Unique requirement for Rb/E2F3 in neuronal migration: evidence for cell cycle-independent functions.

The cell cycle regulatory retinoblastoma (Rb) protein is a key regulator of neural precursor proliferation; however, its role has been expanded to include a novel cell-autonomous role in mediating neuronal migration. We sought to determine the Rb-interacting factors that mediate both the cell cycle and migration defects. E2F1 and E2F3 are likely Rb-interacting candidates that we have shown to be deregulated in the absence of Rb.

A cell-autonomous requirement for the cell cycle regulatory protein, Rb, in neuronal migration.

Precise cell cycle regulation is critical for nervous system development. To assess the role of the cell cycle regulator, retinoblastoma (Rb) protein, in forebrain development, we studied mice with telencephalon-specific Rb deletions. We examined the role of Rb in neuronal specification and migration of diverse neuronal populations.

Apoptosis-inducing factor is a key factor in neuronal cell death propagated by BAX-dependent and BAX-independent mechanisms.

Mitochondria release proteins that propagate both caspase-dependent and caspase-independent cell death pathways. AIF (apoptosis-inducing factor) is an important caspase-independent death regulator in multiple neuronal injury pathways. Presently, there is considerable controversy as to whether AIF is neuroprotective or proapoptotic in neuronal injury, such as oxidative stress or excitotoxicity.

p107 regulates neural precursor cells in the mammalian brain.

Here we show a novel function for Retinoblastoma family member, p107 in controlling stem cell expansion in the mammalian brain. Adult p107-null mice had elevated numbers of proliferating progenitor cells in their lateral ventricles. In vitro neurosphere assays revealed striking increases in the number of neurosphere forming cells from p107(-/-) brains that exhibited enhanced capacity for self-renewal.

Growth factors: can they promote neurogenesis?

Cortical development is a complex process in which extrinsic and intrinsic factors modulate the sequential generation of neurons and glia. Following successive rounds of division, precursors become determined along a neuronal or glial lineage prior to cell cycle exit and differentiation. Although the influence of growth factors in cell fate specification is not new, until recently little was known about the signaling pathways by which they regulate neuronal differentiation.

Telencephalon-specific Rb knockouts reveal enhanced neurogenesis, survival and abnormal cortical development.

Correct cell cycle regulation and terminal mitosis are critical for nervous system development. The retinoblastoma (Rb) protein is a key regulator of these processes, as Rb-/- embryos die by E15.5, exhibiting gross hematopoietic and neurological defects.