Structural studies of binding proteins : investigations of flexibility, specificity and stability /

Magnusson, Ulrika,

January 2003

Diss. (sammanfattning) Uppsala : Univ., 2003. / Härtill 3 uppsatser.

Periplasmic binding proteins.

Characterisation of a novel protein export pathway in Escherichia coli

Stanley, Nicola Ruth

January 2000

No description available.

572

Periplasmic proteins; Tat signal peptide

Novel octaheme cytochrome c tetrathionate reductase (OTR) from Shewanella oneidensis MR-1

Wu, Fei

January 2010

Octa-heme cytochrome c tetrathionate reductase (OTR) from Shewanella oneidensis MR-1 is a periplasmic protein and shows several extraordinary structural features around its active-site heme. OTR has been found able to catalyse the in vitro reduction of tetrathionate, nitrite, hydroxylamine and hydrogen peroxide. However the physiological function of this novel protein remains unknown. The subject of this thesis is the in vitro catalytic mechanism and the in vivo function of OTR. As OTR displays great similarity with bacterial penta-heme cytochrome c nitrite reductase (NrfA) in several aspects, it has been proposed that OTR might be physiologically involved in the metabolism of nitrite or other nitrogenous compounds. However kinetics assays and phenotypes studies carried out in this project suggest this is not the case. In vitro kinetic assays of the reduction of nitrite and hydroxylamine catalysed by OTR showed no significant difference in enzyme activities among the wild-type OTR and its mutant forms which have one active site residue replaced by alanine, namely OTR K153A, C64A, N61A and D150A. And the nitrite reductase activity of OTR (kcat/Km = 1.0×105 M-1•s-1) are much lower than that of NrfA (kcat/Km = ~108 M-1•s-1). These results indicate that OTR is not specifically adapted to reduce nitrite and it cannot compete for nitrite against NrfA in vivo. No phenotype difference was identified between the wild-type and the Δotr strain of Shewanella oneidensis MR-1 when nitrite or nitrate served as the sole electron acceptor. OTR appears not to be involved in the respiration or detoxification of nitrite, which is consistent with previous transcriptional and phenotype reports that involve OTR or its homologues. The in vitro tetrathionate reduction activity of OTR was unable to be reproduced in this project for unknown reasons. Although transcriptomic data from the literature suggest that OTR may be related to the metabolism of sulphur-containing compounds, kinetic and phenotype studies reveal that OTR does not directly participate in the respiration of thiosulfate, sulfite, tetrathionate, polysulfide or elemental sulphur. Cysteine 64 is a highly-conserved amino acid residue of OTR close to the active site and its side-chain sulphur atom is covalently bonded by either an oxygen or a sulphur atom as observed in the crystal structure. Such a modification is potentially important to the function of OTR. ESI mass spectroscopy results show that in native OTR the modified form is around 48 Da heavier than the unmodified form, and the MALDITOF peptide mass spectra show that the modified form could be converted into the unmodified form by reducing agent DTT. These results suggest that the modification could be a cysteine persulfide attaching an extra oxygen atom in the form of water or hydroxide anion.

579

Structural and Biochemical Studies of the Metal Binding Protein CusF and its Role in Escherichia coli Copper Homeostasis

Loftin, Isabell

January 2008

Biometals such as copper, cobalt and zinc are essential to life. These transition metals are used as cofactors in many enzymes. Nonetheless, these metals cause deleterious effects if their intracellular concentration exceeds the cells' requirement. Prokaryotic organisms usually employ efflux systems to maintain metals in appropriate intracellular concentrations.The Cus system of Escherichia coli plays a crucial part in the copper homeostasis of the organism. This system is a tetrapartite efflux system, which includes an additional component compared to similar efflux systems. This fourth component is a small periplasmic protein, CusF. CusF is essential for full copper resistance, yet its role within the Cus system has not been characterized. It could potentially serve in the role of a metallochaperone or as a regulator to the Cus system.To gain insight into the molecular mechanism of resistance of this system, I have structurally and biochemically characterized CusF. Using X-ray crystallography I determined the CusF structure. CusF displays a novel fold for a copper binding protein. Through multiple sequence alignment and NMR chemical shift experiments, I proposed a metal binding site in CusF, which I confirmed through determination of the structure of CusF-Ag(I). CusF displays a novel coordination of Ag(I) and Cu(I) through a Met2His motif and a cation-pi interaction between the metal ion and a tryptophan sidechain. Furthermore, I have shown that CusF binds Cu(I) and Ag(I) specifically and tightly.I investigated the role of the tryptophan at the binding site to establish its effect on metal binding and function of CusF. I have shown through competitive binding assays, NMR studies and through collaborative EXAFS studies that the tryptophan plays an essential role in CusF metal handling. The affinity of CusF for Cu(I) is influenced by this residue. Moreover, the tryptophan also caps the binding site such that oxidation of the bound metal as well access to adventitious ligands is prevented. In summary, these findings show that the structure and metal site of CusF are unique and are specifically designed to perform the function of CusF as a metallochaperone to the Cus system.

copper

metallochaperone

periplasmic protein

copper chaperone

copper homeostasis

protein structure

Mucosal immunity in the respiratory tract : the role of IgA in protection against intracellular pathogens /

Rodrʹiguez Muñoz, Ariane,

January 2005

Diss. (sammanfattning) Stockholm : Univ., 2005. / Härtill 4 uppsatser.

Estudo de proteínas GGDEF-EAL em vias de sinalização de c-di-GMP em Xanthomonas citri subsp. citri / Study of GGDEF-EAL proteins in c-di-GMP pathways in Xanthomonas citri subsp. citri

Teixeira, Raphael Dias

17 April 2015

Segundos mensageiros nucleotídicos são amplamente utilizados por bactérias para se adaptar às mudanças ambientais e fisiológicas. Neste cenário destaca-se o c-di-GMP, um segundo mensageiro praticamente universal em bactérias responsável por controlar a transição do estilo de vida bacteriano. Em geral, altos níveis celulares de c-di-GMP promovem um estado séssil, de formação de biofilme, enquanto baixos níveis induzem a motilidade. Xanthomonas citri subsp. citri (Xac), um fitopatógeno de grande importância econômica no Brasil, possui uma complexa regulação da sinalização de c-di-GMP, possuindo mais de 30 proteínas envolvidas na síntese, na degradação e na detecção deste segundo mensageiro. Dentre essas proteínas, destacam-se as que possuem os domínios de síntese e degradação presentes na mesma cadeia polipetídica, os domínios GGDEF e EAL respectivamente. A análise das estruturas primárias das 11 proteínas GGDEF-EAL codificadas pelo genoma de Xac revelou que a maior parte delas (6) provavelmente possui o domínio GGDEF inativo, enquanto o EAL é ativo. Três possivelmente possuem ambos os domínios ativos enquanto outras duas possuem ambos os domínios inativos. O nocaute do gene xac2382 que codifica uma dessas proteínas (que possui um domínio periplasmático seguido dos domínios citoplasmáticos HAMP-GGDEF-EAL), demonstra um aumento de motilidade e uma diminuição na formação de biofilme. Construções de fragmentos da proteína revelaram que XAC2382 necessita pelo menos dos domínios HAMP-GGDEF para complementar a cepa nocaute e que a atividade de diguanilato ciclase é essencial para isto. O domínio periplasmático de XAC2382 se mostrou interagir com XAC2383, uma proteína codificada por um gene presente no mesmo cluster do gene de XAC2382, e essa interação parece importante para o controle da motilidade de Xac. A estrutura de XAC2383 foi resolvida por cristalografia de raios X na qual foi revelada uma topologia típica de proteínas da família das periplasmic binding proteins (PBPs) possuindo ainda uma cavidade carregada positivamente contendo um motivo Ser-Thr-Ser (amnioácidos 152-154) importante para a ligação de compostos com grupos fosfatos ou fosfonatos. A mutação sítio dirigida nesse motivo aboliu os efeitos na motilidade dependentes dessa proteína. Esses resultados sugerem que XAC2383 é um sensor periplasmático de um composto eletronegativo e esta proteína interage com XAC2382 regulando a motilidade bacteriana. XAC0495, uma proteína com ambos os domínios GGDEF-EAL provavelmente inativos, pode fazer parte de um sistema de dois componentes com a histidina quinase XAC0494. XAC0495 se comporta como um monômero em solução e possui um formato alongado, como revelado por experimentos de SAXS. / Nucleotide based second messengers are widely used by bacteria in signaling pathways that mediate adaptations to environmental and physiological changes. c-di-GMP is a nucleotide second messenger ubiquitous in Gram-negative bacteria, where it plays a role in many important behaviors that define bacterial lifestyle. In general, high cellular levels of c-di-GMP promote biofilm formation, while low levels induce bacterial motility. Xanthomonas citri subsp. Citri (Xac), a pathogen of great economic importance in Brazil, has a complex repertoire of c-di-GMP signaling molecules, with more than 30 genes coding for proteins involved in the synthesis, degradation and detection of this second messenger. Among these proteins, many have both GGDEF and EAL domains (often associated with c-di-GMP synthesis and degradation, respectively) present in the same polypeptide chain. Analysis of the primary structure of 11 GGDEF-EAL proteins coded by the Xac genome revealed that six most likely possess an inactive GGDEF domain plus an active EALdomain. Another three proteins have both domains active while the other two have both domains inactive. The knockout of the xac2382 gene, coding for a protein which contains a periplasmic domain followed by cytoplasmic HAMP, GGDEF (active) and EAL (active) domains, shows an increase in motility and a decrease in biofilm formation. Constructions containing fragments of this protein revealed that constructs containing at least the HAMP and GGDEF domains are able to complement the knockout strain and that diguanilate cyclase activity is essential for this. The XAC2382 periplasmic domain was shown to interact with a protein encoded by a gene situated in the same cluster, XAC2383, and that this interaction seems crucial for the control of Xac motility. The structure of XAC2383 was solved by X-ray crystallography and was shown to adopt a topology typical of the periplasmic binding proteins (PBP) family. The protein possesses a positively charged groove that contains a Ser-Thr-Ser motif (152STS154) important for the binding of compounds with phosphate or phosphonate groups. Site-directed mutagenesis of this motif abolished the effects on motility caused by this protein. These results suggest that XAC2383 is a periplasmic protein responsible for sensing a compound with electronegative characteristics and which interacts with XAC2382, thereby regulating the bacterial motility. Another protein, XAC0495 (with both GGDEF-EAL domains probably inactive) may be part of a two-component system with the histidine kinase XAC0494. Small-angle X-ray scattering (SAXS) experiments reveal that XAC0495 exists as an elongated monomer in solution.

C-di-GMP

C-di-GMP

GGDEF-EAL

GGDEF-EAL

Microbiologia

Microbiology

Periplasmic binding proteins

Periplasmic binding proteins

Xanthomonas citri subsp. citri

Xanthomonas citri subsp. citri

Estudo de proteínas GGDEF-EAL em vias de sinalização de c-di-GMP em Xanthomonas citri subsp. citri / Study of GGDEF-EAL proteins in c-di-GMP pathways in Xanthomonas citri subsp. citri

Raphael Dias Teixeira

17 April 2015

Segundos mensageiros nucleotídicos são amplamente utilizados por bactérias para se adaptar às mudanças ambientais e fisiológicas. Neste cenário destaca-se o c-di-GMP, um segundo mensageiro praticamente universal em bactérias responsável por controlar a transição do estilo de vida bacteriano. Em geral, altos níveis celulares de c-di-GMP promovem um estado séssil, de formação de biofilme, enquanto baixos níveis induzem a motilidade. Xanthomonas citri subsp. citri (Xac), um fitopatógeno de grande importância econômica no Brasil, possui uma complexa regulação da sinalização de c-di-GMP, possuindo mais de 30 proteínas envolvidas na síntese, na degradação e na detecção deste segundo mensageiro. Dentre essas proteínas, destacam-se as que possuem os domínios de síntese e degradação presentes na mesma cadeia polipetídica, os domínios GGDEF e EAL respectivamente. A análise das estruturas primárias das 11 proteínas GGDEF-EAL codificadas pelo genoma de Xac revelou que a maior parte delas (6) provavelmente possui o domínio GGDEF inativo, enquanto o EAL é ativo. Três possivelmente possuem ambos os domínios ativos enquanto outras duas possuem ambos os domínios inativos. O nocaute do gene xac2382 que codifica uma dessas proteínas (que possui um domínio periplasmático seguido dos domínios citoplasmáticos HAMP-GGDEF-EAL), demonstra um aumento de motilidade e uma diminuição na formação de biofilme. Construções de fragmentos da proteína revelaram que XAC2382 necessita pelo menos dos domínios HAMP-GGDEF para complementar a cepa nocaute e que a atividade de diguanilato ciclase é essencial para isto. O domínio periplasmático de XAC2382 se mostrou interagir com XAC2383, uma proteína codificada por um gene presente no mesmo cluster do gene de XAC2382, e essa interação parece importante para o controle da motilidade de Xac. A estrutura de XAC2383 foi resolvida por cristalografia de raios X na qual foi revelada uma topologia típica de proteínas da família das periplasmic binding proteins (PBPs) possuindo ainda uma cavidade carregada positivamente contendo um motivo Ser-Thr-Ser (amnioácidos 152-154) importante para a ligação de compostos com grupos fosfatos ou fosfonatos. A mutação sítio dirigida nesse motivo aboliu os efeitos na motilidade dependentes dessa proteína. Esses resultados sugerem que XAC2383 é um sensor periplasmático de um composto eletronegativo e esta proteína interage com XAC2382 regulando a motilidade bacteriana. XAC0495, uma proteína com ambos os domínios GGDEF-EAL provavelmente inativos, pode fazer parte de um sistema de dois componentes com a histidina quinase XAC0494. XAC0495 se comporta como um monômero em solução e possui um formato alongado, como revelado por experimentos de SAXS. / Nucleotide based second messengers are widely used by bacteria in signaling pathways that mediate adaptations to environmental and physiological changes. c-di-GMP is a nucleotide second messenger ubiquitous in Gram-negative bacteria, where it plays a role in many important behaviors that define bacterial lifestyle. In general, high cellular levels of c-di-GMP promote biofilm formation, while low levels induce bacterial motility. Xanthomonas citri subsp. Citri (Xac), a pathogen of great economic importance in Brazil, has a complex repertoire of c-di-GMP signaling molecules, with more than 30 genes coding for proteins involved in the synthesis, degradation and detection of this second messenger. Among these proteins, many have both GGDEF and EAL domains (often associated with c-di-GMP synthesis and degradation, respectively) present in the same polypeptide chain. Analysis of the primary structure of 11 GGDEF-EAL proteins coded by the Xac genome revealed that six most likely possess an inactive GGDEF domain plus an active EALdomain. Another three proteins have both domains active while the other two have both domains inactive. The knockout of the xac2382 gene, coding for a protein which contains a periplasmic domain followed by cytoplasmic HAMP, GGDEF (active) and EAL (active) domains, shows an increase in motility and a decrease in biofilm formation. Constructions containing fragments of this protein revealed that constructs containing at least the HAMP and GGDEF domains are able to complement the knockout strain and that diguanilate cyclase activity is essential for this. The XAC2382 periplasmic domain was shown to interact with a protein encoded by a gene situated in the same cluster, XAC2383, and that this interaction seems crucial for the control of Xac motility. The structure of XAC2383 was solved by X-ray crystallography and was shown to adopt a topology typical of the periplasmic binding proteins (PBP) family. The protein possesses a positively charged groove that contains a Ser-Thr-Ser motif (152STS154) important for the binding of compounds with phosphate or phosphonate groups. Site-directed mutagenesis of this motif abolished the effects on motility caused by this protein. These results suggest that XAC2383 is a periplasmic protein responsible for sensing a compound with electronegative characteristics and which interacts with XAC2382, thereby regulating the bacterial motility. Another protein, XAC0495 (with both GGDEF-EAL domains probably inactive) may be part of a two-component system with the histidine kinase XAC0494. Small-angle X-ray scattering (SAXS) experiments reveal that XAC0495 exists as an elongated monomer in solution.

C-di-GMP

GGDEF-EAL

Microbiologia

Periplasmic binding proteins

Xanthomonas citri subsp. citri

C-di-GMP

GGDEF-EAL

Microbiology

Periplasmic binding proteins

Xanthomonas citri subsp. citri

Outer Membrane Vesicle Production in Escherichia coli Relieves Envelope Stress and is Modulated by Changes in Peptidoglycan

Schwechheimer, Carmen

January 2014

<p>Bacterial outer membrane vesicles (OMVs) are spherical buds of the outer membrane (OM) containing periplasmic lumenal components. OMVs have been demonstrated to play a critical part in the transmission of virulence factors, immunologically active compounds, and bacterial survival, however vesiculation also appears to be a ubiquitous physiological process for Gram-negative bacteria. Despite their characterized biological roles, especially for pathogens, very little is known about their importance for the originating organism as well as regulation and mechanism of production. Only when we have established their biogenesis can we fully uncover their roles in pathogenesis and bacterial physiology. The overall goal of this research was to characterize bacterial mutants which display altered vesiculation phenotypes using genetic and biochemical techniques, and thereby begin to elucidate the mechanism of vesicle production and regulation. One part of this work elucidated a synthetic genetic growth defect for a strain with reduced OMV production (&#916;nlpA, inner membrane lipoprotein with a minor role in methionine transport) and envelope stress (&#916;degP, dual function periplasmic chaperone/ protease responsible for managing proteinaceous waste). This research showed that the growth defect of &#916;nlpA&#916;degP correlated with reduced OMV production with respect to the hyprevesiculator &#916;degP and the accumulation of protein in the periplasm and DegP substrates in the lumen of OMVs. We further demonstrated that OMVs do not solely act as a stress response pathway to rid the periplasm of otherwise damaging misfolded protein but also of accumulated peptidoglycan (PG) fragments and lipopolysaccharide (LPS), elucidating OMVs as a general stress response pathway critical for bacterial well-being. The second part of this work, focused on the role of PG structure, turnover and covalent crosslinks to the OM in vesiculation. We established a direct link between PG degradation and vesiculation: Mutations in the OM lipoprotein nlpI had been previously established as a very strong hypervesiculation phenotype. In the literature NlpI had been associated with another OM lipoprotein, Spr that was recently identified as a PG hydrolase. The data presented here suggest that NlpI acts as a negative regulator of Spr and that the &#916;nlpI hypervesiculation phenotype is a result of rampantly degraded PG by Spr. Additionally, we found that changes in PG structure and turnover correlate with altered vesiculation levels, as well as non-canonical D-amino acids, which are secreted by numerous bacteria on the onset of stationary phase, being a natural factor to increase OMV production. Furthermore, we discovered an inverse relationship between the concentration of Lpp-mediated, covalent crosslinks and the level of OMV production under conditions of modulated PG metabolism and structure. In contrast, situations that lead to periplasmic accumulation (protein, PG fragments, and LPS) and consequent hypervesiculation the overall OM-PG crosslink concentration appears to be unchanged. Form this work, we conclude that multiple pathways lead to OMV production: Lpp concentration-dependent and bulk driven, Lpp concentration-independent.</p> / Dissertation

Biochemistry

Envelope Stress

Lpp

NlpI/ Spr

Outer membrane vesicles

Peptidoglycan

Periplasmic Accumulation

Exploring the structurial diversity and engineering potential of thermophilic periplasmic binding proteins

Cuneo, Matthew Joseph

02 May 2007

The periplasmic binding protein (PBP) superfamily is found throughout the genosphere of both prokaryotic and eukaryotic organisms. PBPs function as receptors in bacterial solute transport and chemotaxis systems; however the same fold is also used in transcriptional regulators, enzymes, and eukaryotic neurotransmitter receptors. This versatility has been exploited for structure-based computational protein design experiments where PBPs have been engineered to bind novel ligands and serve as biosensors for the detection of small-molecule ligands relevant to biomedical or defense-related interests. In order to further understand functional adaptation from a structural biology perspective, and to provide a set of robust starting points for engineering novel biosensors by structure-based design, I have characterized the ligand-binding properties and solved the structure of nine PBPs from various thermophilic bacteria. Analysis of these structures reveals a variety of mechanisms by which diverse function can be encoded in a common fold. It is observed that re-modeling of secondary structure elements (such as insertions, deletions, and loop movements), and re-decoration of amino acid side-chains are common diversification mechanisms in PBPs. Furthermore, the relationship between hinge-bending motion and ligand binding is critical to understanding the function of natural or engineered adaptations in PBPs. Three of these proteins were solved in both the presence and absence of ligand which allowed for the first time the observation and analysis of ligand-induced structural rearrangements in thermophilic PBPs. This work revealed that the magnitude and transduction of local and global ligand-induced motions are diverse throughout the PBP superfamily. Through the analysis of the open-to-closed transition, and the identification of natural structural adaptations in thermophilic members of the PBP superfamily, I reveal strategies which can be applied to computational protein design to significantly improve current strategies. / Dissertation

periplasmic binding protein (PBP)

ligand-binding properties

thermophilic bacteria

computational biology

Structures et spécificités de Protéines Périplasmiques de Fixation pour les mannityl-opines chez Agrobacterium tumefaciens. / Structures and specificity of Periplasmic Binding Proteins toward mannityl-opines in Agrobacterium tumefaciens.

Marty, Loic

16 September 2016

L’agent pathogène Agrobacterium tumefaciens induit, chez les plantes, le développement de tumeurs dans lesquelles il prolifère, en intégrant un fragment de son plasmide Ti de virulence dans le génome de son hôte. Les tissus transformés synthétisent des composés originaux, appelés opines, qui sont utilisés comme nutriments spécifiques par la bactérie. Une vingtaine d’opines sont connues à ce jour, et chacune d’elle peut être métabolisée par des souches d’Agrobacterium tumefaciens possédant les gènes de transport et de catabolisme qui lui sont associés, ce qui apparait comme un avantage compétitif dans la colonisation de la tumeur. La présence de ces gènes dépend du type de plasmide Ti que la souche pathogène possède.Agrobacterium tumefaciens B6 possède un pTi de type octopine, qui porte les gènes de métabolisme des mannityl-opines, qui sont la mannopine, l’acide mannopinique, l’agropine et l’acide agropinique. La mannopine et l’acide mannopinique sont synthétisés par la même enzyme, et ont pour précurseurs respectivement la désoxy-fructosyl-glutamine (DFG) et le désoxy-fructosyl-glutamate (DFGA), tous deux opines de la famille de la chrysopine. La DFG est aussi un composé d’Amadori répandu et assimilable par de nombreux organismes. La mannopine sert de précurseur pour la synthèse de l’agropine. Enfin, la mannopine, l’acide mannopinique et l’agropine peuvent toutes trois se lactamiser spontanément en acide agropinique.Malgré la similarité chimique de ces quatre opines, chacune est transportée par une protéine périplasmique de fixation (PBP) associée à un transporteur ATP-binding Cassette (ABC) différent. La PBP sélectionne et fixe une opine pour l’apporter au transporteur ABC, qui permet le passage de l’opine dans le cytoplasme grâce à l’hydrolyse de deux molécules d’ATP. La spécificité du transporteur entier est déterminée par la PBP.Des études génétiques chez des souches possédant un pTi de type octopine ont montré que le système PBP-transporteur ABC AgaABCD est spécifique de l’acide agropinique, AgtABCD spécifique de l’agropine, MoaABCD spécifique de l’acide mannopinique et que MotABCD transporte la mannopine et également l’acide mannopinique. Chez la souche C58, qui ne possède pas un pTi de type octopine, le système de transport SocAB, codé par des gènes situés sur le plasmide cryptique At, transporte la DFG comme nutriment, et semble aussi capable d’importer la mannopine.Mon travail de thèse a permis, dans un premier temps, de caractériser les fortes affinités et la spécificité des PBP AgaA et AgtB pour l’acide agropinique, de la PBP MoaA pour l’acide mannopinique et de la PBP SocA pour la DFG, mais aussi la non spécificité de MotA pour la mannopine, l’acide mannopinique et la DFG, ce qui remet en question les affinités précédemment décrites pour AgtB et SocA. Dans un deuxième temps, ce travail a apporté les bases moléculaires et structurales des complexes PBP-mannityl-opines, complexes jamais caractérisés auparavant. Enfin, dans un troisième temps, la structure de la PBP AttC chez la souche C58, annotée comme mannopine-like, a été déterminée, et les expériences d’interaction ont montré qu’elle n’interagit avec aucune mannityl-opine, ce qui conduit à une révision de son annotation.Mes travaux apportent un éclairage nouveau sur l’import des mannityl-opines chez Agrobacterium tumefaciens. Le fait qu’aucun des transporteurs étudié ne permette l’import de l’agropine laisse penser qu’il existe une autre PBP ou un autre système de transport encore inconnu assurant cette fonction, ouvrant la voie vers de nouvelles études sur les pTi de type octopine et agropine. / Agrobacterium tumefaciens pathogenic agent confers the development of tumors in plants, in which it proliferates, integrating a fragment of its virulence Ti plasmid into its host genome. Transformed tissues synthesize original compounds, called opines, used as specific nutrients by the bacterium. More than twenty opines are known so far, and each one of them can be metabolized by A. tumefaciens strains possessing its associated transport and catabolism genes, which appears as a competitive advantage in the tumor colonization. The presence of these genes relies on the Ti plasmid type a pathogenic strain possesses. A. tumefaciens B6 possesses an octopine-type pTi, which harbors the metabolism genes of the mannityl-opines, which are mannopine, mannopinic acid, agropine and agropinic acid. Mannopine and mannopinic acid are synthesized by the same enzyme, and their precursors are deoxy-fructosyl-glutamine (DFG) and deoxy-fructosyl-glutamate (DFGA) respectively, both opines of the chrysopine family. DFG is also a wide-spread Amadori compound which can be uptaken by numerous organisms. Mannopine is a precursor for agropine synthesis. Finally, mannopine, mannopinic acid and agropine can spontaneously lactamize into agropinic acid.Despite the chemical similarity of these four opines, each one is transported by a different periplasmic binding protein (PBP) associated with an ATP-binding cassette (ABC) transporter. The PBP selects and binds one opine to bring it to the ABC transporter, which allows the passage of the opine to the cytoplasm due to two ATP molecules hydrolysis. The whole transporter specificity is determined by the PBP.Genetic studies in strains possessing an octopine-type pTi showed that AgaABCD PBP-ABC transporter system is specific to agropinic acid, AgtABCD to agropine, MoaABCD to mannopinic acid and that MotABCD transports mannopine and also mannopinic acid. In C58 strain, which do not possess an octopine-type pTi, SocAB transport system, coded by genes located on the cryptic pAt plasmid, allows the transport of DFG as a nutrient, and seems able to import mannopine too.My thesis work allowed, first, to characterize the strong affinities and the specificity of PBPs AgaA and AgtB to agropinic acid, PBP MoaA to mannopinic acid and PBP SocA to DFG, and also MotA unspecificity toward mannopine, mannopinique acid and DFG, which leads to a revision of the previously described affinities of AgtB and SocA. Secondly, this work brought molecular and structural basis of PBP-mannityl-opine complexes, never described before. Finally, the structure of PBP AttC, annotated as a mannopine binding-like protein in C58, was determined, and interactions experiments showed that it binds no mannityl-opines, leading to a revision of its annotation.My work sheds light on the mannityl-opines importation in Agrobacterium tumefaciens. The fact that none of the studied transport system allows agropine import lets think that there is another unknown PBP or another unknown whole transport system assuming this role, opening new ways to new studies about octopine- and agropine-type pTis.

Protéines périplasmiques de fixation

Opine

Agrobacterium tumefaciens

Transporteur

Periplasmic binding proteins

Opine

Agrobacterium tumefaciens

Transporter