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1.
Plant J ; 115(2): 386-397, 2023 Jul.
Artículo en Inglés | MEDLINE | ID: mdl-37010739

RESUMEN

Carbonic anhydrases (CAs) are ubiquitous enzymes that accelerate the reversible conversion of CO2 to HCO3 - . The Arabidopsis genome encodes members of the α-, ß- and γ-CA families, and it has been hypothesized that ßCA activity has a role in photosynthesis. In this work, we tested this hypothesis by characterizing the two plastidial ßCAs, ßCA1 and ßCA5, in physiological conditions of growth. We conclusively established that both proteins are localized in the chloroplast stroma and that the loss of ßCA5 induced the expression of ßCA1, supporting the existence of regulatory mechanisms to control the expression of stromal ßCAs. We also established that ßCA1 and ßCA5 have markedly different enzymatic kinetics and physiological relevance. Specifically, we found that ßCA5 had a first-order rate constant ~10-fold lower than ßCA1, and that the loss of ßCA5 is detrimental to growth and could be rescued by high CO2 . Furthermore, we established that, while a ßCA1 mutation showed near wild-type growth and no significant impact on photosynthetic efficiency, the loss of ßCA5 markedly disrupted photosynthetic efficiency and light-harvesting capacity at ambient CO2 . Therefore, we conclude that in physiological autotrophic growth, the loss of the more highly expressed ßCA1 does not compensate for the loss of a less active ßCA5, which in turn is involved in growth and photosynthesis at ambient CO2 levels. These results lend support to the hypothesis that, in Arabidopsis,ßCAs have non-overlapping roles in photosynthesis and identify a critical activity of stromal ßCA5 and a dispensable role for ßCA1.


Asunto(s)
Proteínas de Arabidopsis , Arabidopsis , Anhidrasas Carbónicas , Arabidopsis/metabolismo , Anhidrasas Carbónicas/genética , Anhidrasas Carbónicas/metabolismo , Dióxido de Carbono/metabolismo , Fotosíntesis , Proteínas de Arabidopsis/genética , Proteínas de Arabidopsis/metabolismo
2.
J Biol Chem ; 294(37): 13800-13810, 2019 09 13.
Artículo en Inglés | MEDLINE | ID: mdl-31350338

RESUMEN

The flavin transferase ApbE plays essential roles in bacterial physiology, covalently incorporating FMN cofactors into numerous respiratory enzymes that use the integrated cofactors as electron carriers. In this work we performed a detailed kinetic and structural characterization of Vibrio cholerae WT ApbE and mutants of the conserved residue His-257, to understand its role in substrate binding and in the catalytic mechanism of this family. Bi-substrate kinetic experiments revealed that ApbE follows a random Bi Bi sequential kinetic mechanism, in which a ternary complex is formed, indicating that both substrates must be bound to the enzyme for the reaction to proceed. Steady-state kinetic analyses show that the turnover rates of His-257 mutants are significantly smaller than those of WT ApbE, and have increased Km values for both substrates, indicating that the His-257 residue plays important roles in catalysis and in enzyme-substrate complex formation. Analyses of the pH dependence of ApbE activity indicate that the pKa of the catalytic residue (pKES1) increases by 2 pH units in the His-257 mutants, suggesting that this residue plays a role in substrate deprotonation. The crystal structures of WT ApbE and an H257G mutant were determined at 1.61 and 1.92 Å resolutions, revealing that His-257 is located in the catalytic site and that the substitution does not produce major conformational changes. We propose a reaction mechanism in which His-257 acts as a general base that deprotonates the acceptor residue, which subsequently performs a nucleophilic attack on FAD for flavin transfer.


Asunto(s)
Flavinas/metabolismo , Transferasas/metabolismo , Vibrio cholerae/metabolismo , Proteínas Bacterianas/metabolismo , Catálisis , Dominio Catalítico , Secuencia Conservada , Mononucleótido de Flavina/metabolismo , Flavina-Adenina Dinucleótido/metabolismo , Flavinas/genética , Histidina/metabolismo , Cinética , Oxidación-Reducción , Especificidad por Sustrato/genética , Transferasas/genética , Vibrio cholerae/genética
3.
J Biol Chem ; 293(40): 15664-15677, 2018 10 05.
Artículo en Inglés | MEDLINE | ID: mdl-30135204

RESUMEN

Pseudomonas aeruginosa is a Gram-negative bacterium responsible for a large number of nosocomial infections. The P. aeruginosa respiratory chain contains the ion-pumping NADH:ubiquinone oxidoreductase (NQR). This enzyme couples the transfer of electrons from NADH to ubiquinone to the pumping of sodium ions across the cell membrane, generating a gradient that drives essential cellular processes in many bacteria. In this study, we characterized P. aeruginosa NQR (Pa-NQR) to elucidate its physiologic function. Our analyses reveal that Pa-NQR, in contrast with NQR homologues from other bacterial species, is not a sodium pump, but rather a completely new form of proton pump. Homology modeling and molecular dynamics simulations suggest that cation selectivity could be determined by the exit ion channels. We also show that Pa-NQR is resistant to the inhibitor 2-n-heptyl-4-hydroxyquinoline N-oxide (HQNO). HQNO is a quinolone secreted by P. aeruginosa during infection that acts as a quorum sensing agent and also has bactericidal properties against other bacteria. Using comparative analysis and computational modeling of the ubiquinone-binding site, we identified the specific residues that confer resistance toward this inhibitor. In summary, our findings indicate that Pa-NQR is a proton pump rather than a sodium pump and is highly resistant against the P. aeruginosa-produced compound HQNO, suggesting an important role in the adaptation against autotoxicity. These results provide a deep understanding of the metabolic role of NQR in P. aeruginosa and provide insight into the structural factors that determine the functional specialization in this family of respiratory complexes.


Asunto(s)
Proteínas Bacterianas/química , Complejo I de Transporte de Electrón/química , Electrones , Protones , Pseudomonas aeruginosa/enzimología , Ubiquinona/química , Secuencia de Aminoácidos , Proteínas Bacterianas/genética , Proteínas Bacterianas/metabolismo , Sitios de Unión , Clonación Molecular , Transporte de Electrón , Complejo I de Transporte de Electrón/genética , Complejo I de Transporte de Electrón/metabolismo , Expresión Génica , Vectores Genéticos/química , Vectores Genéticos/metabolismo , Hidroxiquinolinas/farmacología , Cinética , Modelos Moleculares , Unión Proteica , Conformación Proteica en Hélice alfa , Conformación Proteica en Lámina beta , Dominios y Motivos de Interacción de Proteínas , Pseudomonas aeruginosa/efectos de los fármacos , Pseudomonas aeruginosa/genética , Proteínas Recombinantes/química , Proteínas Recombinantes/genética , Proteínas Recombinantes/metabolismo , Alineación de Secuencia , Homología de Secuencia de Aminoácido , Especificidad por Sustrato , Ubiquinona/metabolismo , Vibrio cholerae/efectos de los fármacos , Vibrio cholerae/enzimología , Vibrio cholerae/genética
5.
J Biol Chem ; 292(7): 3039-3048, 2017 02 17.
Artículo en Inglés | MEDLINE | ID: mdl-28053088

RESUMEN

The sodium-dependent NADH dehydrogenase (Na+-NQR) is a key component of the respiratory chain of diverse prokaryotic species, including pathogenic bacteria. Na+-NQR uses the energy released by electron transfer between NADH and ubiquinone (UQ) to pump sodium, producing a gradient that sustains many essential homeostatic processes as well as virulence factor secretion and the elimination of drugs. The location of the UQ binding site has been controversial, with two main hypotheses that suggest that this site could be located in the cytosolic subunit A or in the membrane-bound subunit B. In this work, we performed alanine scanning mutagenesis of aromatic residues located in transmembrane helices II, IV, and V of subunit B, near glycine residues 140 and 141. These two critical glycine residues form part of the structures that regulate the site's accessibility. Our results indicate that the elimination of phenylalanine residue 211 or 213 abolishes the UQ-dependent activity, produces a leak of electrons to oxygen, and completely blocks the binding of UQ and the inhibitor HQNO. Molecular docking calculations predict that UQ interacts with phenylalanine 211 and pinpoints the location of the binding site in the interface of subunits B and D. The mutagenesis and structural analysis allow us to propose a novel UQ-binding motif, which is completely different compared with the sites of other respiratory photosynthetic complexes. These results are essential to understanding the electron transfer pathways and mechanism of Na+-NQR catalysis.


Asunto(s)
NADH Deshidrogenasa/metabolismo , Sodio/metabolismo , Ubiquinona/metabolismo , Vibrio cholerae/enzimología , Secuencia de Aminoácidos , Sitios de Unión , Dominio Catalítico , Cinética , Simulación de Dinámica Molecular , NADH Deshidrogenasa/química , Resonancia Magnética Nuclear Biomolecular , Homología de Secuencia de Aminoácido
6.
Environ Microbiol Rep ; 14(5): 700-710, 2022 10.
Artículo en Inglés | MEDLINE | ID: mdl-35855583

RESUMEN

The application of nanotechnology to plants, termed phytonanotechnology, has the potential to revolutionize plant research and agricultural production. Advancements in phytonanotechnology will allow for the time-controlled and target-specific release of bioactive compounds and agrochemicals to alter and optimize conventional plant production systems. A diverse range of engineered nanoparticles with unique physiochemical properties is currently being investigated to determine their suitability for plants. Improvements in crop yield, disease resistance and nutrient and pesticide management are all possible using designed nanocarriers. However, despite these prospective benefits, research to thoroughly understand the precise activity, localization and potential phytotoxicity of these nanoparticles within plant systems is required. Protein-based bacterial microcompartment shell proteins that self-assemble into spherical shells, nanotubes and sheets could be of immense value for phytonanotechnology due to their ease of manipulation, multifunctionality, rapid and efficient producibility and biodegradability. In this review, we explore bacterial microcompartment-based architectures within the scope of phytonanotechnology.


Asunto(s)
Nanopartículas , Plaguicidas , Agroquímicos , Proteínas Bacterianas/metabolismo , Nanotecnología , Orgánulos , Plantas/metabolismo
7.
Sci Rep ; 10(1): 14500, 2020 09 02.
Artículo en Inglés | MEDLINE | ID: mdl-32879425

RESUMEN

The impact of material chemical composition on microbial growth on building materials remains relatively poorly understood. We investigate the influence of the chemical composition of material extractives on microbial growth and community dynamics on 30 different wood species that were naturally inoculated, wetted, and held at high humidity for several weeks. Microbial growth was assessed by visual assessment and molecular sequencing. Unwetted material powders and microbial swab samples were analyzed using reverse phase liquid chromatography with tandem mass spectrometry. Different wood species demonstrated varying susceptibility to microbial growth after 3 weeks and visible coverage and fungal qPCR concentrations were correlated (R2 = 0.55). Aspergillaceae was most abundant across all samples; Meruliaceae was more prevalent on 8 materials with the highest visible microbial growth. A larger and more diverse set of compounds was detected from the wood shavings compared to the microbial swabs, indicating a complex and heterogeneous chemical composition within wood types. Several individual compounds putatively identified in wood samples showed statistically significant, near-monotonic associations with microbial growth, including C11H16O4, C18H34O4, and C6H15NO. A pilot experiment confirmed the inhibitory effects of dosing a sample of wood materials with varying concentrations of liquid C6H15NO (assuming it presented as Diethylethanolamine).


Asunto(s)
Materiales de Construcción , Microbiología Ambiental , Monitoreo del Ambiente , Hongos/crecimiento & desarrollo , Madera/química , Aspergillus/crecimiento & desarrollo , Aspergillus/aislamiento & purificación , Basidiomycota/crecimiento & desarrollo , Basidiomycota/aislamiento & purificación , Cromatografía Liquida , Análisis por Conglomerados , Hongos/aislamiento & purificación , Humedad , Reacción en Cadena de la Polimerasa , Polvos , ARN Ribosómico , Espectrometría de Masas en Tándem
8.
PLoS One ; 15(4): e0231965, 2020.
Artículo en Inglés | MEDLINE | ID: mdl-32324772

RESUMEN

Pseudomonas aeruginosa is a Gram-negative γ-proteobacterium that forms part of the normal human microbiota and it is also an opportunistic pathogen, responsible for 30% of all nosocomial urinary tract infections. P. aeruginosa carries a highly branched respiratory chain that allows the colonization of many environments, such as the urinary tract, catheters and other medical devices. P. aeruginosa respiratory chain contains three different NADH dehydrogenases (complex I, NQR and NDH-2), whose physiologic roles have not been elucidated, and up to five terminal oxidases: three cytochrome c oxidases (COx), a cytochrome bo3 oxidase (CYO) and a cyanide-insensitive cytochrome bd-like oxidase (CIO). In this work, we studied the composition of the respiratory chain of P. aeruginosa cells cultured in Luria Broth (LB) and modified artificial urine media (mAUM), to understand the metabolic adaptations of this microorganism to the growth in urine. Our results show that the COx oxidases play major roles in mAUM, while P. aeruginosa relies on CYO when growing in LB medium. Moreover, our data demonstrate that the proton-pumping NQR complex is the main NADH dehydrogenase in both LB and mAUM. This enzyme is resistant to HQNO, an inhibitory molecule produced by P. aeruginosa, and may provide an advantage against the natural antibacterial agents produced by this organism. This work offers a clear picture of the composition of this pathogen's aerobic respiratory chain and the main roles that NQR and terminal oxidases play in urine, which is essential to understand its physiology and could be used to develop new antibiotics against this notorious multidrug-resistant microorganism.


Asunto(s)
Materiales Biomiméticos , Medios de Cultivo , Oxidorreductasas/metabolismo , Pseudomonas aeruginosa/crecimiento & desarrollo , Pseudomonas aeruginosa/metabolismo , Orina , Aerobiosis , Transporte de Electrón , NADH Deshidrogenasa/metabolismo , Quinonas/metabolismo
9.
ACS Omega ; 4(21): 19324-19331, 2019 Nov 19.
Artículo en Inglés | MEDLINE | ID: mdl-31763556

RESUMEN

The ion-pumping NADH: ubiquinone dehydrogenase (NQR) is a vital component of the respiratory chain of numerous species of marine and pathogenic bacteria, including Vibrio cholerae. This respiratory enzyme couples the transfer of electrons from NADH to ubiquinone (UQ) to the pumping of ions across the plasma membrane, producing a gradient that sustains multiple homeostatic processes. The binding site of UQ within the enzyme is an important functional and structural motif that could be used to design drugs against pathogenic bacteria. Our group recently located the UQ site in the interface between subunits B and D and identified the residues within subunit B that are important for UQ binding. In this study, we carried out alanine scanning mutagenesis of amino acid residues located in subunit D of V. cholerae NQR to understand their role in UQ binding and enzymatic catalysis. Moreover, molecular docking calculations were performed to characterize the structure of the site at the atomic level. The results show that mutations in these positions, in particular, in residues P185, L190, and F193, decrease the turnover rate and increase the Km for UQ. These mutants also showed an increase in the resistance against the inhibitor HQNO. The data indicate that residues in subunit D fulfill important structural roles, restricting and orienting UQ in a catalytically favorable position. In addition, mutations of these residues open the site and allow the simultaneous binding of substrate and inhibitors, producing partial inhibition, which appears to be a strategy used by Pseudomonas aeruginosa to avoid autopoisoning.

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