Giardia duodenalis Rad52 protein: biochemical characterization and response upon DNA damage.

Giardia duodenalis is a flagellated binucleated protozoan that colonizes the small intestine in mammals, causing giardiasis, acute or chronic diarrhea. DNA double strand break either endogenously or exogenously generated is a major insult to DNA and its repair by homologous recombination (HR) is crucial for genomic stability. During HR, Rad52 plays key roles in the loading of the Rad51 recombinase, and the annealing of the second double-strand break end to the displaced strand of the D-loop structure. Among the functions found in vitro in yeast and human Rad52 protein are: ssDNA or dsDNA binding activity, ability to anneal bare or RPA coated-ssDNA, as well as multimeric ring formation. In this work, we searched for conserved domains in a putative Rad52 protein from G. duodenalis (GdRad52). Its coding sequence was cloned, expressed and purified to study its biochemical properties. rGdRad52 binds to dsDNA and ssDNA, with greater affinity for the latter. Likewise, rGdRad52 promotes annealing of DNA uncoated and coated with GdRPA1. rGdRad52 interacts with GdDMC1B and with GdRPA1 protein as shown in far western blotting assay. Additionally, rGdRad52 formed multimeric rings as observed by electronic microscopy. Finally, GdRad52 is over expressed in response upon DNA damage inflicted on trophozoites.

In silico data analyses of recombinases GdDMC1A and GdDMC1B from Giardia duodenalis.

Giardia duodenalis is a worldwide protozoa known causing diarrhea in all vertebrates, humans among these. Homologous recombination is a mechanism that provides genomic stability. Two putative recombinases were identified in G. duodenalis genome: GdDMC1A and GdDMC1B. In this article, we describe the identification of conserved domains in GdDMC1A and GdDMC1B, such as: DNA binding domains (Helix-turn-helix motif, loops 1 and 2) and an ATPcap and Walker A and B motifs associated with ATP binding and hydrolysis, phylogenetic analyses among assemblages and three-dimensional structure modeling of these recombinases using bioinformatics tools. Also, experimental data is described about LD50 determination for ionizing radiation in trophozoites of G. duodenalis. Additionally, as recombinases, GdDMC1A and GdDMC1B were used to rescue a defective Saccharomyces cerevisiae Δ rad51 strain under genotoxic conditions and data is described. The data described here are related to the research article entitled "Characterization of recombinase DMC1B and its functional role as Rad51 in DNA damage repair in Giardia duodenalis trophozoites" (Torres-Huerta et al.,) [1].

Characterization of recombinase DMC1B and its functional role as Rad51 in DNA damage repair in Giardia duodenalis trophozoites.

Homologous recombination (HR) is a highly conserved pathway for the repair of chromosomes that harbor DNA double-stranded breaks (DSBs). The recombinase RAD51 plays a key role by catalyzing the pairing of homologous DNA molecules and the exchange of information between them. Two putative DMC1 homologs (DMC1A and DMC1B) have been identified in Giardia duodenalis. In terms of sequences, GdDMC1A and GdDMC1B bear all of the characteristic recombinase domains: DNA binding domains (helix-turn-helix motif, loops 1 and 2), an ATPcap and Walker A and B motifs associated with ATP binding and hydrolysis. Because GdDMC1B is expressed at the trophozoite stage and GdDMC1A is expressed in the cyst stage, we cloned the giardial dmc1B gene and expressed and purified its protein to determine its activities, including DNA binding, ATP hydrolysis, and DNA strand exchange. Our results revealed that it possessed these activities, and they were modulated by divalent metal ions in different manners. GdDMC1B expression at the protein and transcript levels, as well as its subcellular localization in trophozoites upon DNA damage, was assessed. We found a significant increase in GdDMC1B transcript and protein levels after ionizing radiation treatment. Additionally, GdDMC1B protein was mostly located in the nucleus of trophozoites after DNA damage. These results indicate that GdDMC1B is the recombinase responsible for DSBs repair in the trophozoite; therefore, a functional Rad51 role is proposed for GdDMC1B.