ATG4A regulates human erythroid maturation and mitochondrial clearance.

Autophagy is a self-degradation pathway that is essential for erythropoiesis. During erythroid differentiation, autophagy facilitates the degradation of macromolecules and the programmed clearance of mitochondria. Impaired mitochondrial clearance results in anemia and alters the lifespan of red blood cells in vivo. While several essential autophagy genes contribute to autophagy in erythropoiesis, little is known about erythroid-specific mediators of this pathway. Genetic analysis of primary human erythroid and nonerythroid cells revealed the selective upregulation of the core autophagy gene ATG4A in maturing human erythroid cells. Because the function of ATG4A in erythropoiesis is unknown, we evaluated its role using an ex vivo model of human erythropoiesis. Depletion of ATG4A in primary human hematopoietic stem and progenitor cells selectively impaired erythroid but not myeloid lineage differentiation, resulting in reduced red cell production, delayed terminal differentiation, and impaired enucleation. Loss of ATG4A impaired autophagy and mitochondrial clearance, giving rise to reticulocytes with retained mitochondria and autophagic vesicles. In summary, our study identifies ATG4A as a cell type-specific regulator of autophagy in erythroid development.

A rapid and quantitative assay for measuring neighboring gene activation by vector proviruses.

A simple, quantitative assay for measuring the oncogenic potential of integrating vectors is needed in order to improve vector design and safety. In this study, we have developed a transient plasmid-based assay to measure the activation of a reporter gene by an adjacent vector provirus. Plasmid pACT contains a luciferase cassette driven by a minimal, enhancerless promoter, into which vector proviruses are inserted upstream for evaluation by luciferase assays and northern blots. In a comparison of analogous vectors based on murine leukemia virus (MLV), human immunodeficiency virus (HIV), and foamy virus (FV), we observed significant enhancer activity and read-through transcription from MLV proviruses, and significant read-through transcription from HIV proviruses. HIV and FV proviruses containing an internal MLV long-terminal repeat (LTR) promoter also had significant enhancer activity, which was not observed with an internal promoter from the murine phosphoglycerate kinase-1 gene, PGK. These results demonstrate that neighboring gene activation can be limited by using internal promoter(s) lacking enhancer activity, especially when present in an FV vector backbone that prevents read-through transcription. Although the pACT assay does not measure oncogenesis directly, it should be useful for screening vectors before more time-consuming and costly animal studies are undertaken.