Notch signals are required for in vitro but not in vivo maintenance of human hematopoietic stem cells and delay the appearance of multipotent progenitors.

All blood cell lineages start from hematopoietic stem cells (HSCs), which were recently shown to represent a heterogeneous group of cells. In mice, Notch signaling promotes the maintenance of "stemness" as well as the expansion of self-renewing HSCs in vitro. Additionally, human CD34(+) cells were shown to expand in vitro in response to Notch signals.

HES1 opposes a PTEN-dependent check on survival, differentiation, and proliferation of TCRβ-selected mouse thymocytes.

The developmental progression of immature thymocytes requires cooperative input from several pathways, with Notch signals playing an indispensable role at the T-cell receptor (TCR)-β selection checkpoint. Notch signals affect the activation of the PI3K/Akt pathway, which is required for pTα/TCRβ (pre-TCR)-induced survival, differentiation, and proliferation of developing αβ-lineage thymocytes. However, the molecular players responsible for the interaction between the Notch and PI3K pathways at this critical developmental stage are unknown.

Stage-specific and differential notch dependency at the alphabeta and gammadelta T lineage bifurcation.

Signals transduced by Notch receptors are indispensable for T cell specification and differentiation of alphabeta T lineage cells. However, the role of Notch signals during alphabeta versus gammadelta T lineage decision remains controversial. Here, we addressed this question by employing a clonal analysis of CD4(-)CD8(-) (DN) progenitor potential to position the divergence of alphabeta and gammadelta T cell lineages to the late DN2 to DN3 developmental stages.