rivers. The promise of indicators is that they can turn large amounts of environmental data into simple, timely results and thereby provide an effective means of incorporating this information into river management decisions. It is also suggested that indicators will be useful for measuring the outcomes of management intervention and provide feedback on the effectiveness of strategies. / Can environmental indicators live up to this promise? This thesis examines this question by reviewing indicator systems that have been developed by others and then exploring, in detail, the Index of Stream Conditions (ISC) that is is intended as a tool to assist the management of rivers in Victoria. I argue that environmental indicators have a role at the level of regional waterway management authorities but only if they are closely aligned with managers’ needs. Without consideration of non-technical issues, indicators are unlikely to be used, so it is important to establish a balance between pragmatic constraints and the need for scientific rigour. A procedure to achieve this balance is described in this thesis and was applied to the development of the ISC. Selection of indicators and the choice of indicator frameworks are explored and the value judgements behind the interpretation of indicator scores are examined. / It is also important to consider the accuracy and sensitivity of indicators. Possible objectives for the use of indicators include benchmarking, detecting change and providing information to trigger management intervention. Case studies are used to explore the performance of indicators in practical applications in streams in Victoria in relation to these objectives. Extensive use is made of non-traditional statistical procedures, including bootstrapping, and results are presented that show the likely variance of indicator scores and the relationship between indicator objectives and required sampling effort.

Caracterização da maquinaria SUF responsável pela formação e associação dos cofatores [Fe-S] em Enterococcus faecalis

Riboldi, Gustavo Pelicioli

January 2011

Cofatores ferro-enxofre são grupos prostéticos inorgânicos ubíquos e evolutivamente ancestrais, cuja formação é dependente de complexas maquinarias protéicas. Três sistemas de formação distintos já foram determinados, denominados sistemas NIF, ISC e SUF. Apesar de bem descritos em diversos organismos, estas maquinarias são pouco caracterizadas no filo Firmicutes, o qual agrupa diversas bactérias patogênicas, e onde Enterococcus faecalis aparece como um representante clinicamente relevante. O objetivo deste estudo foi identificar a maquinaria biossintética de formação dos cofatores [Fe-S] de E. faecalis mediante análises de bioinformática, determinação das regiões promotoras do operon e de elementos cis-atuantes, padrão de expressão gênica, caracterização bioquímica dos elementos encontrados e comparação entre as maquinarias de associação do cofator [Fe-S] presente em Proteobacteria e Firmicutes através da capacidade de complementação deste sistema nos sistemas ISC e SUF de Azotobacter vinelandii e Escherichia coli, respectivamente. Metodologias de bioinformática permitiram identificar representantes da maquinaria SUF de formação dos cofatores [Fe-S], previamente identificado em Proteobacteria, apresentando os genes sufB, sufC, sufD e sufS e a presença de sufU, o único representante homólogo do sistema ISC, codificando possível proteína arcabouço, no lugar de sufA; da mesma forma, sufE e sufR não foram identificadas. A alta conservação deste sistema foi verificada em Firmicutes através de análises filogenéticas. Análise de sequências primária e estrutural de SufU verificaram um padrão estrutural similar à IscU. Modelagem molecular de SufU de E. faecalis apresentou dados de alta flexibilidade na região do sítio ativo, bem como a presença de região específica em Firmicutes, denominada região Gram-positiva (GPR), possivelmente envolvida em interações com outros fatores e/ou reguladores. SufU e o complexo SufSU são capazes de reconstituir cofactor [4Fe-4S], apresentando-se portanto como a proteína arcabouço do sistema. A enzima SufS purificada apresenta PLP ligado como cofator e atividade de cisteína desulfurase. Esta enzima apresenta um residuo catalítico essencial de cisteína na posição 365 , e necessita SufU como ativador, onde outro residuo de cisteína (128) atua como aceptor do enxofre durante a reação de transpersulfuração. SufC apresenta atividade ATPase, porém em nível reduzido em comparação ao homólogo de E. coli; SufD apresenta alta similaridade com homólogo de proteobactérias. Por outro lado, SufB não apresenta os resíduos de cisteína previamente descritos como importantes na formação dos cofatores [Fe-S] em outros organismos, assim sua função no sistema ainda deve ser determinada. Experimentos in vivo demonstraram a conservação específica de sistemas biossintéticos dos cofatores [Fe-S], onde o operon SUF de E. faecalis não foi capaz de complementar os sistemas ISC de Proteobacteria, porém complementou sistema SUF de E. coli, tornando viáveis mutantes de ambos os operons sufABCDSE e iscRSU-hscBA-fdx. / Iron-sulfur clusters are ubiquitous and evolutionary ancient inorganic prosthetic groups, which biosynthesis depends on complex protein machineries. Three distinct assembly systems involved in the maturation of cellular Fe-S proteins have been determined, designated the NIF, ISC and SUF systems. Although well described in several organisms, these machineries are poorly understood in the Firmicutes phylum, which groups several pathological bacteria, where Enterococcus faecalis rises as a clinical relevant representative. The aim of this study was to identify the E. faecalis [Fe-S] cluster biosynthetic machinery through bioinformatics analysis, determination of operon promoter regions and cis-acting elements, relative genetic expression pattern, biochemical characterization of putative elements, and comparison of Proteobacteria and Firmicutes machineries through the ability of complementing Azotobacter vinelandii and Escherichia coli ISC and SUF systems, respectively. Bioinformatics methods enabled us to identify representatives of the SUF machinery for [Fe-S] cluster biosynthesis, previously verified in Proteobacteria showing conserved sufB, sufC, sufD and sufS genes and the presence of sufU, the only ISC homolog representative, coding for putative scaffold protein, instead of sufA; neither sufE nor sufR are present. High conservancy of this system for Firmicutes bacteria was verified through phylogenetic analysis. Primary sequences and structural analysis of the SufU protein demonstrated its structural-like pattern to the scaffold protein IscU. E. faecalis SufU molecular modeling showed high flexibility over the active site regions, and demonstrated the existence of a specific region in Firmicutes, the Gram positive region (GPR), a possible candidate for interaction with other factors and/or regulators. SufU is able to reconstitute a [4Fe-4S] cluster, such as the complex SufSU, arising as the scaffold protein in the system. Purified SufS corresponds to a PLP containing enzyme with cysteine desulfurase activity. It encloses a catalytically essential cysteine residue at position 365, and requires SufU as activator, where another cysteine residue (128) works as a proximal sulfur acceptor site for transpersulfurization reaction. SufC presents ATPase activity, though in a reduced level, when compared to the Escherichia coli homolog; SufD also shares high similarity with proteobacterial SufD. On the other hand, SufB does not present cysteine residues previously described as important involved in the [Fe-S] cluster formation process of other organisms, therefor its function in the system still have to be determined. In vivo experiments enabled us to dfemonstrate the conservancy of specific [Fe-S] cluster biosynthetic systems, where E. faecalis SUF operon was not able to complement Proteobacteria ISC systems, but complemented E. coli SUF system, turning viable mutants of both sufABCDSE and iscRSU-hscBA-fdx operons.

Enterococcus faecalis

Cofator ferro-enxofre

Eucariotos

[Fe-S] cluster biosynthetic machinery

ISC

SUF

Enterococcus faecalis

Caracterização da maquinaria SUF responsável pela formação e associação dos cofatores [Fe-S] em Enterococcus faecalis

Riboldi, Gustavo Pelicioli

January 2011

Cofatores ferro-enxofre são grupos prostéticos inorgânicos ubíquos e evolutivamente ancestrais, cuja formação é dependente de complexas maquinarias protéicas. Três sistemas de formação distintos já foram determinados, denominados sistemas NIF, ISC e SUF. Apesar de bem descritos em diversos organismos, estas maquinarias são pouco caracterizadas no filo Firmicutes, o qual agrupa diversas bactérias patogênicas, e onde Enterococcus faecalis aparece como um representante clinicamente relevante. O objetivo deste estudo foi identificar a maquinaria biossintética de formação dos cofatores [Fe-S] de E. faecalis mediante análises de bioinformática, determinação das regiões promotoras do operon e de elementos cis-atuantes, padrão de expressão gênica, caracterização bioquímica dos elementos encontrados e comparação entre as maquinarias de associação do cofator [Fe-S] presente em Proteobacteria e Firmicutes através da capacidade de complementação deste sistema nos sistemas ISC e SUF de Azotobacter vinelandii e Escherichia coli, respectivamente. Metodologias de bioinformática permitiram identificar representantes da maquinaria SUF de formação dos cofatores [Fe-S], previamente identificado em Proteobacteria, apresentando os genes sufB, sufC, sufD e sufS e a presença de sufU, o único representante homólogo do sistema ISC, codificando possível proteína arcabouço, no lugar de sufA; da mesma forma, sufE e sufR não foram identificadas. A alta conservação deste sistema foi verificada em Firmicutes através de análises filogenéticas. Análise de sequências primária e estrutural de SufU verificaram um padrão estrutural similar à IscU. Modelagem molecular de SufU de E. faecalis apresentou dados de alta flexibilidade na região do sítio ativo, bem como a presença de região específica em Firmicutes, denominada região Gram-positiva (GPR), possivelmente envolvida em interações com outros fatores e/ou reguladores. SufU e o complexo SufSU são capazes de reconstituir cofactor [4Fe-4S], apresentando-se portanto como a proteína arcabouço do sistema. A enzima SufS purificada apresenta PLP ligado como cofator e atividade de cisteína desulfurase. Esta enzima apresenta um residuo catalítico essencial de cisteína na posição 365 , e necessita SufU como ativador, onde outro residuo de cisteína (128) atua como aceptor do enxofre durante a reação de transpersulfuração. SufC apresenta atividade ATPase, porém em nível reduzido em comparação ao homólogo de E. coli; SufD apresenta alta similaridade com homólogo de proteobactérias. Por outro lado, SufB não apresenta os resíduos de cisteína previamente descritos como importantes na formação dos cofatores [Fe-S] em outros organismos, assim sua função no sistema ainda deve ser determinada. Experimentos in vivo demonstraram a conservação específica de sistemas biossintéticos dos cofatores [Fe-S], onde o operon SUF de E. faecalis não foi capaz de complementar os sistemas ISC de Proteobacteria, porém complementou sistema SUF de E. coli, tornando viáveis mutantes de ambos os operons sufABCDSE e iscRSU-hscBA-fdx. / Iron-sulfur clusters are ubiquitous and evolutionary ancient inorganic prosthetic groups, which biosynthesis depends on complex protein machineries. Three distinct assembly systems involved in the maturation of cellular Fe-S proteins have been determined, designated the NIF, ISC and SUF systems. Although well described in several organisms, these machineries are poorly understood in the Firmicutes phylum, which groups several pathological bacteria, where Enterococcus faecalis rises as a clinical relevant representative. The aim of this study was to identify the E. faecalis [Fe-S] cluster biosynthetic machinery through bioinformatics analysis, determination of operon promoter regions and cis-acting elements, relative genetic expression pattern, biochemical characterization of putative elements, and comparison of Proteobacteria and Firmicutes machineries through the ability of complementing Azotobacter vinelandii and Escherichia coli ISC and SUF systems, respectively. Bioinformatics methods enabled us to identify representatives of the SUF machinery for [Fe-S] cluster biosynthesis, previously verified in Proteobacteria showing conserved sufB, sufC, sufD and sufS genes and the presence of sufU, the only ISC homolog representative, coding for putative scaffold protein, instead of sufA; neither sufE nor sufR are present. High conservancy of this system for Firmicutes bacteria was verified through phylogenetic analysis. Primary sequences and structural analysis of the SufU protein demonstrated its structural-like pattern to the scaffold protein IscU. E. faecalis SufU molecular modeling showed high flexibility over the active site regions, and demonstrated the existence of a specific region in Firmicutes, the Gram positive region (GPR), a possible candidate for interaction with other factors and/or regulators. SufU is able to reconstitute a [4Fe-4S] cluster, such as the complex SufSU, arising as the scaffold protein in the system. Purified SufS corresponds to a PLP containing enzyme with cysteine desulfurase activity. It encloses a catalytically essential cysteine residue at position 365, and requires SufU as activator, where another cysteine residue (128) works as a proximal sulfur acceptor site for transpersulfurization reaction. SufC presents ATPase activity, though in a reduced level, when compared to the Escherichia coli homolog; SufD also shares high similarity with proteobacterial SufD. On the other hand, SufB does not present cysteine residues previously described as important involved in the [Fe-S] cluster formation process of other organisms, therefor its function in the system still have to be determined. In vivo experiments enabled us to dfemonstrate the conservancy of specific [Fe-S] cluster biosynthetic systems, where E. faecalis SUF operon was not able to complement Proteobacteria ISC systems, but complemented E. coli SUF system, turning viable mutants of both sufABCDSE and iscRSU-hscBA-fdx operons.

Enterococcus faecalis

Cofator ferro-enxofre

Eucariotos

[Fe-S] cluster biosynthetic machinery

ISC

SUF

Enterococcus faecalis

Caracterização da maquinaria SUF responsável pela formação e associação dos cofatores [Fe-S] em Enterococcus faecalis

Riboldi, Gustavo Pelicioli

January 2011

Cofatores ferro-enxofre são grupos prostéticos inorgânicos ubíquos e evolutivamente ancestrais, cuja formação é dependente de complexas maquinarias protéicas. Três sistemas de formação distintos já foram determinados, denominados sistemas NIF, ISC e SUF. Apesar de bem descritos em diversos organismos, estas maquinarias são pouco caracterizadas no filo Firmicutes, o qual agrupa diversas bactérias patogênicas, e onde Enterococcus faecalis aparece como um representante clinicamente relevante. O objetivo deste estudo foi identificar a maquinaria biossintética de formação dos cofatores [Fe-S] de E. faecalis mediante análises de bioinformática, determinação das regiões promotoras do operon e de elementos cis-atuantes, padrão de expressão gênica, caracterização bioquímica dos elementos encontrados e comparação entre as maquinarias de associação do cofator [Fe-S] presente em Proteobacteria e Firmicutes através da capacidade de complementação deste sistema nos sistemas ISC e SUF de Azotobacter vinelandii e Escherichia coli, respectivamente. Metodologias de bioinformática permitiram identificar representantes da maquinaria SUF de formação dos cofatores [Fe-S], previamente identificado em Proteobacteria, apresentando os genes sufB, sufC, sufD e sufS e a presença de sufU, o único representante homólogo do sistema ISC, codificando possível proteína arcabouço, no lugar de sufA; da mesma forma, sufE e sufR não foram identificadas. A alta conservação deste sistema foi verificada em Firmicutes através de análises filogenéticas. Análise de sequências primária e estrutural de SufU verificaram um padrão estrutural similar à IscU. Modelagem molecular de SufU de E. faecalis apresentou dados de alta flexibilidade na região do sítio ativo, bem como a presença de região específica em Firmicutes, denominada região Gram-positiva (GPR), possivelmente envolvida em interações com outros fatores e/ou reguladores. SufU e o complexo SufSU são capazes de reconstituir cofactor [4Fe-4S], apresentando-se portanto como a proteína arcabouço do sistema. A enzima SufS purificada apresenta PLP ligado como cofator e atividade de cisteína desulfurase. Esta enzima apresenta um residuo catalítico essencial de cisteína na posição 365 , e necessita SufU como ativador, onde outro residuo de cisteína (128) atua como aceptor do enxofre durante a reação de transpersulfuração. SufC apresenta atividade ATPase, porém em nível reduzido em comparação ao homólogo de E. coli; SufD apresenta alta similaridade com homólogo de proteobactérias. Por outro lado, SufB não apresenta os resíduos de cisteína previamente descritos como importantes na formação dos cofatores [Fe-S] em outros organismos, assim sua função no sistema ainda deve ser determinada. Experimentos in vivo demonstraram a conservação específica de sistemas biossintéticos dos cofatores [Fe-S], onde o operon SUF de E. faecalis não foi capaz de complementar os sistemas ISC de Proteobacteria, porém complementou sistema SUF de E. coli, tornando viáveis mutantes de ambos os operons sufABCDSE e iscRSU-hscBA-fdx. / Iron-sulfur clusters are ubiquitous and evolutionary ancient inorganic prosthetic groups, which biosynthesis depends on complex protein machineries. Three distinct assembly systems involved in the maturation of cellular Fe-S proteins have been determined, designated the NIF, ISC and SUF systems. Although well described in several organisms, these machineries are poorly understood in the Firmicutes phylum, which groups several pathological bacteria, where Enterococcus faecalis rises as a clinical relevant representative. The aim of this study was to identify the E. faecalis [Fe-S] cluster biosynthetic machinery through bioinformatics analysis, determination of operon promoter regions and cis-acting elements, relative genetic expression pattern, biochemical characterization of putative elements, and comparison of Proteobacteria and Firmicutes machineries through the ability of complementing Azotobacter vinelandii and Escherichia coli ISC and SUF systems, respectively. Bioinformatics methods enabled us to identify representatives of the SUF machinery for [Fe-S] cluster biosynthesis, previously verified in Proteobacteria showing conserved sufB, sufC, sufD and sufS genes and the presence of sufU, the only ISC homolog representative, coding for putative scaffold protein, instead of sufA; neither sufE nor sufR are present. High conservancy of this system for Firmicutes bacteria was verified through phylogenetic analysis. Primary sequences and structural analysis of the SufU protein demonstrated its structural-like pattern to the scaffold protein IscU. E. faecalis SufU molecular modeling showed high flexibility over the active site regions, and demonstrated the existence of a specific region in Firmicutes, the Gram positive region (GPR), a possible candidate for interaction with other factors and/or regulators. SufU is able to reconstitute a [4Fe-4S] cluster, such as the complex SufSU, arising as the scaffold protein in the system. Purified SufS corresponds to a PLP containing enzyme with cysteine desulfurase activity. It encloses a catalytically essential cysteine residue at position 365, and requires SufU as activator, where another cysteine residue (128) works as a proximal sulfur acceptor site for transpersulfurization reaction. SufC presents ATPase activity, though in a reduced level, when compared to the Escherichia coli homolog; SufD also shares high similarity with proteobacterial SufD. On the other hand, SufB does not present cysteine residues previously described as important involved in the [Fe-S] cluster formation process of other organisms, therefor its function in the system still have to be determined. In vivo experiments enabled us to dfemonstrate the conservancy of specific [Fe-S] cluster biosynthetic systems, where E. faecalis SUF operon was not able to complement Proteobacteria ISC systems, but complemented E. coli SUF system, turning viable mutants of both sufABCDSE and iscRSU-hscBA-fdx operons.

Enterococcus faecalis

Cofator ferro-enxofre

Eucariotos

[Fe-S] cluster biosynthetic machinery

ISC

SUF

Enterococcus faecalis

Assessing Near-Field Black Carbon Variability Due to Wood Burning and Evaluating Regression Models and ISC Dispersion Modeling

Tan, Stella

01 September 2011

PM2.5 variability within the neighborhood scale has not been thoroughly studied for wood burning communities. High variability in near-field PM2.5 concentration may lead to harmful public exposure since monitoring does not occur on that scale. This study measures near-field PM2.5 variability by measuring black carbon (BC), a component of PM2.5, in a 1 km2 area located in Cambria, California. BC and meteorological data (when meteorological instruments were available) were measured over thirteen 12-hour intensive operation periods (IOPs) occurring over the winters of 2009 and 2010. Near-field BC variability was measured to understand the type of exposures found in communities where many homes are burning wood simultaneously within a small area. In addition, relationships between meteorological, geographical, and burning source characteristics and BC were observed as tools for understanding BC concentration. The computer air dispersion modeling programs, ISC-PRIME and ISCST3, were also evaluated for applicability to the near field. BC concentrations were measured using 1- to 2-minute resolution aethalometers and 12 hour resolution Personal Environmental Monitors (PEMs). On average, over all IOPs and sites, aethalometer and PEM BC averages were very similar, ranging between 200 and 250 ng/m3, or 4 and 5 µg/m3 for PM2.5, and standard deviations were often high. Averaging all BC measurements, aethalometer BC standard deviation values were 360 percent of the average BC concentration and PEM BC standard deviations were 120 percent the average BC concentration. The average standard deviation detected during each IOP was 190 percent of the average BC concentration for aethalometers and 79 percent of the average BC concentration for PEMs. The average standard deviation detected at each site was 220 percent of the average BC concentration for aethalometers and 76 percent of the average BC concentration for PEMs. The larger standard deviations measured by higher resolution aethalometers demonstrated that low resolution instruments, such as PEMs, are unable to detect high concentrations that may occur. In addition to examining BC variability, multiple linear regression analyses were conducted to determine the impact of meteorological variables and geographic and burning source characteristics on BC concentration and a weighted BC deviation function (BC standard deviation divided by average BC concentration). Time impacts, humidity, and wind speed, accounted for about 50 percent of variability in aethalometer average BC and BC deviation. However, because all model assumptions were not satisfied, improvements are needed. Regression models based on PEM BC found wind speed and direction to account for about 80 percent of average PEM BC variability and number of burning sources to account for about 30 percent of PEM BC deviation. Although PEM BC models accounted for a high percentage of BC variability, few data points were available for the PEM analyses and more IOPs are needed to determine their accuracy. When evaluating correlations between geographic and burning source characteristics and PEM BC concentrations, specific IOP and PEM sampling location explained almost 70 percent of variability in BC concentration, though model residuals suggested model bias. IOP likely explained variation in burning patterns and meteorology over each night while sampling location was likely a proxy for housing density, tree coverage, and/or elevation. Because all regression model assumptions could not be satisfied, the predictors were also observed graphically. Plotting BC concentration versus the number of burning sources suggested that number of burning sources may affect BC concentration in areas of low tree coverage and high housing density and in the case that the level of surrounding vegetation and structures are minimal. More data points will be needed to determine whether or not these relationships are significant. ISC-PRIME and ISCST3 modeling overall tended to under predict BC concentrations with average modeled-to-measured ratios averaging 0.25 and 0.15, for ISC-PRIME and ISCST3, respectively. Correction factors of 9.75 and 18.2 for ISC-PRIME and ISCST3, respectively, were determined to bring modeled BC concentrations closer to unity, but the range of ratios was still high. Both programs were unable to consistently capture BC variability in the area and more investigation will be needed to improve models. The results of the study indicate high BC variability exists on the near-field scale, but that the variability is not clearly explained by existing regression and air dispersion models. To prevent public exposure to harmful concentrations, more investigation will be needed to determine factors that largely influence pollutant variability on the neighborhood scale.

black carbon

PM2.5

near-field

multiple regression

ISCST3

ISC-PRIME

Environmental Engineering

Caractérisation du rôle de la frataxine dans la machinerie de biosynthèse des clusters FeS et développement d'un logiciel de prédiction des protéines FeS / Characterization of frataxin function during the iron-sulfur clusters biosynthesis and development of a software for the in silico prediction of Fer-Sulfur Cluster proteins

Colin, Florent

09 December 2013

L’Ataxie de Friedreich est une maladie génétique récessive neurodégénérative. Elle est due à un déficit dans l’expression d’une protéine mitochondriale, la frataxine. Cette protéine est impliquée dans l’assemblage des protéines fer-soufre (FeS). Le premier axe de ma thèse a consisté à mieux caractériser le rôle de la frataxine au sein du complexe précoce de biosynthèse des clusters FeS (NFS1/ISD11/ISCU). Mes résultats m’ont permis de mettre en évidence l’importance de la frataxine dans le contrôle de l’entrée du fer au sein du complexe de biosynthèse, sur l’activité enzymatique de NFS1 et sur le transfert des clusters FeS vers les apo-protéines. Le second axe a été le développement du programme de bioinformatique (PredISC) nous permettant des candidats de protéines FeS. Ce programme a permis de générer une liste de candidat qui pourra être compilée sous la forme d’une base de données. Par la suite, des approches transversales y seront associées à afin d’affiner les listes de candidats. / Friedreich Ataxia (FA) is the most prevalent form of autosomal recessive ataxia in the Caucasian population. Frataxin is implicated in the biosynthesis of iron-sulfur (FeS). The first axis of my work was to better characterize the function of Frataxin in the “early” complex of FeS clusters biosynthesis (NFS1/ISD11/ISCU). I was able to show the crucial involvement of Frataxin in the control of iron entry in this complex, on the enzymatic activity of NFS1 and on the transfert of FeS cluster to apo-proteins. Thesecond axis was the development of a bio-informatic software (PredISC) that is able to predict potential iron-sulfur containing proteins. The software allows us to generate a list of candidates that will be compiled in a database. In the future transversal approaches have to be associated in order to reduced the number of candidates, and increase their interest.

Frataxine

Clusters Fer-Soufre

Ataxie de Friedreich

Protéines Fer-Soufre

Machinerie ISC

NFS1

ISCU

ISD11

Frataxin

Fer-Sulfur Clusters

Friedreich Ataxia

Fer-Sulfur Proteins

ISC machinery

NFS1

ISCU

ISD11

572.4

616

Maturation de sites métalliques de protéines par les protéines à radical S-Adénosyl-L-méthionine et la machinerie de fabrication des centres fer-soufre

Marinoni, Elodie

09 December 2011

Les centres FeS sont un des cofacteurs protéiques majeurs, ils se trouvent aussi bien chez les bactéries que chez les eucaryotes. Ils ont des rôles essentiels de transfert d'électron, liaison de substrat et son activation, régulation d'expression de gènes, donneur de soufre etc. Leur agencement est très varié, allant du centre [2Fe-2S] à l'agrégat plus complexe MoFe7S9X (X = C, N ou O) de la nitrogénase. L'assemblage de ces centres se fait par des machineries protéiques. Nous avons étudié le système ISC (Iron-Sulfur Cluster) chez les bactéries, qui fabrique des centres [2Fe-2S] et [4Fe-4S]. Il est composé des protéines IscS, IscU, IscA, HscA, HscB et d'une ferrédoxine. Deux de ces protéines, IscS, qui est une cystéine désulfurase et IscU, protéine dite échafaudage, sont le cœur de la machinerie puisque IscS apporte le soufre sur la protéine IscU, qui, avec le fer qu'elle aura obtenu d'une autre protéine (non clairement identifiée à ce jour), fabriquera le centre fer-soufre et le transfèrera à une apoprotéine. Nous avons isolé un complexe stable (IscS-D35A-IscU)2 contenant un centre [2Fe-2S] dans des conditions anaérobie. Différentes formes du complexe ont été obtenues et cristallisées afin d'obtenir leurs structures, résolues par remplacement moléculaire. Ces structures nous ont permis de proposer un mécanisme d'assemblage des centres [2Fe-2S] à l'échelle atomique et électronique. Nous avons d'autre part étudié la protéine HmdB probablement impliquée dans la maturation de l'hydrogénase à fer. HmdB fait partie de la superfamille des protéines à radical SAM. Des cristaux de l'apoprotéine ont été obtenus et sa structure a été résolue par remplacement moléculaire. Même si une partie de la structure n'est pas visible du fait de l'absence de centre [4Fe-4S], elle donne une première vue du site actif de la protéine.

Radical SAM

Centres FeS

Machinerie ISC

Hydrogénase

Automated Reasoning Support for Invasive Interactive Parallelization

Moshir Moghaddam, Kianosh

January 2012

To parallelize a sequential source code, a parallelization strategy must be defined that transforms the sequential source code into an equivalent parallel version. Since parallelizing compilers can sometimes transform sequential loops and other well-structured codes into parallel ones automatically, we are interested in finding a solution to parallelize semi-automatically codes that compilers are not able to parallelize automatically, mostly because of weakness of classical data and control dependence analysis, in order to simplify the process of transforming the codes for programmers.Invasive Interactive Parallelization (IIP) hypothesizes that by using anintelligent system that guides the user through an interactive process one can boost parallelization in the above direction. The intelligent system's guidance relies on a classical code analysis and pre-defined parallelizing transformation sequences. To support its main hypothesis, IIP suggests to encode parallelizing transformation sequences in terms of IIP parallelization strategies that dictate default ways to parallelize various code patterns by using facts which have been obtained both from classical source code analysis and directly from the user.In this project, we investigate how automated reasoning can supportthe IIP method in order to parallelize a sequential code with an acceptable performance but faster than manual parallelization. We have looked at two special problem areas: Divide and conquer algorithms and loops in the source codes. Our focus is on parallelizing four sequential legacy C programs such as: Quick sort, Merge sort, Jacobi method and Matrix multipliation and summation for both OpenMP and MPI environment by developing an interactive parallelizing assistance tool that provides users with the assistanceneeded for parallelizing a sequential source code.

Multi-processors

Dependence Analysis

Code parallelization

Semi-automatic parallelization

IIP

ISC

OpenMP

MPI

Artificial Intelligence

Reasoning

Decision Tree

Divide and Conquer (D&C) algorithms