Architecture of a lymphomyeloid developmental switch controlled by PU.1, Notch and Gata3

Real, Marissa Morales Del; Rothenberg, Ellen V.

doi:10.1242/dev.088559

Cited by 88 publications

(140 citation statements)

References 40 publications

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“…2E). For more extensive confirmation of the effects of this shRNA on Gata3 RNA and GATA-3 protein in the Adh.2C2 system, also see our recent report (43). Gata3 shRNA thus consistently lowered GATA-3 protein levels, despite its generally mild effect on RNA levels.…”

Section: Resultsmentioning

confidence: 58%

“…PU.1 and GATA-3 act as antagonists in a network circuit in which GATA-3 restrains the ability of PU.1 to cause myeloid differentiation of DN pro-T cells, even when Spi1 expression itself is not under GATA-3 control (43). PU.1 naturally begins at high levels in ETP and DN2a cells, but falls immediately after GATA-3 reaches its peak (data not shown) (42), and our results suggested that GATA-3 might be required for this decline.…”

Section: Resultsmentioning

confidence: 99%

“…However, in contrast to cells transduced with Gata3 shRNA, now Zfpm1 (FOG1) was clearly downregulated. This was significant because Zfpm1 exhibits strong binding of GATA-3 in vivo (13) and seems responsive to GATA-3 in a model cell line system (43). If incubation was continued for an additional day before harvesting the cells, detectable reductions in Tcf7, Rag1, Kit , and Zbtb16 (PLZF) were seen, as well as effects on Bcl11b and Ets1 (Fig.…”

Section: Resultsmentioning

confidence: 99%

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GATA-3 Dose-Dependent Checkpoints in Early T Cell Commitment

Scripture-Adams

Damle

et al. 2014

The Journal of Immunology

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126

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GATA-3 expression is crucial for T cell development and peaks during commitment to the T-cell lineage, midway through the CD4−CD8− (DN) 1-3 stages. We used RNA interference and conditional deletion to reduce GATA-3 protein acutely at specific points during T-cell differentiation in vitro. Even moderate GATA-3 reduction killed DN1 cells, delayed progression to DN2 stage, skewed DN2 gene regulation, and blocked appearance of DN3 phenotype. Although a Bcl-2 transgene rescued DN1 survival and improved DN2 cell generation, it did not restore DN3 differentiation. Gene expression analyses (qPCR, RNA-seq) showed that GATA-3-deficient DN2 cells quickly upregulated genes including Spi1 (PU.1) and Bcl11a and downregulated genes including Cpa3, Ets1, Zfpm1, Bcl11b, Il9r and Il17rb, with gene-specific kinetics and dose-dependencies. These targets could mediate two distinct roles played by GATA-3 in lineage commitment, as revealed by removing wildtype or GATA-3-deficient early T-lineage cells from environmental Notch signals. GATA-3 worked as a potent repressor of B-cell potential even at low expression levels, so that only full deletion of GATA-3 enabled pro-T cells to reveal B-cell potential. The ability of GATA-3 to block B-cell development did not require T-lineage commitment factor Bcl11b. In prethymic multipotent precursors, however, titration of GATA-3 activity using tamoxifen-inducible GATA-3 showed that GATA-3 inhibits B and myeloid developmental alternatives at different threshold doses. Furthermore, differential impacts of a GATA-3 obligate repressor construct imply that B and myeloid development are inhibited through distinct transcriptional mechanisms. Thus, the pattern of GATA-3 expression sequentially produces B-lineage exclusion, T-lineage progression, and myeloid-lineage exclusion for commitment.

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Section: Resultsmentioning

confidence: 58%

Section: Resultsmentioning

confidence: 99%

Section: Resultsmentioning

confidence: 99%

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GATA-3 Dose-Dependent Checkpoints in Early T Cell Commitment

Scripture-Adams

Damle

et al. 2014

The Journal of Immunology

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126

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“…These studies indicate that Pu.1 may be repressed gradually following T cell commitment from HSCs. In the thymus, antagonism between Notch and Pu.1 maintains the identity of T cell progenitor and prevents the adoption of myeloid fate (Del Real and Rothenberg, 2013;Franco et al, 2006). However, the underlying molecular mechanism for the downregulation of Pu.1 at the prethymic stage is still unclear.…”

Section: Discussionmentioning

confidence: 99%

Irf4 Regulates the Choice between T Lymphoid-Primed Progenitor and Myeloid Lineage Fates during Embryogenesis

Wang

et al. 2015

Developmental Cell

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T lymphoid-primed progenitors are hematopoietic progenitors destined to enter the thymus. The in vivo characterization of these embryonic progenitors is challenging, however, due to the intrauterine development of mouse embryos. Thus, how the fate of these cells is determined has not been fully defined in mammals. Here we use zebrafish embryos to show that the homing of T lymphoid-primed progenitors to the thymus is impaired, concomitant with a decrease in ccr9a expression, in the absence of irf4a. Strikingly, fate mapping assays at the single-cell level showed a fate change of irf4a-deficient T lymphoid-primed progenitors to myeloid cells, accompanied by an increase in Pu.1 expression. These data indicate that in addition to regulating ccr9a expression, Irf4a is essential in T lymphoid-primed progenitors for repressing Pu.1 expression to prevent an alternate fate. Our findings provide insight into the fate determination mechanism of T lymphoid-primed progenitors.

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“…Importantly and similar to the erythroid lineage, PU.1 expression is required in later T-cell progenitors to become repressed (Anderson et al, 2002), stays repressed in Th2 cells and CD8 T cells, but is reexpressed in Th9 cells (Gerlach et al, 2014). To achieve PU.1 repression in early T cells, the activity of PU.1 is antagonized by Notch, which is essential to push thymocytes into further maturation (Del Real and Rothenberg, 2013). Moreover, T-cell-specific repression of PU.1 expression is thought to be facilitated by binding of Runx1 to a silencer element located between the Sfpi1 promoter and its upstream enhancer elements (Zarnegar et al, 2010).…”

Section: Pu1 Cross-talk With Other Lineagespecific Transcription Facmentioning

confidence: 99%

Epigenetic control of hematopoiesis: the PU.1 chromatin connection

Riel

Rosenbauer

2014

Biological Chemistry

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Purine-rich box1 (PU.1) is a transcription factor that not only has a key role in the development of most hematopoietic cell lineages but also in the suppression of leukemia. To exert these functions, PU.1 can cross-talk with multiple different proteins by forming complexes in order to activate or repress transcription. Among its protein partners are chromatin remodelers, DNA methyltransferases, and a number of other transcription factors with important roles in hematopoiesis. While a great deal of knowledge has been acquired about PU.1 function over the years, it was the development of novel genome-wide technologies, which boosted our understanding of how PU.1 acts on the chromatin to drive its repertoire of target genes. This review summarizes current knowledge and ideas of molecular mechanisms by which PU.1 controls hematopoiesis and suppresses leukemia.

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Architecture of a lymphomyeloid developmental switch controlled by PU.1, Notch and Gata3

Cited by 88 publications

References 40 publications

GATA-3 Dose-Dependent Checkpoints in Early T Cell Commitment

GATA-3 Dose-Dependent Checkpoints in Early T Cell Commitment

Irf4 Regulates the Choice between T Lymphoid-Primed Progenitor and Myeloid Lineage Fates during Embryogenesis

Epigenetic control of hematopoiesis: the PU.1 chromatin connection

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