Investigations of cellular [2Fe-2S] and [4Fe-4S] cluster biosynthesis and trafficking

Hendricks, Amber Lee

January 2021

No description available.

Biochemistry

Chemistry

Probing Plant Metabolism: The Machineries of [Fe-S] Cluster Assembly and Flavonoid Biosynthesis

Ramirez, Melissa V.

12 September 2008

The organization of metabolism is an essential feature of cellular biochemistry. Metabolism does not occur as a linear assembly of freely diffusing enzymes, but as a complex web in which multiple interactions are possible. Because of the crowded environment of the cell, there must be structured and ordered mechanisms that control metabolic pathways. The following work will examine two metabolic pathways, one that is ubiquitous among living organisms and another that is entirely unique to plants, and examine the organization of each in an attempt to further define mechanisms that are fundamental features of metabolic control. One study offers some of the first characterizations of genes involved in [Fe-S] cluster assembly in Arabidopsis. The other explores the mechanisms that control localization of an enzyme that is part of the well-characterized flavonoid biosynthetic pathway. These two distinct pathways serve as unique models for genetic and biochemical studies that contribute to our overall understanding of plant metabolism. / Ph. D.

intracellular localization

chalcone synthase

[Fe-S] cluster assembly

flavonoid biosynthesis

confocal microscopy

Análise transcricional dos genes do sistema ISC em EUCALYPTUS GRANDIS e AZOBACTER VINELAND

Oliveira, Luisa Abruzzi de

January 2012

Os cofatores de ferro-enxofre [Fe-S] estão entre os mais versáteis e antigos cofatores enzimáticos encontrados na natureza. As células têm explorado as propriedades eletrônicas e estruturais destes cofatores inorgânicos para uma ampla variedade de atividades incluindo a transferência de elétrons, a catálise e a ativação de substratos. Um grande número de proteínas está envolvido na biogênese dos cofatores [Fe-S], e este processo pode ser dividido em três etapas principais: (i) formação do enxofre elementar, (ii) montagem do cofator [Fe-S], e (iii) inserção do cofator em apoproteínas. As plantas realizam fotossíntese e respiração, dois processos que requerem proteínas Fe-S, sendo os únicos organismos em que a biossíntese destas proteínas é compartimentalizada. Diversos fatores afetam o desenvolvimento das plantas, entre eles, a temperatura baixa, fator limitante à produtividade e à distribuição geográfica das plantas, incluindo Eucalyptus grandis, uma espécie com grande importância econômica. Devido a esse fato, foi realizada uma análise transcricional dos genes codificados pelo sistema ISC de biossíntese de cofatores [Fe-S] NFS1, ISA1 e ISU1 de E. grandis por meio de PCR quantitativa (RT-qPCR), após plântulas desta espécie serem submetidas ao tratamento de frio. O gene NFS1 teve sua expressão reprimida nas primeiras 48 horas de tratamento, porém, após esse período observa-se um aumento da expressão gênica em relação à condição controle. O genes ISU1 e ISA1 apresentaram maior expressão gênica nas primeiras duas horas de tratamento, diminuindo drasticamente logo após este período. Foi verificado um aumento na quantidade relativa de Fe e S nos nas plântulas submetidas ao tratamento de frio, indicando um possível aumento na quantidade de cofatores [Fe-S] requeridos para o reestabelecimento da homeostase celular. As bactérias, por sua vez, desenvolveram pelo menos três sistemas de biossíntese, altamente conservados, que estão envolvidos na formação dos cofatores [Fe-S], sendo estes NIF, ISC e SUF. Em muitas proteobactérias, a regulação da produção de cofatores [Fe-S] pelos sistemas ISC e SUF é controlada por uma única proteína, IscR, pertencente à família de reguladores Rrf2. A proteína IscR possui um domínio de ligação ao DNA na região N-terminal e um segundo domínio de ligação de cofatores com três resíduos de cisteínas (Cys) altamente conservados. A ligação de um cofator do tipo [2Fe-2S] reprime a transcrição do seu próprio promotor in vitro. O genoma de Azotobacter vinelandii não inclui um sistema SUF completo e, portanto, permite o estudo dos efeitos da regulação de IscR não relacionada a SUF. No presente trabalho, objetivamos analisar a expressão do operon isc em linhagens selvagens e mutantes para IscR de A. vinelandii por meio das técnicas de sequenciamento do transcritoma e RT-qPCR. As substituições das Cys92, Cys104, His107 e a deleção de 120 pb da região codificadora do segundo domínio de IscR levaram à indução de um aumento da expressão de todo o operon isc. Notou-se também uma diferença fenotípica clara no tamanho das colônias portadoras das substituições de Cys e His, sendo estas menores em relação à linhagem selvagem. As substituições das Cys98 e Cys111, ou ainda a dupla substituição Cys98/111 não levaram a alteração da expressão do operon. A ligação ou não do cofator [Fe-S] é, portanto, responsável pela regulação do operon isc em A. vinelandii, bem como, de outros operons codificadores de proteínas envolvidas em cadeias tranportadoras de elétrons. / The iron-sulfur clusters [Fe-S] are among the oldest and most versatile enzyme cofactors found in nature. The cells have explored the structural and electronic properties of these inorganic clusters for a wide variety of activities including electron transfer, catalysis and activation of substrates. A large number of proteins is involved in the biogenesis of the [Fe-S] clusters, and this process can be divided into three main steps: (i) formation of elemental sulfur, (ii) assembly of the [Fe-S] cluster and (iii) insertion into apoproteins. Plants perform photosynthesis and respiration, two processes that require Fe-S protein, and in these organisms the synthesis of these proteins is compartmentalized. Several factors affect the development of plants, among them, the low temperature is a limiting factor to productivity and geographical distribution of plants, including Eucalyptus grandis, a specie with great economic importance. Due to this fact, we performed a transcriptional analysis by quantitative PCR (RT-qPCR) of the genes encoded by the E. grandis [Fe-S] cluster ISC system NFS1, ISA1 and ISU1 after seedlings were submitted to the chilling treatment. The NFS1 gene expression is repressed in the first 48 hours of treatment, but after this period there was an increase in gene expression relating to the control condition. The genes ISU1 and ISA1 showed higher gene expression in the first two hours of treatment, followed by a sharp decrease. There was an increase in the relative amount of Fe and S in the seedlings subjected to cold treatment, indicating a possible increase in the amount of [Fe-S] clusters, required for the reestablishment of cellular homeostasis. Bacteria have developed at least three synthesis systems, highly conserved, which are involved in the formation of Fe-S proteins, NIF, ISC and SUF. In many proteobacteria, the regulation of clusters production by ISC and SUF is controlled by a single protein, IscR, belonging to the Rrf2 regulators family. The protein IscR has a DNA binding site at the N-terminal domain and second cofactors binding domain with three cysteine residues (Cys) highly conserved. The binding of a [2Fe-2S] cluster represses the transcription of its own promoter in vitro. The genome of Azotobacter vinelandii does not include a full SUF system and thus permits the study of the effects of IscR regulation unrelated to SUF. In this study, the aim was to analyze the expression of isc operon in wild type and mutant strains of A. vinelandii IscR by the techniques of the transcriptome sequencing and qRT-PCR. The replacement of Cys92, Cys104, His107 and a deletion of 120 bp region encoding the second IscR domain led to an increased expression of the whole isc operon. It also showed a clear phenotypic difference in colonies size in the strains carrying the substitutions of His and Cys, it was smaller compared to the wild type strain. The replacement of Cys98 and Cys111, or the double substitution Cys98/111 not led to an altered operon expression. The [Fe-S] cluster binding or not, is therefore responsible for the regulation of the isc operon in A. vinelandii as well as of other operons encoding proteins involved in electron tranport chains.

Eucalyptus grandis

Azotobacter vinelandii

Genes

Genética vegetal

Eucalyptus grandis

Azotobacter vinelandii

[Fe-S] cluster

RT-qPCR

Cold stress

IscR

Análise transcricional dos genes do sistema ISC em EUCALYPTUS GRANDIS e AZOBACTER VINELAND

Oliveira, Luisa Abruzzi de

January 2012

Os cofatores de ferro-enxofre [Fe-S] estão entre os mais versáteis e antigos cofatores enzimáticos encontrados na natureza. As células têm explorado as propriedades eletrônicas e estruturais destes cofatores inorgânicos para uma ampla variedade de atividades incluindo a transferência de elétrons, a catálise e a ativação de substratos. Um grande número de proteínas está envolvido na biogênese dos cofatores [Fe-S], e este processo pode ser dividido em três etapas principais: (i) formação do enxofre elementar, (ii) montagem do cofator [Fe-S], e (iii) inserção do cofator em apoproteínas. As plantas realizam fotossíntese e respiração, dois processos que requerem proteínas Fe-S, sendo os únicos organismos em que a biossíntese destas proteínas é compartimentalizada. Diversos fatores afetam o desenvolvimento das plantas, entre eles, a temperatura baixa, fator limitante à produtividade e à distribuição geográfica das plantas, incluindo Eucalyptus grandis, uma espécie com grande importância econômica. Devido a esse fato, foi realizada uma análise transcricional dos genes codificados pelo sistema ISC de biossíntese de cofatores [Fe-S] NFS1, ISA1 e ISU1 de E. grandis por meio de PCR quantitativa (RT-qPCR), após plântulas desta espécie serem submetidas ao tratamento de frio. O gene NFS1 teve sua expressão reprimida nas primeiras 48 horas de tratamento, porém, após esse período observa-se um aumento da expressão gênica em relação à condição controle. O genes ISU1 e ISA1 apresentaram maior expressão gênica nas primeiras duas horas de tratamento, diminuindo drasticamente logo após este período. Foi verificado um aumento na quantidade relativa de Fe e S nos nas plântulas submetidas ao tratamento de frio, indicando um possível aumento na quantidade de cofatores [Fe-S] requeridos para o reestabelecimento da homeostase celular. As bactérias, por sua vez, desenvolveram pelo menos três sistemas de biossíntese, altamente conservados, que estão envolvidos na formação dos cofatores [Fe-S], sendo estes NIF, ISC e SUF. Em muitas proteobactérias, a regulação da produção de cofatores [Fe-S] pelos sistemas ISC e SUF é controlada por uma única proteína, IscR, pertencente à família de reguladores Rrf2. A proteína IscR possui um domínio de ligação ao DNA na região N-terminal e um segundo domínio de ligação de cofatores com três resíduos de cisteínas (Cys) altamente conservados. A ligação de um cofator do tipo [2Fe-2S] reprime a transcrição do seu próprio promotor in vitro. O genoma de Azotobacter vinelandii não inclui um sistema SUF completo e, portanto, permite o estudo dos efeitos da regulação de IscR não relacionada a SUF. No presente trabalho, objetivamos analisar a expressão do operon isc em linhagens selvagens e mutantes para IscR de A. vinelandii por meio das técnicas de sequenciamento do transcritoma e RT-qPCR. As substituições das Cys92, Cys104, His107 e a deleção de 120 pb da região codificadora do segundo domínio de IscR levaram à indução de um aumento da expressão de todo o operon isc. Notou-se também uma diferença fenotípica clara no tamanho das colônias portadoras das substituições de Cys e His, sendo estas menores em relação à linhagem selvagem. As substituições das Cys98 e Cys111, ou ainda a dupla substituição Cys98/111 não levaram a alteração da expressão do operon. A ligação ou não do cofator [Fe-S] é, portanto, responsável pela regulação do operon isc em A. vinelandii, bem como, de outros operons codificadores de proteínas envolvidas em cadeias tranportadoras de elétrons. / The iron-sulfur clusters [Fe-S] are among the oldest and most versatile enzyme cofactors found in nature. The cells have explored the structural and electronic properties of these inorganic clusters for a wide variety of activities including electron transfer, catalysis and activation of substrates. A large number of proteins is involved in the biogenesis of the [Fe-S] clusters, and this process can be divided into three main steps: (i) formation of elemental sulfur, (ii) assembly of the [Fe-S] cluster and (iii) insertion into apoproteins. Plants perform photosynthesis and respiration, two processes that require Fe-S protein, and in these organisms the synthesis of these proteins is compartmentalized. Several factors affect the development of plants, among them, the low temperature is a limiting factor to productivity and geographical distribution of plants, including Eucalyptus grandis, a specie with great economic importance. Due to this fact, we performed a transcriptional analysis by quantitative PCR (RT-qPCR) of the genes encoded by the E. grandis [Fe-S] cluster ISC system NFS1, ISA1 and ISU1 after seedlings were submitted to the chilling treatment. The NFS1 gene expression is repressed in the first 48 hours of treatment, but after this period there was an increase in gene expression relating to the control condition. The genes ISU1 and ISA1 showed higher gene expression in the first two hours of treatment, followed by a sharp decrease. There was an increase in the relative amount of Fe and S in the seedlings subjected to cold treatment, indicating a possible increase in the amount of [Fe-S] clusters, required for the reestablishment of cellular homeostasis. Bacteria have developed at least three synthesis systems, highly conserved, which are involved in the formation of Fe-S proteins, NIF, ISC and SUF. In many proteobacteria, the regulation of clusters production by ISC and SUF is controlled by a single protein, IscR, belonging to the Rrf2 regulators family. The protein IscR has a DNA binding site at the N-terminal domain and second cofactors binding domain with three cysteine residues (Cys) highly conserved. The binding of a [2Fe-2S] cluster represses the transcription of its own promoter in vitro. The genome of Azotobacter vinelandii does not include a full SUF system and thus permits the study of the effects of IscR regulation unrelated to SUF. In this study, the aim was to analyze the expression of isc operon in wild type and mutant strains of A. vinelandii IscR by the techniques of the transcriptome sequencing and qRT-PCR. The replacement of Cys92, Cys104, His107 and a deletion of 120 bp region encoding the second IscR domain led to an increased expression of the whole isc operon. It also showed a clear phenotypic difference in colonies size in the strains carrying the substitutions of His and Cys, it was smaller compared to the wild type strain. The replacement of Cys98 and Cys111, or the double substitution Cys98/111 not led to an altered operon expression. The [Fe-S] cluster binding or not, is therefore responsible for the regulation of the isc operon in A. vinelandii as well as of other operons encoding proteins involved in electron tranport chains.

Eucalyptus grandis

Azotobacter vinelandii

Genes

Genética vegetal

Eucalyptus grandis

Azotobacter vinelandii

[Fe-S] cluster

RT-qPCR

Cold stress

IscR

Análise transcricional dos genes do sistema ISC em EUCALYPTUS GRANDIS e AZOBACTER VINELAND

Oliveira, Luisa Abruzzi de

January 2012

Os cofatores de ferro-enxofre [Fe-S] estão entre os mais versáteis e antigos cofatores enzimáticos encontrados na natureza. As células têm explorado as propriedades eletrônicas e estruturais destes cofatores inorgânicos para uma ampla variedade de atividades incluindo a transferência de elétrons, a catálise e a ativação de substratos. Um grande número de proteínas está envolvido na biogênese dos cofatores [Fe-S], e este processo pode ser dividido em três etapas principais: (i) formação do enxofre elementar, (ii) montagem do cofator [Fe-S], e (iii) inserção do cofator em apoproteínas. As plantas realizam fotossíntese e respiração, dois processos que requerem proteínas Fe-S, sendo os únicos organismos em que a biossíntese destas proteínas é compartimentalizada. Diversos fatores afetam o desenvolvimento das plantas, entre eles, a temperatura baixa, fator limitante à produtividade e à distribuição geográfica das plantas, incluindo Eucalyptus grandis, uma espécie com grande importância econômica. Devido a esse fato, foi realizada uma análise transcricional dos genes codificados pelo sistema ISC de biossíntese de cofatores [Fe-S] NFS1, ISA1 e ISU1 de E. grandis por meio de PCR quantitativa (RT-qPCR), após plântulas desta espécie serem submetidas ao tratamento de frio. O gene NFS1 teve sua expressão reprimida nas primeiras 48 horas de tratamento, porém, após esse período observa-se um aumento da expressão gênica em relação à condição controle. O genes ISU1 e ISA1 apresentaram maior expressão gênica nas primeiras duas horas de tratamento, diminuindo drasticamente logo após este período. Foi verificado um aumento na quantidade relativa de Fe e S nos nas plântulas submetidas ao tratamento de frio, indicando um possível aumento na quantidade de cofatores [Fe-S] requeridos para o reestabelecimento da homeostase celular. As bactérias, por sua vez, desenvolveram pelo menos três sistemas de biossíntese, altamente conservados, que estão envolvidos na formação dos cofatores [Fe-S], sendo estes NIF, ISC e SUF. Em muitas proteobactérias, a regulação da produção de cofatores [Fe-S] pelos sistemas ISC e SUF é controlada por uma única proteína, IscR, pertencente à família de reguladores Rrf2. A proteína IscR possui um domínio de ligação ao DNA na região N-terminal e um segundo domínio de ligação de cofatores com três resíduos de cisteínas (Cys) altamente conservados. A ligação de um cofator do tipo [2Fe-2S] reprime a transcrição do seu próprio promotor in vitro. O genoma de Azotobacter vinelandii não inclui um sistema SUF completo e, portanto, permite o estudo dos efeitos da regulação de IscR não relacionada a SUF. No presente trabalho, objetivamos analisar a expressão do operon isc em linhagens selvagens e mutantes para IscR de A. vinelandii por meio das técnicas de sequenciamento do transcritoma e RT-qPCR. As substituições das Cys92, Cys104, His107 e a deleção de 120 pb da região codificadora do segundo domínio de IscR levaram à indução de um aumento da expressão de todo o operon isc. Notou-se também uma diferença fenotípica clara no tamanho das colônias portadoras das substituições de Cys e His, sendo estas menores em relação à linhagem selvagem. As substituições das Cys98 e Cys111, ou ainda a dupla substituição Cys98/111 não levaram a alteração da expressão do operon. A ligação ou não do cofator [Fe-S] é, portanto, responsável pela regulação do operon isc em A. vinelandii, bem como, de outros operons codificadores de proteínas envolvidas em cadeias tranportadoras de elétrons. / The iron-sulfur clusters [Fe-S] are among the oldest and most versatile enzyme cofactors found in nature. The cells have explored the structural and electronic properties of these inorganic clusters for a wide variety of activities including electron transfer, catalysis and activation of substrates. A large number of proteins is involved in the biogenesis of the [Fe-S] clusters, and this process can be divided into three main steps: (i) formation of elemental sulfur, (ii) assembly of the [Fe-S] cluster and (iii) insertion into apoproteins. Plants perform photosynthesis and respiration, two processes that require Fe-S protein, and in these organisms the synthesis of these proteins is compartmentalized. Several factors affect the development of plants, among them, the low temperature is a limiting factor to productivity and geographical distribution of plants, including Eucalyptus grandis, a specie with great economic importance. Due to this fact, we performed a transcriptional analysis by quantitative PCR (RT-qPCR) of the genes encoded by the E. grandis [Fe-S] cluster ISC system NFS1, ISA1 and ISU1 after seedlings were submitted to the chilling treatment. The NFS1 gene expression is repressed in the first 48 hours of treatment, but after this period there was an increase in gene expression relating to the control condition. The genes ISU1 and ISA1 showed higher gene expression in the first two hours of treatment, followed by a sharp decrease. There was an increase in the relative amount of Fe and S in the seedlings subjected to cold treatment, indicating a possible increase in the amount of [Fe-S] clusters, required for the reestablishment of cellular homeostasis. Bacteria have developed at least three synthesis systems, highly conserved, which are involved in the formation of Fe-S proteins, NIF, ISC and SUF. In many proteobacteria, the regulation of clusters production by ISC and SUF is controlled by a single protein, IscR, belonging to the Rrf2 regulators family. The protein IscR has a DNA binding site at the N-terminal domain and second cofactors binding domain with three cysteine residues (Cys) highly conserved. The binding of a [2Fe-2S] cluster represses the transcription of its own promoter in vitro. The genome of Azotobacter vinelandii does not include a full SUF system and thus permits the study of the effects of IscR regulation unrelated to SUF. In this study, the aim was to analyze the expression of isc operon in wild type and mutant strains of A. vinelandii IscR by the techniques of the transcriptome sequencing and qRT-PCR. The replacement of Cys92, Cys104, His107 and a deletion of 120 bp region encoding the second IscR domain led to an increased expression of the whole isc operon. It also showed a clear phenotypic difference in colonies size in the strains carrying the substitutions of His and Cys, it was smaller compared to the wild type strain. The replacement of Cys98 and Cys111, or the double substitution Cys98/111 not led to an altered operon expression. The [Fe-S] cluster binding or not, is therefore responsible for the regulation of the isc operon in A. vinelandii as well as of other operons encoding proteins involved in electron tranport chains.

Eucalyptus grandis

Azotobacter vinelandii

Genes

Genética vegetal

Eucalyptus grandis

Azotobacter vinelandii

[Fe-S] cluster

RT-qPCR

Cold stress

IscR

Frameshifting as a tool in analysis of transfer RNA modification and translation

Leipuviene, Ramune

January 2004

Studies of ribosomal reading frame maintenance are often based on frameshift mutation suppression experiments. In this thesis, suppression of a frameshift mutation in Salmonella enterica serovar Typhimurium by a tRNA and a ribosomal protein are described. The +1 frameshift mutation hisC3072 (that contains an extra G in a run of Gs) is corrected by mutations in the argU gene coding for the minor tRNAArgmnm5UCU. The altered tRNAArgmnm5UCU has a decreased stability and reduced aminoacylation due to changed secondary and/or tertiary structure. Protein sequencing revealed that during the translation of the GAA-AGA frameshifting site the altered tRNAArgmnm5UCU reads the AGA codon inefficiently. This induces a ribosomal pause, allowing the tRNAGlumnm5s2UUC residing in the ribosomal P-site to slip forward one nucleotide. The same frameshift mutation (hisC3072) was also suppressed by defects in the large ribosomal subunit protein L9. Single base substitutions, truncations, and absence of this protein induced ribosome slippage. Mutated ribosome could shift to the overlapping codon in the +1 frame, or bypass to a codon further downstream in the +1 frame. The signal for stimulation of slippage and function of L9 needs to be investigated. During the search for suppressors of the hisD3749 frameshift mutation, a spontaneous mutant was isolated in the iscU gene that contained greatly decreased levels of the thiolated tRNA modifications ms2io6A and s2C. The iscU gene belongs to the iscR-iscSUA-hscBA-fdx operon coding for proteins involved in the assembly of [Fe-S] clusters. As has been shown earlier, IscS influences the synthesis of all thiolated nucleosides in tRNA by mobilizing sulfur from cysteine. In this thesis, it is demonstrated that IscU, HscA, and Fdx proteins are required for the synthesis of the tRNA modifications ms2io6A and s2C but are dispensable for the synthesis of s4U and (c)mnm5s2U. Based on these results it is proposed that two distinct pathways exist in the formation of thiolated nucleosides in tRNA: one is an [Fe-S] cluster-dependent pathway for the synthesis of ms2io6A and s2C and the other is an [Fe-S] cluster-independent pathway for the synthesis of s4U and (c)mnm5s2U. MiaB is a [Fe-S] protein required for the introduction of sulfur in ms2io6A. TtcA is proposed to be involved in the synthesis of s2C. This protein contains a CXXC conserved motif essential for cytidine thiolation that, together with an additional CXXC motif in the C-terminus may serve as an [Fe-S] cluster ligation site.

Molecular biology

minor tRNA

frameshifting

suppression

L9

hopping

tRNA thiolation

[Fe-S] cluster

[Fe-S] protein

TtcA

Molekylärbiologi

Molecular biology

Molekylärbiologi

Réalisation de nanofils de protéines / Making and caracterisation of protein nano-devices

Horvath, Christophe

26 September 2011

Ce travail de thèse propose de réaliser un nanofil électrique auto-assemblé constitué de protéines. L'unité de base de ce nanofil est une protéine chimère comprenant un domaine capable de former des fibres amyloïdes (Het-s 218-289) et un domaine capable d'effectuer des transferts d'électrons (une rubrédoxine). Le premier domaine permet la réalisation d'une fibre par auto-assemblage tandis que le deuxième est exposé à la surface de cette structure. Les caractéristiques redox du domaine exposé permettent aux électrons de se déplacer d'un bout à l'autre de la fibre par sauts successifs. Un tel nanofil a été créé et caractérisé par différentes techniques biophysiques. Ensuite, la preuve de la conduction des nanofils a été apportée sur des ensembles d'objets, de manière indirecte par électrochimie, et de manière directe par des mesures tension/courant. Ces travaux ouvrent la voie à la réalisation d'objets biocompatibles, biodégradables, possédant des propriétés électroniques exploitables dans des dispositifs technologiques. / The research described in this thesis aims at creating a self-assembled nanowire only made of proteins. The building block of this wire is a chimeric protein that comprises an amyloid fibril forming domain (Het-s 218-289) and an electron transfer domain (rubredoxin). The first one self-assembles in amyloid fibrils which display the second at their surface. Redox characteristics of the exposed domain allow electrons to move from one extremity of the fibril to the other by successive jumps. Such a nanowire has been created and characterized by various biophysical experiments. Then, the conductivity of the nanowires has been demonstrated on sets of wires by electrochemistry and by direct current measurements. These experiments pave the way for future design of biocompatible and biodegradable objects that possess usable electronic properties.

Nanofil

Fibre amyloïde

Complexe Fe-S

Auto-assemblage

Électronique moléculaire

Nanowire

Amyloid fibrils

Fe-S cluster

Self-assembling

Molecular electronic

530

Etude biochimique de mitoNEET humaine, protéine à centre [2Fe-2S], impliquée dans une voie de réparation des protéines Fe-S suite à un stress oxydatif / Biochemical studies of human mitoNEET, a [2Fe-2S] protein involved in a pathway dedicated to Fe-S protein repair after oxidative stress

Mons, Cécile

20 November 2017

Présente chez les mammifères, mitoNEET (mNT) est une protéine à centre Fe-S ancrée à la membrane externe de la mitochondrie. Cette protéine dimérique possède un centre [2Fe-2S] par monomère lié de façon atypique à la protéine par trois cystéines et une histidine. Notre équipe a auparavant montré l’implication de mNT dans une nouvelle voie de réparation du centre [4Fe-4S] de l’Iron Regulatory Protein-1 (IRP-1), régulateur majeur de l’homéostasie du fer intracellulaire, par transfert du centre Fe-S de mNT à l’IRP-1 à réparer. Au cours de ma thèse, je me suis focalisée sur la caractérisation in vitro de la réaction de transfert de centre Fe-S de mNT vers une protéine réceptrice modèle, l’apo-ferrédoxine d’E. coli. En combinant des approches de biochimie et biophysique (réalisées en collaboration) à l’aide de protéines purifiées, cette étude a permis de démontrer que mNT agit comme un interrupteur moléculaire : lorsque son centre Fe-S est réduit, la protéine est extrêmement stable et le centre ne peut être ni perdu ni transféré; une fois oxydé, il peut alors être transféré à une protéine réceptrice. La présence d’oxygène n’affecte pas cette réaction même s’il s’agit d’un déterminant majeur de la stabilité de la protéine. De plus, la vitesse de transfert du centre est très sensible au pH, ce qui fait de mNT un senseur de pH. Ces études ont aussi montré que mNT est extrêmement résistante à H2O2 en comparaison à d’autres protéines de transfert de centre Fe-S. J’ai également étudié l’interaction d’une molécule anti-oxydante, le resvératrol-3 sulfate, avec mNT. Pour finir, je me suis intéressée à l’effet du glutathion sur mNT. Acteur majeur de la régulation de l’homéostasie rédox, le glutathion existe sous deux formes: oxydée (GSSG) et réduite (GSH). J’ai alors constaté que le GSH déstabilise fortement mNT à certains pH et peut même se lier à cette protéine. La fonction thiol du GSH et la formation de radicaux sur cette dernière sont clairement impliquées dans la déstabilisation de mNT. / Present in mammals, mitoNEET (mNT) is an Fe-S protein anchored to the outer mitochondrial membrane. This dimeric protein contains a [2Fe-2S] per monomer with an atypical ligation involving three cysteines and one histidine. Previously, our team proposed that mNT is involved in a new pathway dedicated to the reparation of the oxidatively damaged [4Fe-4S] cluster of human iron-regulatory protein-1 (IRP-1)/cytosolic aconitase, a key player of the regulation of cellular iron homeostasis. This reparation occurs via Fe-S cluster transfer from mNT to IRP-1 to repair. In the course of my thesis, I focused on the characterization of cluster transfer reaction from mNT to a model receptor protein, the E. coli apo-ferredoxin. Using purified proteins and combining biochemical approaches with biophysical ones performed in colaboration, this study showed that mNT acts as a redox switch: when the Fe-S cluster is reduced, the protein is extremely stable and it cannot be lost or transferred; when it is oxidized, it can be transferred to a receptor protein. Dioxygen does not affect this transfer reaction whereas this is a major determinant of protein stability. The transfer speed is highly sensitive to pH. Thus, mNT seems to act also as a pH sensor. Moreover, this study shows that mNT is extremely resistant to H2O2 compared to other Fe-S cluster transfer proteins. I also looked at the interaction of an antioxidant molecule, the resveratrol-3-sulfate, with mNT. Finally, I studied the effects of glutathione on mNT. Major player of the regulation of redox homeostasis, glutathione exists under two states: a reduced state (GSH) and an oxidized one (GSSG). I observed that GSH strongly destabilizes mNT at specific pHs and can even directly interact with the protein. The thiol function of GSH and the radical formation on this function are clearly involved in the mNT Fe-S destabilization.

Biochimie des protéines

Protéines Fe-S

MitoNEET

Transfert et stabilité de centre Fe-S

Stabilité

Glutathion

Biochemistry of proteins

Iron Sulfur protein

MitoNEET

Fe-S cluster transfer and stability

Stability

Glutathione

Syntéza železo-sirných center v Monocercomonoides exilis / Iron-Sulfur cluster assembly in Monocercomonoides exilis

Vacek, Vojtěch

January 2020

In the search for the mitochondrion of oxymonads, DNA of Monocercomonoides exilis - an oxymonad isolated from the gut of Chinchilla, was isolated and its genome was sequenced. Sequencing resulted in a fairly complete genome which was extensively searched or genes for mitochondrion related proteins, but no reliable candidate for such gene was identified. Even genes for the ISC pathway, which is responsible for Fe-S cluster assembly and considered to be the only essential function of reduced mitochondrion-like organelles (MROs), were absent. Instead, we were able to detect the presence of a SUF pathway which functionally replaced the ISC pathway. Closer examination of the SUF pathway based on heterologous localisation revealed that this pathway localised in the cytosol. In silico analysis showed that SUF genes are highly conserved at the level of secondary and tertiary structure and most catalytic residues and motifs are present in their sequences. The functionality of these proteins was further indirectly confirmed by complementation experiments in Escherichia coli where SUF proteins of M. exilis were able to restore at least partially Fe-S cluster assembly of strains deficient in the SUF and ISC pathways. We also proved by bacterial adenylate cyclase two-hybrid system that SufB and SufC can form...

Die Analyse der Sauerstofftoleranz und biotechnologische Anwendung der NAD+-reduzierenden Hydrogenase aus Ralstonia eutropha H16

Lauterbach, Lars

30 May 2014

Die NAD+-reduzierende Hydrogenase aus Ralstonia eutropha (SH) katalysiert die reversible H2-Oxidation in Verbindung mit der Reduktion von NAD+ in Gegenwart von Sauerstoff. Die bemerkenswerte O2-Toleranz des Enzyms wurde zuvor auf eine für [NiFe]-Hydrogenasen ungewöhnliche Struktur des Wasserstoff-spaltenden Zentrums zurückgeführt. Diese Hypothese wurde in dieser Arbeit mittels in situ-Spektroskopie an SH-haltigen Zellen widerlegt. Um die folgende Untersuchung der aus sechs Untereinheiten und mindestens acht Kofaktoren bestehenden SH zu erleichtern, wurde das Enzym mittels genetischer Methoden in seine beiden Module aufgeteilt. Das die H2-Oxidation katalysierende Hydrogenase-Modul beinhaltete ein FMN-Molekül, welches für die reduktive Reaktivierung des oxidativ modifizierten Zentrums benötigt wird. Das Diaphorase-Modul besaß ebenfalls ein FMN, und die Reduktion von NAD+ wurde von der Anwesenheit von O2 nicht beeinträchtigt. Neben Wasserstoff reagierte das [NiFe]-Zentrum der SH auch mit Sauerstoff. Dabei wurde sowohl Wasserstoffperoxid- als auch Wasser im Hydrogenase-Modul freigesetzt. Die Sauerstofftoleranz der SH basiert auf einer kontinuierlichen Reaktivierung des durch Sauerstoff oxidierten [NiFe]-Zentrums. Aufgrund der außergewöhnlichen Sauerstofftoleranz stellt die SH ein vielversprechendes System für die wasserstoffgetriebene Regeneration von NADH in gekoppelten enzymatischen Reaktionen dar. In dieser Arbeit wurde ein SH-Derivat durch rationale Mutagenese konstruiert, das in der Lage war, ebenso den Kofaktor NADP+ wasserstoffabhängig zu reduzieren. Durch Ganzzellansätze kann die zeitaufwändige und kostenintensive Proteinreinigung vermieden werden. Um die wasserstoffabhängige in-vivo-Kofaktorregeneration zu ermöglichen, wurde die SH in Pseudomonas putida heterolog produziert. Die in dieser Arbeit erzielten Ergebnisse sind sowohl für das molekulare Verständnis der H2-abhängigen Katalyse als auch für die biotechnologische Anwendung der O2-toleranten SH relevant. / The NAD+ reducing hydrogenase from Ralstonia eutropha (SH) catalyzes the reversible oxidation of hydrogen in connection with the reduction of NAD+ in the presence of oxygen. The remarkable oxygen tolerance was previously related to an unusual [NiFe] active site with four instead of two cyanide ligands. This hypothesis was rejected in this study by using in situ spectroscopy on SH containing cells. To simplify the investigation of the six-subunit and at least eight cofactors containing SH, the enzyme was separated into its two modules by genetic methods. The hydrogen oxidizing hydrogenase module contained one FMN molecule, which was required for the reductive reactivation of the oxidatively modified active site. The diaphorase module carried a second FMN. The reduction of NAD+ was not affected by the presence of oxygen. In addition to hydrogen, the [NiFe] center of the SH reacted with oxygen. Both hydrogen peroxide and water were released by the hydrogenase module. The oxygen tolerance of the SH is based on a continuous reactivation of the oxidized [NiFe] center. Due to the oxygen tolerance, the SH is a promising system for hydrogen based NADH regeneration in coupled enzymatic reactions. In this study a SH derivative was constructed by means of rational mutagenesis. The SH derivative was able to reduce the cofactor NADP+ by hydrogen oxidation. The time consuming and costly protein purification can be avoided by using whole cell approaches. In order to allow the hydrogen dependent in vivo cofactor regeneration, SH was heterologously produced in Pseudomonas putida. The results obtained in this study are relevant for the molecular understanding of hydrogen dependent catalysis and for the biotechnological application of the oxygen tolerant SH.

Elektrochemie

Wasser

Hydrogenase

Eisen-Schwefel-Cluster

Ralstonia eutropha

Sauerstofftoleranz

Aktives Zentrum

NADH-Regeneration

Diaphorase

FTIR

Komplex I

FMN

Flavinmononukleotid

Wasserstoffperoxid

FTIR

electrochemistry

water

oxygen tolerance

Ralstonia eutropha

active site

hydrogenase

NADH regeneration

diaphorase

Complex I

Fe-S Cluster

FMN

flavin mononucleotide

hydrogen peroxide

570 Biowissenschaften, Biologie

32 Biologie

WD 5050

ddc:570