Ribosome Levels Selectively Regulate Translation and Lineage Commitment in Human Hematopoiesis

Khajuria, Rajiv K.; Munschauer, Mathias; Ulirsch, Jacob C.; Fiorini, Claudia; Ludwig, Leif S.; McFarland, Sean; Abdulhay, Nour J.; Specht, Harrison; Keshishian, Hasmik; Mani, D. R.; Jovanović, Marko; Ellis, Steven R.; Fulco, Charles P.; Engreitz, Jesse M.; Schütz, Sabina; Lian, John; Gripp, Karen W.; Weinberg, Olga K.; Pinkus, Geraldine S.; Gehrke, Lee; Regev, Aviv; Lander, Eric S.; Gazda, Hanna T.; Lee, Winston Y.; Panse, Vikram Govind; Carr, Steven A.; Sankaran, Vijay G.

doi:10.1016/j.cell.2018.02.036

Cited by 324 publications

(412 citation statements)

References 60 publications

(125 reference statements)

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“…Recent studies at the single cell level have also provided renewed insight as to GATA1 protein expression in human erythropoiesis, from hematopoietic stem and progenitor cells (HSPCs) to terminally differentiated erythroid cells. In one study, GATA1 protein could be detected at low levels in a subset of HSPCs, gradually increasing as cells differentiate, reaching high levels in lineage committed erythroid cells . Similarly, in another study, GATA1 protein was clearly detectable at the CMP stage and gradually increased with cell commitment and differentiation through the CFU‐E, proerythroblast, and basophilic erythroblast and orthochromatic erythroblast stages .…”

Section: Gata1 Expression In Hematopoiesismentioning

confidence: 90%

Regulation of GATA1 levels in erythropoiesis

et al. 2019

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GATA1 is considered as the "master" transcription factor in erythropoiesis. It regulates at the transcriptional level all aspects of erythroid maturation and function, as revealed by gene knockout studies in mice and by genome-wide occupancies in erythroid cells. The GATA1 protein contains two zinc finger domains and an N-terminal transactivation domain. GATA1 translation results in the production of the full-length protein and of a shorter variant (GATA1s) lacking the N-terminal transactivation domain, which is functionally deficient in supporting erythropoiesis. GATA1 protein abundance is highly regulated in erythroid cells at different levels, including transcription, mRNA translation, posttranslational modifications, and protein degradation, in a differentiationstage-specific manner. Maintaining high GATA1 protein levels is essential in the early stages of erythroid maturation, whereas downregulating GATA1 protein levels is a necessary step in terminal erythroid differentiation. The importance of maintaining proper GATA1 protein homeostasis in erythropoiesis is demonstrated by the fact that both GATA1 loss and its overexpression result in lethal anemia. Importantly, alterations in any of those GATA1 regulatory checkpoints have been recognized as an important cause of hematological disorders such as dyserythropoiesis (with or without thrombocytopenia), β-thalassemia, Diamond-Blackfan anemia, myelodysplasia, or leukemia. In this review, we provide an overview of the multilevel regulation of GATA1 protein homeostasis in erythropoiesis and of its deregulation in hematological disease. K E Y W O R D S

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Section: Gata1 Expression In Hematopoiesismentioning

confidence: 90%

Regulation of GATA1 levels in erythropoiesis

et al. 2019

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“…However, how the changes in the ribosome machinery in DBA selectively impairs erythropoiesis has been unclear. Recent work by the Sankaran laboratory revealed that transcripts with shorter 5′‐UTR, which are predicted to have less complex secondary structure and fewer upstream start codons (uAUGs), are more sensitive to ribosome protein haploinsufficiency . Significantly longer 5′ UTR lengths and more complex 5′‐UTR structures were found in most hematopoietic master regulators compared to the group of transcripts showing sensitivity to ribosomal protein haploinsufficiency .…”

Section: Gata1 Mutations In Dbamentioning

confidence: 99%

“…Recent work by the Sankaran laboratory revealed that transcripts with shorter 5′‐UTR, which are predicted to have less complex secondary structure and fewer upstream start codons (uAUGs), are more sensitive to ribosome protein haploinsufficiency . Significantly longer 5′ UTR lengths and more complex 5′‐UTR structures were found in most hematopoietic master regulators compared to the group of transcripts showing sensitivity to ribosomal protein haploinsufficiency . Intriguingly, although GATA1 has a relative short and unstructured 5′‐UTR, it exhibits unique features among hematopoietic transcriptional regulators, which may give GATA1 mRNA a higher translation efficiency but make it more sensitive to RP haploinsufficiency in DBA patients …”

Section: Gata1 Mutations In Dbamentioning

confidence: 99%

“…Significantly longer 5′ UTR lengths and more complex 5′‐UTR structures were found in most hematopoietic master regulators compared to the group of transcripts showing sensitivity to ribosomal protein haploinsufficiency . Intriguingly, although GATA1 has a relative short and unstructured 5′‐UTR, it exhibits unique features among hematopoietic transcriptional regulators, which may give GATA1 mRNA a higher translation efficiency but make it more sensitive to RP haploinsufficiency in DBA patients …”

Section: Gata1 Mutations In Dbamentioning

confidence: 99%

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GATA1 mutations in red cell disorders

Ling

Crispino

2019

IUBMB Life

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GATA1 is an essential regulator of erythroid cell gene expression and maturation.In its absence, erythroid progenitors are arrested in differentiation and undergo apoptosis. Much has been learned about GATA1 function through animal models, which include genetic knockouts as well as ones with decreased levels of expression. However, even greater insights have come from the finding that a number of rare red cell disorders, including Diamond-Blackfan anemia, are associated with GATA1 mutations. These mutations affect the amino-terminal zinc finger (N-ZF) and the amino-terminus of the protein, and in both cases can alter the DNA-binding activity, which is primarily conferred by the third functional domain, the carboxylterminal zinc finger (C-ZF). Here we discuss the role of GATA1 in erythropoiesis with an emphasis on the mutations found in human patients with red cell disorders. K E Y W O R D Sanemia, erythropoiesis, GATA1

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“…WES of patients who had a clinical diagnosis of DBA, but no known pathogenic mutations, revealed mutations impairing the production of GATA1 in several patients (Sankaran et al , ; Ludwig et al , ). Building upon this knowledge, subsequent functional studies solidified the link between RPs, GATA1, and defects in erythropoiesis by showing that RP haploinsufficiency reduces ribosome levels and thus results in reduced GATA1 mRNA translation (Ludwig et al , ; Khajuria et al , ). Therefore, DBA genetics revealed new information about the regulation of GATA1 expression in human hematopoiesis, establishing a novel link between ribosome levels and GATA1 driven by its high translation rate (Khajuria et al , ).…”

Section: Introductionmentioning

confidence: 99%

The genetics of human hematopoiesis and its disruption in disease

2019

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Hematopoiesis, or the process of blood cell production, is a paradigm of multi‐lineage cellular differentiation that has been extensively studied, yet in many aspects remains incompletely understood. Nearly all clinically measured hematopoietic traits exhibit extensive variation and are highly heritable, underscoring the importance of genetic variation in these processes. This review explores how human genetics have illuminated our understanding of hematopoiesis in health and disease. The study of rare mutations in blood and immune disorders has elucidated novel roles for regulators of hematopoiesis and uncovered numerous important molecular pathways, as seen through examples such as Diamond‐Blackfan anemia and the GATA2 deficiency syndromes. Additionally, population studies of common genetic variation have revealed mechanisms by which human hematopoiesis can be modulated. We discuss advances in functionally characterizing common variants associated with blood cell traits and discuss therapeutic insights, such as the discovery of BCL11A as a modulator of fetal hemoglobin expression. Finally, as genetic techniques continue to evolve, we discuss the prospects, challenges, and unanswered questions that lie ahead in this burgeoning field.

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Ribosome Levels Selectively Regulate Translation and Lineage Commitment in Human Hematopoiesis

Cited by 324 publications

References 60 publications

Regulation of GATA1 levels in erythropoiesis

Regulation of GATA1 levels in erythropoiesis

GATA1 mutations in red cell disorders

The genetics of human hematopoiesis and its disruption in disease

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