RESUMO

Xylella fastidiosa is a xylem-limited bacterium that infects a wide variety of plants. Stationary phase survival protein E is classified as a nucleotidase, which is expressed when bacterial cells are in the stationary growth phase and subjected to environmental stresses. Here, we report four refined X-ray structures of this protein from X. fastidiosa in four different crystal forms in the presence and/or absence of the substrate 3'-AMP. In all chains, the conserved loop verified in family members assumes a closed conformation in either condition. Therefore, the enzymatic mechanism for the target protein might be different of its homologs. Two crystal forms exhibit two monomers whereas the other two show four monomers in the asymmetric unit. While the biological unit has been characterized as a tetramer, differences of their sizes and symmetry are remarkable. Four conformers identified by Small-Angle X-ray Scattering (SAXS) in a ligand-free solution are related to the low frequency normal modes of the crystallographic structures associated with rigid body-like protomer arrangements responsible for the longitudinal and symmetric adjustments between tetramers. When the substrate is present in solution, only two conformers are selected. The most prominent conformer for each case is associated to a normal mode able to elongate the protein by moving apart two dimers. To our knowledge, this work was the first investigation based on the normal modes that analyzed the quaternary structure variability for an enzyme of the SurE family followed by crystallography and SAXS validation. The combined results raise new directions to study allosteric features of XfSurE protein.

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Citrus variegated chlorosis is a disease that attacks economically important citrus plantations and is caused by the plant-pathogenic bacterium Xylella fastidiosa. In this work, the structure of a small heat-shock protein from X. fastidiosa (XfsHSP17.9) is reported. The high-order structures of small heat-shock proteins from other organisms are arranged in the forms of double-disc, hollow-sphere or spherical assemblies. Unexpectedly, the structure reported here reveals a high-order architecture forming a nearly square cavity.

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As doenças causadas pelo fitopatógeno Xylella fastidiosa, uma bactéria Gram-negativa, devem-se aos seus múltiplos fatores de virulência, tais como formação de biofilme, secreção de enzimas de degradação da parede celular do xilema (CWDE), expressão de proteínas de adesão e produção de vesículas de membrana externa (OMVs). Esses fatores de virulência são controlados por uma via de sinalização mediada por DSF (fatores de sinalização difusíveis de natureza lipídica) e relacionada com percepção de quórum. Nesse trabalho, tivemos como objetivo ampliar a caracterização do secretoma de cepas selvagens e mutantes de X. fastidiosa para evidenciar proteínas e metabólitos potencialmente associados à adaptação ao hospedeiro, virulência e patogenicidade. Desenvolvemos, paralelamente, três estudos empregando como abordagens metodológicas a proteômica, a metabolômica e a transcritômica. No primeiro estudo, comparamos o secretoma (exoproteoma) da cepa Temecula1 selvagem (WT) e do mutante no gene da sintase de DSF (ΔrpfF), o qual exibe fenótipo de hipervirulência em videiras. A este estudo associamos a comparação dos transcritomas dessas cepas. Os resultados mostraram que, mesmo no cultivo in vitro, X. fastidiosa expressa e secreta fatores de virulência previamente conhecidos (lipases-esterases e proteases), além de toxinas (microcinas) que, supostamente, teriam papel de controlar bactérias competidoras pelo mesmo nicho. No segundo estudo caracterizamos a composição de OMVs secretadas no cultivo in vitro por X. fastidiosa Fb7 e 9a5c (cepas isoladas de laranjeiras) e Temecula1 (cepa isolada de videira). Demonstramos que Fb7 produz até 57% mais OMVs que 9a5c e Temecula1 e identificamos um total de 202 proteínas distintas nas OMVs produzidas pelas 3 cepas, ampliando consideravelmente o número de proteínas secretadas por meio de OMVs descrito, até então, para X. fastidiosa. Entre as proteínas enriquecidas, citamos adesinas afimbriais, porinas, lipoproteínas, hidrolases (lipases/esterases, proteases e peptidases) e uma pectina-liase putativa. Destacamos a detecção da enzima L-ascorbato oxidase nas OMVs e sugerimos que esta enzima poderia atuar na depleção do ascorbato produzido pelo hospedeiro vegetal. Além disso, demonstramos, pela primeira vez, que OMVs de X. fastidiosa transportam ácidos graxos da família DSF, sugerindo um papel adicional para OMVs nesse fitopatógeno. Finalmente, no terceiro estudo verificamos alterações relevantes no perfil de metabólitos secretados por X. fastidiosa em resposta a sua interação com metabólitos secretados por Burkholderia phytofirmans, proposta como uma cepa para o biocontrole da doença de Pierce de videiras. Confirmamos que o sobrenadante de B. phytofirmans possui um composto de natureza apolar que induz a formação de biofilme em X. fastidiosa, contudo ainda não foi possível decifrar a natureza química deste composto

The diseases caused by the phytopathogen Xylella fastidiosa, a Gram-negative bacterium, are due to multiple virulence factors, such as biofilm formation, secretion of xylem cell wall degradation enzymes (CWDE), expression of adhesion proteins and production of outer membrane vesicles (OMVs). These virulence factors are controlled by a DSF (diffusible signaling factors of a lipidic nature) mediating signaling pathway and related to quorum sensing perception. In this work, we aimed to extend the characterization of the secretoma of wild type and mutants strains of X. fastidiosa to uncover proteins and metabolites potentially associated to host adaptation, virulence and pathogenicity. We developed three studies in parallel using proteomics, metabolomics and transcriptomics as methodological approaches. In the first study, we compared the secretome (exoproteome) of the wild type strain Temecula1 (WT) and of DSF synthase mutant (ΔrpfF) which exhibits hypervirulence phenotype in grapevines. We also compared the transcriptomes of these strains. Our results showed that, even in in vitro culture, X. fastidiosa expresses and secretes previously known virulence factors (lipasesesterases and proteases), as well as toxins (microcins) that might play a role in controlling competing bacteria in the same niche. In the second study, we characterized the composition of OMVs secreted by in vitro cultures of X. fastidiosa Fb7 and 9a5c (strains isolated from orange trees) and Temecula1 (strain isolated from grapevine). We have shown that Fb7 produces up to 57% more OMVs than the 9a5c and Temecula1. Moreover we identified a total of 202 distinct proteins in the OMVs produced by these three strains, increasing considerably the number of OMVs secreted proteins so far described for X. fastidiosa. Among the proteins enriched in OMVs, we point out afimbrial adhesins, porins, lipoproteins, hydrolases (lipases/esterases, proteases and peptidases) and a putative pectin-lyase. We highlight the detection of the enzyme L-ascorbate oxidase in the OMVs and we suggest that this enzyme could act in the depletion of ascorbate produced by the plant host. In addition, we have demonstrated, for the first time, that X. fastidiosa OMVs transport fatty acids from the DSF family, suggesting an additional role for OMVs in this phytopathogen. Finally, in the third study we verified relevant changes in the profile of metabolites secreted by X. fastidiosa in response to the interaction with metabolites secreted by Burkholderia phytofirmans that has been sugested as a biocontrol strain for Pierce's disease in grapevines. We confirm that the B. phytofirmans supernatant has a non-polar compound that induces biofilm formation in X. fastidiosa, but it has not yet been possible to elucidate the chemical nature of this compound

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The ORF XF2234 in the Xylella fastidiosa genome was identified as encoding a small heat-shock protein of 17.9 kDa (HSP17.9). HSP17.9 was found as one of the proteins that are induced during X. fastidiosa proliferation and infection in citrus culture. Recombinant HSP17.9 was crystallized and surface atomic force microscopy experiments were conducted with the aim of better characterizing the HSP17.9 crystals. X-ray diffraction data were collected at 2.7 Šresolution. The crystal belonged to space group P4(3)22, with unit-cell parameters a = 68.90, b = 68.90, c = 72.51 Å, and is the first small heat-shock protein to crystallize in this space group.

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The bacterium Xylella fastidiosa is a phytopathogenic organism that causes citrus variegated chlorosis, a disease which attacks economically important crops, mainly oranges. In this communication, the crystallization and preliminary X-ray crystallographic analysis of XfSurE, a survival protein E from X. fastidiosa, are reported. Data were collected for two crystal forms, I and II, to 1.93 and 2.9 Å resolution, respectively. Crystal form I belonged to space group C2, with unit-cell parameters a = 172.36, b = 84.18, c = 87.24 Å, α = γ = 90, ß = 96.59°, whereas crystal form II belonged to space group C2, with unit-cell parameters a = 88.05, b = 81.26, c = 72.84 Å, α = γ = 90, ß = 94.76°.

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Biofilms are complex microbial communities with important biological functions including enhanced resistance against external factors like antimicrobial agents. The formation of a biofilm is known to be strongly dependent on substrate properties including hydrophobicity/hydrophilicity, structure, and roughness. The adsorption of (macro)molecules on the substrate, also known as conditioning film, changes the physicochemical properties of the surface and affects the bacterial adhesion. In this study, we investigate the physicochemical changes caused by Periwinkle wilt (PW) culture medium conditioning film formation on different surfaces (glass and silicon) and their effect on X. fastidiosa biofilm formation. Contact angle measurements have shown that the film formation decreases the surface hydrophilicity degree of both glass and silicon after few hours. Atomic force microscopy (AFM) images show the glass surface roughness is drastically reduced with conditioning film formation. First-layer X. fastidiosa biofilm on glass was observed in the AFM liquid cell after a period of time similar to that determined for the hydrophilicity changes. In addition, attenuation total reflection-Fourier transform infrared (ATR-FTIR) spectroscopy supports the AFM observation, since the PW absorption spectra increases with time showing a stronger contribution from the phosphate groups. Although hydrophobic and rough surfaces are commonly considered to increase bacteria cell attachment, our results suggest that these properties are not as important as the surface functional groups resulting from PW conditioning film formation for X. fastidiosa adhesion and biofilm development.

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BACKGROUND: Xylella fastidiosa, a Gram-negative fastidious bacterium, grows in the xylem of several plants causing diseases such as citrus variegated chlorosis. As the xylem sap contains low concentrations of amino acids and other compounds, X. fastidiosa needs to cope with nitrogen limitation in its natural habitat. RESULTS: In this work, we performed a whole-genome microarray analysis of the X. fastidiosa nitrogen starvation response. A time course experiment (2, 8 and 12 hours) of cultures grown in defined medium under nitrogen starvation revealed many differentially expressed genes, such as those related to transport, nitrogen assimilation, amino acid biosynthesis, transcriptional regulation, and many genes encoding hypothetical proteins. In addition, a decrease in the expression levels of many genes involved in carbon metabolism and energy generation pathways was also observed. Comparison of gene expression profiles between the wild type strain and the rpoN null mutant allowed the identification of genes directly or indirectly induced by nitrogen starvation in a σ54-dependent manner. A more complete picture of the σ54 regulon was achieved by combining the transcriptome data with an in silico search for potential σ54-dependent promoters, using a position weight matrix approach. One of these σ54-predicted binding sites, located upstream of the glnA gene (encoding glutamine synthetase), was validated by primer extension assays, confirming that this gene has a σ54-dependent promoter. CONCLUSIONS: Together, these results show that nitrogen starvation causes intense changes in the X. fastidiosa transcriptome and some of these differentially expressed genes belong to the σ54 regulon.

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Xylella fastidiosa is a xylem-restricted plant pathogen that causes a range of diseases in several and important crops. Through comparative genomic sequence analysis many genes were identified and, among them, several potentially involved in plant-pathogen interaction. The experimental determination of the primary sequence of some markedly expressed proteins for X. fastidiosa and the comparison with the nucleic acids sequence of genome identified one of them as being SCJ21.16 (XFa0032) gene product. The comparative analysis of this protein against SWISSPROT database, in special, resulted in similarity with alpha-hydroxynitrile lyase enzyme (HNL) from Arabidopsis thaliana, causing interest for being one of the most abundant proteins both in the whole cell extract as well as in the extracellular protein fraction. It is known that HNL enzyme are involved in a process termed "cyanogenesis", which catalyzes the dissociation of alpha-hydroxinitrile into carbonyle and HCN when plant tissue is damaged. Although the complete genome sequences of X. fastidiosa are available and the cyanogenesis process is well known, the biological role of this protein in this organism is not yet functionally characterized. In this study we presented the cloning, expression, characterization of recombinant HNL from X. fastidiosa, and its probable function in the cellular metabolism. The successful cloning and heterologous expression in Escherichia coli resulted in a satisfactory amount of the recombinant HNL expressed in a soluble, and active form giving convenient access to pure enzyme for biochemical and structural studies. Finally, our results confirmed that the product of the gene XFa0032 can be positively assigned as FAD-independent HNLs.

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Xylella fastidiosa (X.f.) is a plant pathogen with high levels of genomic similarity to Xanthomonas campestris pv. campestris (X.c.c.). It has been shown that X. fastidiosa synthesizes a putative diffusible signal factor (X.f.-DSF) that activates regulation of pathogenicity factor (rpf) genes in a X.c.c. reporter system, which might be involved in the regulation of pathogenesis associated genes as in X.c.c., as well as in quorum-sensing. The nature of the X.f.-DSF is not known, whereas the X.c.c.-DSF has been identified as cis-11-methyl-2-dodecenoic acid. In this work, the chemical nature of a putative X.f.-DSF molecule, able to restore endoglucanase activity in a X.c.c. rpfF mutant, was investigated as if it was a fatty acid derivative. Bioassays with X.c.c. reporter bacterium and X.f. culture extracts, based on endoglucanase restoration activity, were also carried out in order to confirm the DSFs molecules similarities. For this reason, a gas chromatography-mass spectrometry method was developed with standard fatty acids methyl esters mixtures. The retention time, as well as the fragmentation patterns, of each standard was used to identify the DSF molecule synthesized by X.f. in the culture medium. Typical ester fragmentation patterns (the derivatized analyte) were observed, such as: McLafferty rearrangement and migration of the Hdelta followed by 1,4-hydrogen shift and cleavage of the bond Cbeta--Cgamma, confirming the nature of this molecule. This confirmation was corroborated by the common peaks in both spectra. Besides, the observed retention time reinforces our conclusion since it corresponds to a methyl ester with 15 carbons. Since the X.f.-DSF molecule was tentatively identified as 12-methyl-tetradecanoic acid (by mass spectra library comparison), this standard compound was also analyzed, strongly suggesting that this is the identification of such a molecule. To our knowledge, this is the first time a DSF produced by X.f. has been characterized.

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BigR (biofilm growth-associated repressor) is a novel repressor protein that regulates the transcription of an operon implicated in biofilm growth in both Xylella fastidiosa and Agrobacterium tumefaciens. This protein binds to a palindromic TA-rich element located in the promoter of the BigR operon and strongly represses transcription of the operon. BigR contains a helix-turn-helix (HTH) domain that is found in some members of the ArsR/SmtB family of metal sensors, which control metal resistance in bacteria. Although functional studies have suggested that BigR does not act as a metal sensor, the presence of two cysteines and a methionine in its primary structure raised the possibility of BigR being a metal-ligand protein. In order to gain new insights into the protein structure and its possible interaction with a metal ion or effector ligand, BigR from X. fastidiosa was crystallized in native and selenomethionine (SeMet) labelled forms using the hanging-drop vapour-diffusion method. X-ray diffraction data were collected from native and SeMet crystals to resolutions of 1.95 and 2.2 A, respectively. Both crystals belong to space group P321 and contain one molecule per asymmetric unit.

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