Spontaneous abrogation of the G₂DNA damage checkpoint has clinical benefits but promotes leukemogenesis in Fanconi anemia patients

Diamond Blackfan anemia

Mutations affecting genes encoding ribosomal proteins cause Diamond Blackfan anemia (DBA), a rare congenital syndrome associated with physical anomalies, short stature, red cell aplasia, and an increased risk of malignancy. p53 activation has been identified as a key component in the pathophysiology of DBA after cellular and molecular studies of knockdown cellular and animal models of DBA and other disorders affecting ribosomal assembly or function. Other potential mechanisms that warrant further investigation include impaired translation as the result of ribosomal insufficiency, which may be ameliorated by leucine supplementation, and alternative splicing leading to reduced expression of a cytoplasmic heme exporter, the human homolog of the receptor for feline leukemia virus C (FVLCR). However, the molecular basis for the characteristic steroid responsiveness of the erythroid failure in DBA remains unknown. This review explores the clinical and therapeutic implications of the current state of knowledge and delineates important but as-yet-unanswered questions.

Cytokinesis failure and attenuation: new findings in Fanconi anemia

The hallmarks of the rare inherited disorder Fanconi anemia (FA) are progressive bone marrow failure and susceptibility to cancer. The former is the major cause of death for patients with FA, as it usually occurs earlier in life than cancer development. Despite spectacular advances in unraveling the molecular details of FA, the origin of the bone marrow failure that is central to this condition for most patients has long been puzzling and controversial. Two studies recently published in the JCI, including one in this issue, will add to the debate. They also highlight the fact that studying rare disorders can elucidate important new clinical and biological principles.