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Evolution of structure-function relationships in the GFP-family of proteinsModi, Chintan Kishore 16 September 2014 (has links)
One of the most intriguing questions in evolutionary biology is how biochemical and structural complexity arise through small and incremental changes; however answering this question requires an explicit set of candidate residues and an experimental system in which to test them. This dissertation aims to understand how biochemical complexity evolves and assesses the structure-function relationship in the green fluorescent protein (GFP) protein family using an ancestral reconstruction approach. In the second chapter, I studied the evolution of biochemical complexity in Kaede-type red fluorescent proteins (FPs) from Faviina corals. An increase in biochemical complexity is represented by the emergence of red fluorescence because it necessitates the synthesis of a tri-cyclic chromophore from a precursor bi-cyclic chromophore through an additional autocatalytic reaction step. The autocatalytic reaction is fully enabled by as many as twelve historical mutations. Here, I showed that the red fluorescent chromophore evolved from an ancestral green chromophore by perturbing the ancestral protein stability at multiple levels of protein structure. Moreover, only three historical mutations are sufficient to initiate the selection-accessible evolutionary trajectory leading to emergence of red fluorescence. The third chapter investigates six mutations proximate to the chromophore in the Kaede-type FP that could have facilitated autocatalytic synthesis of the red chromophore by enlarging the chromophore-containing cavity and modifying its microenvironment. Two of these six mutations were found to strongly affect the protein’s stability and oligomeric tendency. Additionally, I showed that the dimeric least divergent Kaede-type FP, R1-2, evolved from the tetrameric green ancestor. Taken together the results of these studies indicate that the step-up in biochemical complexity in the Kaede-type FPs was achieved via disruption of the existing stable interactions at tertiary and quaternary protein structure levels. In the fourth chapter, I resurrected the common ancestor of all FPs cloned from the order Leptothecata (class Hydrozoa), which are characterized by the highest known homo-oligomeric diversity. I showed that the ancestor was a green monomeric FP with a large Stokes shift. The ancestral FP together with the extant Leptothecata FPs could server as a model system to study the evolution of function and homo-oligomerization, and the desirable photophysical characteristics would make this ancestral FP a useful bio-marker in bio-medical research. / text
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Investigating the Stoichiometry of RuBisCO Activase by Fluorescence Fluctuation SpectroscopyJanuary 2014 (has links)
abstract: Ribulose-1, 5-bisphosphate carboxylase oxygenase, commonly known as RuBisCO, is an enzyme involved in carbon fixation in photosynthetic organisms. The enzyme is subject to a mechanism-based deactivation during its catalytic cycle. RuBisCO activase (Rca), an ancillary enzyme belonging to the AAA+ family of the ATP-ases, rescues RuBisCO by facilitating the removal of the tightly bound sugar phosphates from the active sites of RuBisCO. In this work, we investigated the ATP/ADP dependent oligomerization equilibrium of fluorescently tagged Rca for a wide range of concentrations using fluorescence correlation spectroscopy. Results show that in the presence of ADP-Mg2+, the oligomerization state of Rca gradually changes in steps of two subunits. The most probable association model supports the dissociation constants (K_d) of ∼4, 1, 1 μM for the monomer-dimer, dimer-tetramer, and tetramer-hexamer equlibria, respectively. Rca continues to assemble at higher concentrations which are indicative of the formation of aggregates. In the presence of ATP-Mg2+, a similar stepwise assembly is observed. However, at higher concentrations (30-75 µM), the average oligomeric size remains relatively unchanged around six subunits per oligomer. This is in sharp contrast with observations in ADP-Mg2+, where a marked decrease in the diffusion coefficient of Rca was observed, consistent with the formation of aggregates. The estimated K_d values obtained from the analysis of the FCS decays were similar for the first steps of the assembly process in both ADP-Mg2+ and ATP-Mg2+. However, the formation of the hexamer from the tetramer is much more favored in ATP-Mg2+, as evidenced from 20 fold lower K_d associated with this assembly step. This suggests that the formation of a hexameric ring in the presence of ATP-Mg2+. In addition to that, Rca aggregation is largely suppressed in the presence of ATP-Mg2+, as evidenced from the 1000 fold larger K_d value for the hexamer-24 mer association step. In essence, a fluorescence-based method was developed to monitor in vitro protein oligomerization and was successfully applied with Rca. The results provide a strong hint at the active oligomeric structure of Rca, and this information will hopefully help the ongoing research on the mechanistic enzymology of Rca. / Dissertation/Thesis / Ph.D. Chemistry 2014
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Characterization and Inhibition of the Dimer Interface in Bacterial Small Multidrug Resistance ProteinsPoulsen, Bradley E. 19 December 2012 (has links)
As one of the mechanisms of antibiotic resistance, bacteria use several families of membrane-embedded α-helical transporters to remove cytotoxic molecules from the cell. The small multidrug resistance protein family (SMR) is one such group of drug transporters that because of their relative small size [ca. 110 residues with four transmembrane (TM) helices] must form at the minimum dimers to efflux drugs. We have used the SMR homologue Hsmr from Halobacterium salinarum to investigate the oligomerization properties of the protein family at TM helix 4. We produced point mutations along the length of the TM4 helix in the full length Hsmr protein and assayed their dimerization and functional properties via SDS-PAGE and bacterial cell growth assays. We found that Hsmr forms functionally dependent dimers via an evolutionarily conserved 90GLxLIxxGV98 small residue heptad repeat. Upon investigation of the large hydrophobic residues in this motif by substituting each large residue to Ile, Leu, Met, Phe, and Val, we determined that Hsmr efflux function relies on an optimal level of dimerization. While some substitutions led to either decreased or increased dimer and substrate-binding strength, several Ile94 and Val98 mutants were equal to wild type dimerization levels but were nonfunctional, leading to the hypothesis of a mechanistic role at TM4 in addition to the locus of dimerization. The functionally sensitive TM4 dimer represents a potential target for SMR inhibition using a synthetic TM4 peptide mimetic. Using exponential decay measurements from a real-time cellular efflux assay, we observed the efflux decay constant was decreased by up to ~60% after treatment with the TM4 peptide inhibitor compared to control peptide treatments. Our results suggest that this approach could conceivably be used to design hydrophobic peptides for disruption of key TM-TM interactions of membrane proteins, and represent a valuable route to the discovery of new therapeutics.
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Characterization and Inhibition of the Dimer Interface in Bacterial Small Multidrug Resistance ProteinsPoulsen, Bradley E. 19 December 2012 (has links)
As one of the mechanisms of antibiotic resistance, bacteria use several families of membrane-embedded α-helical transporters to remove cytotoxic molecules from the cell. The small multidrug resistance protein family (SMR) is one such group of drug transporters that because of their relative small size [ca. 110 residues with four transmembrane (TM) helices] must form at the minimum dimers to efflux drugs. We have used the SMR homologue Hsmr from Halobacterium salinarum to investigate the oligomerization properties of the protein family at TM helix 4. We produced point mutations along the length of the TM4 helix in the full length Hsmr protein and assayed their dimerization and functional properties via SDS-PAGE and bacterial cell growth assays. We found that Hsmr forms functionally dependent dimers via an evolutionarily conserved 90GLxLIxxGV98 small residue heptad repeat. Upon investigation of the large hydrophobic residues in this motif by substituting each large residue to Ile, Leu, Met, Phe, and Val, we determined that Hsmr efflux function relies on an optimal level of dimerization. While some substitutions led to either decreased or increased dimer and substrate-binding strength, several Ile94 and Val98 mutants were equal to wild type dimerization levels but were nonfunctional, leading to the hypothesis of a mechanistic role at TM4 in addition to the locus of dimerization. The functionally sensitive TM4 dimer represents a potential target for SMR inhibition using a synthetic TM4 peptide mimetic. Using exponential decay measurements from a real-time cellular efflux assay, we observed the efflux decay constant was decreased by up to ~60% after treatment with the TM4 peptide inhibitor compared to control peptide treatments. Our results suggest that this approach could conceivably be used to design hydrophobic peptides for disruption of key TM-TM interactions of membrane proteins, and represent a valuable route to the discovery of new therapeutics.
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Estudos estruturais e funcionais dos receptores ativadores da proliferação de peroxissomos / Structural and functional studies of peroxisome proliferator-activated receptorMuniz, Amanda Bernardes 17 May 2013 (has links)
Os receptores ativadores da proliferação de peroxissomos (PPARs) pertencem à superfamília de receptores nucleares que funcionam como fatores transcricionais. Eles exercem um papel fundamental em processos que envolvem, principalmente, o metabolismo lipídico, em resposta à ativação por ligantes naturais e sintéticos como os ácidos graxos e os fibratos, respectivamente. A crescente descoberta de importantes funções fisiológicas, coordenadas pelos PPARs, e a necessidade de se conhecer como os agonistas, atualmente disponíveis, atuam nesses receptores, têm incitado pesquisas que vislumbram sua melhor exploração nos tratamentos de doenças metabólicas e inflamatórias, minimizando os efeitos adversos de ativações suprafisiológicas. Nesse cenário, o presente trabalho buscou compreender melhor as bases estruturais envolvidas nas funções atribuídas aos PPARs e explicar como as interações com seus ligantes ocorrem. Para isso, foram realizadas a subclonagem do domínio de ligação ao ligante do PPARα, sua expressão e purificação, seguidas de ensaios cristalográficos e biofísicos, além da abordagem de testes funcionais. Uma vez que a formação de oligômeros está relacionada à funcionalidade desses receptores, foram abordados estudos de oligomerização dos PPARs α e γ, compreendendo tanto o processo de homo- quanto o de heterodimerização. Os ensaios de cristalização do hPPARα LBD complexado a ligantes naturais e sintéticos, resultaram em estruturas cristalográficas que permitiram a identificação dos resíduos envolvidos no reconhecimento dos ligantes e a caracterização de sítios de ligação nunca antes descritos. A presença de ligantes nessas regiões afeta a conformação da proteína e, consequentemente, a modulação de sua função e o recrutamento da maquinaria transcricional. Adicionalmente, as estruturas cristalográficas da proteína complexada a ácidos graxos auxiliaram na compreensão de como essa importante classe de ligantes naturais possui efeitos farmacológicos similares aos de ligantes sintéticos. Esses resultados têm imediato impacto na procura racional de agonistas para esses receptores e se inserem em uma perspectiva de promoção do desenvolvimento científico-tecnológico na área de endocrinologia molecular. / The peroxisome proliferation-activated receptors (PPARs) belong to the nuclear receptors superfamily, acting as transcriptional factors. They play a key role in processes involving essentially lipid metabolism in response to activation by natural and synthetic ligands such as fatty acids and fibrates, respectively. The rising discovery of important physiological functions coordinated by PPARs and the necessity to know how the currently available agonists act on these receptors, have encouraged researches envisioning a better receptor exploration in the treatment of metabolic and inflammatory diseases, minimizing the adverse effects of supraphysiological activations. In this scenario, the present study aimed to better understand the structural basis involved in PPARs functions and elucidates how the interactions with their ligands takes place. For this, the ligand-binding domain of PPARα was subjected to subcloning, expression and purification steps, followed by crystallographical and biophysical assays, in addition to functional testing approaches. Since the degree of oligomerization is related to the functionality of these receptors, oligomeric studies of PPARs α and γ oligomerization were also achieved, comprising both homo- and hetero-dimerization. The co-crystallization assays of hPPARα LBD complexed with natural and synthetic ligands resulted in crystallographic structures that allowed the identification of residues involved in ligand recognition and the characterization of novel binding sites. The presence of ligands in these regions affects the conformation of the protein and thereby modulates their function and transcriptional machinery recruitment. Additionally, the crystallographic structures of the protein complexed to fatty acids were valuable for the understanding of how this important class of natural ligands has similar pharmacological effects to those of synthetic ligands. These results have direct impact on rational agonists design to these receptors and are inserted in a perspective of scientifical promotion and technological development in the field of molecular endocrinology.
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Estudos estruturais e funcionais dos receptores ativadores da proliferação de peroxissomos / Structural and functional studies of peroxisome proliferator-activated receptorAmanda Bernardes Muniz 17 May 2013 (has links)
Os receptores ativadores da proliferação de peroxissomos (PPARs) pertencem à superfamília de receptores nucleares que funcionam como fatores transcricionais. Eles exercem um papel fundamental em processos que envolvem, principalmente, o metabolismo lipídico, em resposta à ativação por ligantes naturais e sintéticos como os ácidos graxos e os fibratos, respectivamente. A crescente descoberta de importantes funções fisiológicas, coordenadas pelos PPARs, e a necessidade de se conhecer como os agonistas, atualmente disponíveis, atuam nesses receptores, têm incitado pesquisas que vislumbram sua melhor exploração nos tratamentos de doenças metabólicas e inflamatórias, minimizando os efeitos adversos de ativações suprafisiológicas. Nesse cenário, o presente trabalho buscou compreender melhor as bases estruturais envolvidas nas funções atribuídas aos PPARs e explicar como as interações com seus ligantes ocorrem. Para isso, foram realizadas a subclonagem do domínio de ligação ao ligante do PPARα, sua expressão e purificação, seguidas de ensaios cristalográficos e biofísicos, além da abordagem de testes funcionais. Uma vez que a formação de oligômeros está relacionada à funcionalidade desses receptores, foram abordados estudos de oligomerização dos PPARs α e γ, compreendendo tanto o processo de homo- quanto o de heterodimerização. Os ensaios de cristalização do hPPARα LBD complexado a ligantes naturais e sintéticos, resultaram em estruturas cristalográficas que permitiram a identificação dos resíduos envolvidos no reconhecimento dos ligantes e a caracterização de sítios de ligação nunca antes descritos. A presença de ligantes nessas regiões afeta a conformação da proteína e, consequentemente, a modulação de sua função e o recrutamento da maquinaria transcricional. Adicionalmente, as estruturas cristalográficas da proteína complexada a ácidos graxos auxiliaram na compreensão de como essa importante classe de ligantes naturais possui efeitos farmacológicos similares aos de ligantes sintéticos. Esses resultados têm imediato impacto na procura racional de agonistas para esses receptores e se inserem em uma perspectiva de promoção do desenvolvimento científico-tecnológico na área de endocrinologia molecular. / The peroxisome proliferation-activated receptors (PPARs) belong to the nuclear receptors superfamily, acting as transcriptional factors. They play a key role in processes involving essentially lipid metabolism in response to activation by natural and synthetic ligands such as fatty acids and fibrates, respectively. The rising discovery of important physiological functions coordinated by PPARs and the necessity to know how the currently available agonists act on these receptors, have encouraged researches envisioning a better receptor exploration in the treatment of metabolic and inflammatory diseases, minimizing the adverse effects of supraphysiological activations. In this scenario, the present study aimed to better understand the structural basis involved in PPARs functions and elucidates how the interactions with their ligands takes place. For this, the ligand-binding domain of PPARα was subjected to subcloning, expression and purification steps, followed by crystallographical and biophysical assays, in addition to functional testing approaches. Since the degree of oligomerization is related to the functionality of these receptors, oligomeric studies of PPARs α and γ oligomerization were also achieved, comprising both homo- and hetero-dimerization. The co-crystallization assays of hPPARα LBD complexed with natural and synthetic ligands resulted in crystallographic structures that allowed the identification of residues involved in ligand recognition and the characterization of novel binding sites. The presence of ligands in these regions affects the conformation of the protein and thereby modulates their function and transcriptional machinery recruitment. Additionally, the crystallographic structures of the protein complexed to fatty acids were valuable for the understanding of how this important class of natural ligands has similar pharmacological effects to those of synthetic ligands. These results have direct impact on rational agonists design to these receptors and are inserted in a perspective of scientifical promotion and technological development in the field of molecular endocrinology.
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Mechanism of Action of Insecticidal Crystal Toxins from <i>Bacillus thuringiensis:</i> Biophysical and Biochemical Analyses of the Insertion of Cry1A Toxins into Insect Midgut MembranesNair, Manoj Sadasivan 11 September 2008 (has links)
No description available.
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Investigating AmrZ-mediated activation of <i>Pseudomonas aeruginosa</i> twitching motility and alginate productionXu, Binjie January 2015 (has links)
No description available.
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Étude structurale du mode de liaison des protéines Whirly de plantes à l’ADN monocaténaireCappadocia, Laurent 12 1900 (has links)
Les plantes doivent assurer la protection de trois génomes localisés dans le noyau, les chloroplastes et les mitochondries. Si les mécanismes assurant la réparation de l’ADN nucléaire sont relativement bien compris, il n’en va pas de même pour celui des chloroplastes et des mitochondries. Or il est important de bien comprendre ces mécanismes puisque des dommages à l’ADN non ou mal réparés peuvent entraîner des réarrangements dans les génomes. Chez les plantes, de tels réarrangements dans l’ADN mitochondrial ou dans l’ADN chloroplastique peuvent conduire à une perte de vigueur ou à un ralentissement de la croissance. Récemment, notre laboratoire a identifié une famille de protéines, les Whirly, dont les membres se localisent au niveau des mitochondries et des chloroplastes. Ces protéines forment des tétramères qui lient l’ADN monocaténaire et qui accomplissent de nombreuses fonctions associées au métabolisme de l’ADN. Chez Arabidopsis, deux de ces protéines ont été associées au maintien de la stabilité du génome du chloroplaste. On ignore cependant si ces protéines sont impliquées dans la réparation de l’ADN.
Notre étude chez Arabidopsis démontre que des cassures bicaténaires de l’ADN sont prises en charge dans les mitochondries et les chloroplastes par une voie de réparation dépendant de très courtes séquences répétées (de cinq à cinquante paires de bases) d’ADN. Nous avons également montré que les protéines Whirly modulent cette voie de réparation. Plus précisément, leur rôle serait de promouvoir une réparation fidèle de l’ADN en empêchant la formation de réarrangements dans les génomes de ces organites. Pour comprendre comment les protéines Whirly sont impliquées dans ce processus, nous avons élucidé la structure cristalline d’un complexe Whirly-ADN. Nous avons ainsi pu montrer que les Whirly lient et protègent l’ADN monocaténaire sans spécificité de séquence. La liaison de l’ADN s’effectue entre les feuillets β de sous-unités contiguës du tétramère. Cette configuration maintient l’ADN sous une forme monocaténaire et empêche son appariement avec des acides nucléiques de séquence complémentaire. Ainsi, les protéines Whirly peuvent empêcher la formation de réarrangements et favoriser une réparation fidèle de l’ADN. Nous avons également montré que, lors de la liaison de très longues séquences d’ADN, les protéines Whirly peuvent s’agencer en superstructures d’hexamères de tétramères, formant ainsi des particules sphériques de douze nanomètres de diamètre. En particulier, nous avons pu démontrer l’importance d’un résidu lysine conservé chez les Whirly de plantes dans le maintien de la stabilité de ces superstructures, dans la liaison coopérative de l’ADN, ainsi que dans la réparation de l’ADN chez Arabidopsis. Globalement, notre étude amène de nouvelles connaissances quant aux mécanismes de réparation de l’ADN dans les organites de plantes ainsi que le rôle des protéines Whirly dans ce processus. / Plants must protect the integrity of three genomes located respectively in the nucleus, the chloroplasts and the mitochondria. Although DNA repair mechanisms in the nucleus are the subject of multiple studies, little attention has been paid to DNA repair mechanisms in chloroplasts and mitochondria. This is unfortunate since mutations in the chloroplast or the mitochondrial genome can lead to altered plant growth and development. Our laboratory has identified a new family of proteins, the Whirlies, whose members are located in plant mitochondria and chloroplasts. These proteins form tetramers that bind single-stranded DNA and play various roles associated with DNA metabolism. In Arabidopsis, two Whirly proteins maintain chloroplast genome stability. Whether or not these proteins are involved in DNA repair has so far not been investigated.
Our studies in Arabidopsis demonstrate that DNA double-strand breaks are repaired in both mitochondria and chloroplasts through a microhomology-mediated repair pathway and indicate that Whirly proteins affect this pathway. In particular, the role of Whirly proteins would be to promote accurate repair of organelle DNA by preventing the repair of DNA double-strand breaks by the microhomology-dependant pathway. To understand how Whirly proteins mediate this function, we solved the crystal structure of Whirly-DNA complexes. These structures show that Whirly proteins bind single-stranded DNA with low sequence specificity. The DNA is maintained in an extended conformation between the β-sheets of adjacent protomers, thus preventing spurious annealing with a complementary strand. In turn, this prevents formation of DNA rearrangements and favors accurate DNA repair. We also show that upon binding long ssDNA sequences, Whirly proteins assemble into higher order structures, or hexamers of tetramers, thus forming spherical particles of twelve nanometers in diameter. We also demonstrate that a lysine residue conserved among plant Whirly proteins is important for the stability of these higher order structures as well as for cooperative binding to DNA and for DNA repair. Overall, our study elucidates some of the mechanisms of DNA repair in plant organelles as well as the roles of Whirly proteins in this process.
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Étude structurale du mode de liaison des protéines Whirly de plantes à l’ADN monocaténaireCappadocia, Laurent 12 1900 (has links)
Les plantes doivent assurer la protection de trois génomes localisés dans le noyau, les chloroplastes et les mitochondries. Si les mécanismes assurant la réparation de l’ADN nucléaire sont relativement bien compris, il n’en va pas de même pour celui des chloroplastes et des mitochondries. Or il est important de bien comprendre ces mécanismes puisque des dommages à l’ADN non ou mal réparés peuvent entraîner des réarrangements dans les génomes. Chez les plantes, de tels réarrangements dans l’ADN mitochondrial ou dans l’ADN chloroplastique peuvent conduire à une perte de vigueur ou à un ralentissement de la croissance. Récemment, notre laboratoire a identifié une famille de protéines, les Whirly, dont les membres se localisent au niveau des mitochondries et des chloroplastes. Ces protéines forment des tétramères qui lient l’ADN monocaténaire et qui accomplissent de nombreuses fonctions associées au métabolisme de l’ADN. Chez Arabidopsis, deux de ces protéines ont été associées au maintien de la stabilité du génome du chloroplaste. On ignore cependant si ces protéines sont impliquées dans la réparation de l’ADN.
Notre étude chez Arabidopsis démontre que des cassures bicaténaires de l’ADN sont prises en charge dans les mitochondries et les chloroplastes par une voie de réparation dépendant de très courtes séquences répétées (de cinq à cinquante paires de bases) d’ADN. Nous avons également montré que les protéines Whirly modulent cette voie de réparation. Plus précisément, leur rôle serait de promouvoir une réparation fidèle de l’ADN en empêchant la formation de réarrangements dans les génomes de ces organites. Pour comprendre comment les protéines Whirly sont impliquées dans ce processus, nous avons élucidé la structure cristalline d’un complexe Whirly-ADN. Nous avons ainsi pu montrer que les Whirly lient et protègent l’ADN monocaténaire sans spécificité de séquence. La liaison de l’ADN s’effectue entre les feuillets β de sous-unités contiguës du tétramère. Cette configuration maintient l’ADN sous une forme monocaténaire et empêche son appariement avec des acides nucléiques de séquence complémentaire. Ainsi, les protéines Whirly peuvent empêcher la formation de réarrangements et favoriser une réparation fidèle de l’ADN. Nous avons également montré que, lors de la liaison de très longues séquences d’ADN, les protéines Whirly peuvent s’agencer en superstructures d’hexamères de tétramères, formant ainsi des particules sphériques de douze nanomètres de diamètre. En particulier, nous avons pu démontrer l’importance d’un résidu lysine conservé chez les Whirly de plantes dans le maintien de la stabilité de ces superstructures, dans la liaison coopérative de l’ADN, ainsi que dans la réparation de l’ADN chez Arabidopsis. Globalement, notre étude amène de nouvelles connaissances quant aux mécanismes de réparation de l’ADN dans les organites de plantes ainsi que le rôle des protéines Whirly dans ce processus. / Plants must protect the integrity of three genomes located respectively in the nucleus, the chloroplasts and the mitochondria. Although DNA repair mechanisms in the nucleus are the subject of multiple studies, little attention has been paid to DNA repair mechanisms in chloroplasts and mitochondria. This is unfortunate since mutations in the chloroplast or the mitochondrial genome can lead to altered plant growth and development. Our laboratory has identified a new family of proteins, the Whirlies, whose members are located in plant mitochondria and chloroplasts. These proteins form tetramers that bind single-stranded DNA and play various roles associated with DNA metabolism. In Arabidopsis, two Whirly proteins maintain chloroplast genome stability. Whether or not these proteins are involved in DNA repair has so far not been investigated.
Our studies in Arabidopsis demonstrate that DNA double-strand breaks are repaired in both mitochondria and chloroplasts through a microhomology-mediated repair pathway and indicate that Whirly proteins affect this pathway. In particular, the role of Whirly proteins would be to promote accurate repair of organelle DNA by preventing the repair of DNA double-strand breaks by the microhomology-dependant pathway. To understand how Whirly proteins mediate this function, we solved the crystal structure of Whirly-DNA complexes. These structures show that Whirly proteins bind single-stranded DNA with low sequence specificity. The DNA is maintained in an extended conformation between the β-sheets of adjacent protomers, thus preventing spurious annealing with a complementary strand. In turn, this prevents formation of DNA rearrangements and favors accurate DNA repair. We also show that upon binding long ssDNA sequences, Whirly proteins assemble into higher order structures, or hexamers of tetramers, thus forming spherical particles of twelve nanometers in diameter. We also demonstrate that a lysine residue conserved among plant Whirly proteins is important for the stability of these higher order structures as well as for cooperative binding to DNA and for DNA repair. Overall, our study elucidates some of the mechanisms of DNA repair in plant organelles as well as the roles of Whirly proteins in this process.
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