Project description:The stepwise conversion of multipotent precursors into committed T-cell progenitors depends on several transcriptional regulators, but the interplay between these factors is still obscure. This is particularly true in human since the core early Notch signalling pathway also supports NK cell development and requires tight regulation for efficient T-lineage commitment and differentiation. Here, we show that GATA3, in contrast to TCF1, induces T-lineage commitment following NOTCH1-induced T-lineage specification through direct regulation of at least 3 distinct processes: repression of NK-cell fate, activation of T-lineage genes to promote further differentiation, and downmodulation of Notch signalling activity. GATA3-mediated repression of the NOTCH1 target gene DTX1 hereby is essential to induce T-lineage commitment at the expense of NK cell differentiation. Thus, human T-lineage commitment is dependent on the precise collaboration of several transcriptional regulators that integrate through both positive and negative regulatory loops. ChIP-sequencing data was generated for GATA3 in human thymocytes

Project description:The stepwise conversion of multipotent precursors into committed T-cell progenitors depends on several transcriptional regulators, but the interplay between these factors is still obscure. This is particularly true in human since the core early Notch signalling pathway also supports NK cell development and requires tight regulation for efficient T-lineage commitment and differentiation. Here, we show that GATA3, in contrast to TCF1, induces T-lineage commitment following NOTCH1-induced T-lineage specification through direct regulation of at least 3 distinct processes: repression of NK-cell fate, activation of T-lineage genes to promote further differentiation, and downmodulation of Notch signalling activity. GATA3-mediated repression of the NOTCH1 target gene DTX1 hereby is essential to induce T-lineage commitment at the expense of NK cell differentiation. Thus, human T-lineage commitment is dependent on the precise collaboration of several transcriptional regulators that integrate through both positive and negative regulatory loops. Gene expression was profiled in CT CD34+ cells after transduction with control or GATA3 and coculture on OP9-DL1 for 48h. Cells were collected 48h after coculture and sorted for CD45+EGFP+. 3 independent experiments were performed on 3 different thymus donors.

Project description:The stepwise conversion of multipotent precursors into committed T-cell progenitors depends on several transcriptional regulators, but the interplay between these factors is still obscure. This is particularly true in human since the core early Notch signalling pathway also supports NK cell development and requires tight regulation for efficient T-lineage commitment and differentiation. Here, we show that GATA3, in contrast to TCF1, induces T-lineage commitment following NOTCH1-induced T-lineage specification through direct regulation of at least 3 distinct processes: repression of NK-cell fate, activation of T-lineage genes to promote further differentiation, and downmodulation of Notch signalling activity. GATA3-mediated repression of the NOTCH1 target gene DTX1 hereby is essential to induce T-lineage commitment at the expense of NK cell differentiation. Thus, human T-lineage commitment is dependent on the precise collaboration of several transcriptional regulators that integrate through both positive and negative regulatory loops.

Project description:Here, we show that GATA3 induces T-lineage commitment following Notch-induced T-lineage specification through direct regulation of at least 3 distinct processes: repression of NK-cell fate, activation of T-lineage genes to promote further differentiation, and down modulation of Notch signalling activity.

Project description:Here, we show that GATA3 induces T-lineage commitment following Notch-induced T-lineage specification through direct regulation of at least 3 distinct processes: repression of NK-cell fate, activation of T-lineage genes to promote further differentiation, and down modulation of Notch signalling activity. Gene expression was measured in RPMI8402 cells after transduction with control, shGATA3 or shTCF1 and culture for 48h. Cells were collected 48h after transduction and sorted for EGFP+. This was performed for 2 replicates.

Project description:In both mouse and human, Notch1 activation is the main initial driver to induce T-cell development in hematopoietic progenitor cells. The initiation of this developmental process coincides with Notch1-dependent repression of differentiation towards other hematopoietic lineages. Although well described in mice, the role of the individual Notch1 target genes during these hematopoietic developmental choices is still unclear in human. Here, we investigated the functional capacity of the Notch1 target genes HES1 and HES4 to modulate human Notch1-dependent hematopoietic lineage decisions. Using well-established in vitro cocultures and RNA sequencing, we show that HES1 acts as a repressor of differentiation by maintaining a quiescent stem cell signature in CD34+ hematopoietic progenitor cells. While HES4 can also inhibit NK and myeloid development like HES1, it acts differently on the T- versus B-cell lineage choice. Surprisingly, HES4 is not capable of repressing B-cell development, the most sensitive hematopoietic lineage with respect to Notch-mediated repression. In contrast to HES1, HES4 promotes initiation of early T-cell development. Overall, we show that the Notch1 target genes HES1 and HES4 display both unique and overlapping functions downstream of Notch during human hematopoietic lineage decisions.

Project description:T-cell differentiation requires Notch1 signaling. Here we show that an enhancer upstream of Notch1 active in double-negative (DN) thymocytes is responsible for raising Notch1 signaling intra-thymically. This enhancer is required to expand multipotent progenitors intra-thymically while delaying early differentiation until lineage restrictions are established. Early thymic progenitors lacking the enhancer show accelerated differentiation through the DN stages and increased frequency of B-, ILC-, and NK-cell differentiation. Transcription regulators for T-cell lineage restriction and commitment are expressed normally, but ILC- and NK-cell gene expression persists after T-lineage commitment and TCR V-DJ recombination, Cd3 expression and -selection are impaired. This Notch1 enhancer is inactive in double-positive (DP) thymocytes. Its aberrant reactivation at this stage in Ikaros mutants is required for leukemogenesis. Thus, the DN-specific Notch1 enhancer harnesses the regulatory architecture of DN and DP thymocytes to achieve carefully orchestrated changes in Notch1 signaling required for early lineage restrictions and normal T-cell differentiation.

Project description:T cell differentiation requires Notch1 signaling. Here we show that an enhancer upstream of Notch1 active in double-negative (DN) mouse thymocytes is responsible for raising Notch1 signaling intra-thymically. This enhancer is required to expand multipotent progenitors intra-thymically while delaying early differentiation until lineage restrictions are established. Early thymic progenitors lacking the enhancer show accelerated differentiation through the DN stages and increased frequency of B-, ILC-, and NK-cell differentiation. Transcription regulators for T cell lineage restriction and commitment are expressed normally, but ILC- and NK-cell gene expression persists after T cell lineage commitment and TCRb V-DJ recombination, Cd3 expression and b-selection are impaired. This Notch1 enhancer is inactive in double-positive (DP) thymocytes. Its aberrant reactivation at this stage in Ikaros mutants is required for leukemogenesis. Thus, the DN-specific Notch1 enhancer harnesses the regulatory architecture of DN and DP thymocytes to achieve carefully orchestrated changes in Notch1 signaling required for early lineage restrictions and normal T cell differentiation.

Project description:This randomized phase I/II clinical trial is studying the side effects and best dose of gamma-secretase/notch signalling pathway inhibitor RO4929097 when given together with vismodegib and to see how well they work in treating patients with advanced or metastatic sarcoma. Vismodegib may slow the growth of tumor cells. Gamma-secretase/notch signalling pathway inhibitor RO4929097 may stop the growth of tumor cells by blocking some of the enzymes needed for cell growth. Giving vismodegib together with gamma-secretase/notch signalling pathway inhibitor RO4929097 may be an effective treatment for sarcoma.

Project description:GATA3 restrains Notch signaling activity and represses NK cell development to induce human T cell commitment following Notch-induced T-lineage specification