Cloning and high-level expression of Thermus thermophilus RecA in E. coli: purification and novel use in HBV diagnostics

ABSTRACT We studied the role of Thermus thermophilus Recombinase A (RecA) in enhancing the PCR signals of DNA viruses such as Hepatitis B virus (HBV). The RecA gene of a thermophilic eubacterial strain, T. thermophilus, was cloned and hyperexpressed in Escherichia coli. The recombinant RecA protein was purified using a single heat treatment step without the use of any chromatography steps, and the purified protein (>95%) was found to be active. The purified RecA could enhance the polymerase chain reaction (PCR) signals of HBV and improve the detection limit of the HBV diagnosis by real time PCR. The yield of recombinant RecA was ∼35 mg/L, the highest yield reported for a recombinant RecA to date. RecA can be successfully employed to enhance detection sensitivity for the diagnosis of DNA viruses such as HBV, and this methodology could be particularly useful for clinical samples with HBV viral loads of less than 10 IU/mL, which is interesting and novel.

Hydrogen/rydride ion relay - a mechanism for early electron transfer in cytochrome c oxidases / El reléuónico hidrógeno-hidruro: un mecanismo de transferencia temprana de electrones en las citocromo c oxidasas

Cytochrome c oxidase (COX) employs electrons obtained from cytochrome c to bring about the reduction of oxygen to water. It is known that the electrons originate from the haem edge of cytochrome c and enters bovine COX at Trp-104. It is also known that Tyr-105, Glu-198 and Asp-158 of COX subunit II play roles in the enzyme's catalysis but how these roles are linked to electron transfer remain unclear. Recently, we proposed that electrons travel from the haem edge of cytochrome c to CuA, the first metal redox centre of COX, by a hydrogen/hydride ion relay using six residues. Now using a similar computer assisted approach, we investigate the extent to which this hydride/hydrogen ion mechanism is common amongst oxidases. The crystal structures of COX from P denitrificans, R sphaeroides and T thermophilus and quinol oxidase from E coli were downloaded and their binding domains analysed. As with bovine, all four oxidases had only nine amino acid residues in that region and both the sequences and three-dimensional structures were highly conserved. We propose that these residues function as a hydrogen/hydride ion relay, participating directly in electron transfer to CuA. We further suggest that this electron transfer mechanism might be a common feature in oxidases.

La citocromo c oxidasa (COX) emplea electrones obtenidos del citocromo c para producir la reducción del oxígeno a agua. Se sabe que los electrones originan a partir del hemo del citocromo c, y entran en la COX bovina en Trp-104. También se conoce que Tyr-105, Glu-198 y Asp-158 de la subunidad II de COX, desempeñan papeles en la catálisis de la enzima, pero no hay todavía claridad en cuanto a cómo estos papeles se hallan vinculados con la transferencia de electrones. Recientemente, sugerimos que los electrones viajan del borde del hemo del citocromo c al CuA, el primer centro metálico de reacción redox de la COX, por un relé iónico hidrógeno-hidruro, usando seis residuos. Ahora, usando un enfoque similar computarizado, investigamos hasta que punto este mecanismo de iones hidrógeno/hidruro es común entre las oxidasas. Se bajaron y analizaron los dominios de unión de las estructuras cristalinas de la COX de P denitrificans, R sphaeroides, y T thermophilus, y de la quinol oxidasa de la E coli. Como en el caso de la bovina, las cuatro oxidasas tenían sólo nueve residuos de aminoácido en esa región, y tanto las secuencias como las estructuras tridimensionales presentaban un alto grado de conservación. Proponemos que estos residuos funcionan como un relé iónico hidrógeno-hidruro, participando directamente en una transferencia de electrones al CuA. Asimismo, sugerimos que este mecanismo de transferencia de electrones podría ser un rasgo común de las oxidasas.