Loss of rad51 in zebrafish (Danio rerio): a novel Fanconi anaemia model

RAD51 is an indispensable homologous recombination protein, necessary for strand invasion and crossing over. It has recently been designated as a Fanconi anaemia (FA) gene, following the discovery of two patients carrying dominant negative mutations. FA is a hereditary DNA repair disorder characterised by various congenital abnormalities, progressive bone marrow failure and cancer predisposition. The cellular and molecular pathology of FA is poorly understood, resulting in a severe lack of effective treatment options. In this thesis, I describe the first viable vertebrate model of RAD51 loss. Phenotypic characterisation of zebrafish rad51 loss-of-function mutants showed that they develop key features of FA, including hypocellular kidney marrow, sensitivity to crosslinking agents and decreased size. Taking advantage of the unique properties of the zebrafish model, I show that some of these symptoms stem from both decreased proliferation, as well as increased apoptosis of embryonic haematopoietic stem and progenitor cells. Co-mutation of p$L was able to rescue the haematopoietic defects seen in the single mutants, but led to tumour development, underscoring the role of rad51 as a tumour suppressor. I further demonstrate that prolonged inflammatory stress can exacerbate the haematological impairment, leading to an additional decrease in kidney marrow cell numbers. In contrast, prolonged aldehyde-derived stress did not induce symptoms in the mutant fish. These findings strengthen the assignment of RAD51 as a Fanconi gene and provide more evidence for the notion that aberrant p53 signalling during embryogenesis leads to the haematological defects seen later in life in FA. It also strengthens the evidence for the involvement of haematopoietic stress, such as inflammation, in the development of bone marrow failure. Further research on this novel zebrafish FA model will lead to a deeper understanding of the molecular basis of bone marrow failure in FA and the cellular role of RAD51.This research was supported by a European Hematology Association PhD Studentshi

Loss of the homologous recombination gene<i>rad51</i>leads to Fanconi anemia-like symptoms in zebrafish

AbstractRAD51is an indispensable homologous recombination protein, necessary for strand invasion and crossing over. It has recently been designated as a Fanconi anemia (FA) gene, following the discovery of two patients carrying dominant negative mutations. FA is a hereditary DNA repair disorder characterized by various congenital abnormalities, progressive bone marrow failure and cancer predisposition. In this paper, we describe the first viable vertebrate model ofRAD51loss. Zebrafishrad51loss-of-function mutants developed key features of FA, including hypocellular kidney marrow, sensitivity to crosslinking agents and decreased size. We show that some of these symptoms stem from both decreased proliferation and increased apoptosis of embryonic hematopoietic stem and progenitor cells. Co-mutation ofp53was able to rescue the hematopoietic defects seen in the single mutants, but led to tumor development. We further demonstrate that prolonged inflammatory stress can exacerbate the hematological impairment, leading to an additional decrease in kidney marrow cell numbers. These findings strengthen the assignment ofRAD51as a Fanconi gene and provide more evidence for the notion that aberrant p53 signaling during embryogenesis leads to the hematological defects seen later in life in FA. Further research on this novel zebrafish FA model will lead to a deeper understanding of the molecular basis of bone marrow failure in FA and the cellular role of RAD51.Significance statementThe homologous recombination protein RAD51 has been extensively studied in prokaryotes and lower eukaryotes. However, there is a significant lack of knowledge of the role of this protein and its regulation in anin-vivocontext in vertebrates. Here we report the first viable vertebrate mutant model ofrad51in zebrafish. These mutant fish enabled us to confirm for the first time the recently discovered role ofRAD51in Fanconi anemia pathogenesis. We report that p53 linked embryonic stem cell defects directly lead to hematological impairments later in life. Co-mutation ofrad51withp53rescues the observed hematological defects, but predisposes the fish to early tumor development. The application of this model opens new possibilities to advance Fanconi anemia drug discovery.</jats:sec

Loss of the homologous recombination gene <i>rad51</i> leads to Fanconi anemia-like symptoms in zebrafish

Significance The homologous recombination protein RAD51 has been extensively studied in prokaryotes and lower eukaryotes. However, there is a significant lack of knowledge of the role of this protein and its regulation in an in vivo context in vertebrates. Here we report the first viable vertebrate mutant model of rad51 in zebrafish. These mutant fish enabled us to confirm the recently discovered role of RAD51 in Fanconi anemia pathogenesis. We report that p53-linked embryonic stem cell defects directly lead to hematological impairments later in life. Comutation of rad51 with p53 rescues the observed hematological defects, but predisposes the fish to early tumor development. The application of this model opens new possibilities to advance Fanconi anemia drug discovery. </jats:p