Lengthening of G2/mitosis in cortical precursors from mice lacking beta-amyloid precursor protein.

The beta-amyloid precursor protein (APP) is expressed within the nervous system, even at the earliest stages of embryonic development when cell growth and proliferation is particularly important. In order to study the function of APP at these early developmental stages, we have studied the development of the cerebral cortex in both wild type and App-/- mutant mice. Here, we demonstrate that APP mRNA is expressed in cortical precursor cells and that APP protein is concentrated within their apical domains during interphase. However, during mitosis, APP re-localizes to the peripheral space surrounding the metaphase plate. In APP-deficient cortical precursors, the duration of mitosis is increased and a higher proportion of cortical precursor cells contained nuclei in late G2. We conclude that during cortical development APP plays a role in controlling cell cycle progression, particularly affecting G2 and mitosis. These observations may have important implications for our understanding of how APP influences the progression of Alzheimer's disease, since degenerating cortical neurons have been shown to up-regulate cell cycle markers and re-enter the mitotic cycle before dying.

Control of the cell cycle by neurotrophins: lessons from the p75 neurotrophin receptor.

Although traditionally little attention has been paid to the interplay between neurotrophins and the cell cycle, a number of recent findings suggest an important role for these growth factors in the regulation of this aspect of the cellular physiology. In this article, we review the evidence from a number of studies that neurotrophins can influence cell cycle progression or mitotic cycle arrest both in the nervous system as well as in other cell types. The contrary response of different cells to neurotrophins in terms of cell cycle regulation derives in part from the fact that these factors use two different receptor types to transmit their signals: members of the Trk family and the p75 neurotrophin receptor (p75NTR). With this in mind, we outline the current state of our knowledge regarding the molecular basis underlying the control of cell cycle progression by neurotrophins. We focus our interest on the receptors that transduce these signals and, in particular, the striking finding that p75NTR interacts with proteins that can promote mitotic cycle arrest. Finally, we discuss the mechanisms of cell death mediated by p75NTR in the context of cell cycle regulation.