Modified cell cycle status in a mouse model of altered neuronal vulnerability (Wallerian Degeneration Slow; WldS)
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Colleges, School and Institutes
Background Altered neuronal vulnerability underlies many diseases of the human nervous system, resulting in degeneration and loss of neurons. The neuroprotective Wallerian Degeneration Slow (Wld(s)) mutation delays degeneration in axonal and synaptic compartments of neurons following a wide range of traumatic and disease-inducing stimuli, providing a powerful experimental tool with which to investigate modulation of neuronal vulnerability. Although the mechanisms through which Wlds confers neuroprotection remain unclear a diverse range of downstream modifications, incorporating several genes/pathways, have been implicated. These include: elevated NAD levels associated with nicotinamide mononucleotide adenylyltransferase 1 (Nmnat1; a part of the chimeric Wld(s) gene);altered mRNA expression levels of genes such as pituitary tumor transforming gene 1 (Pttg1); changes in the location/activity of the ubiquitin-proteasome machinery via binding to valosin-containing protein (VCP/p97); and modified synaptic expression of proteins such as ubiquitin- activating Enzyme E1 (Ube1). Results Wld(s) expression in mouse cerebellum and HEK293 cells induced robust increases in a broad spectrum of cell cycle-related genes. Both NAD- and Pttg1-dependent pathways were responsible for mediating different subsets of these alterations, also incorporating changes in VCP/p97 localisation and Ube1 expression. Cell proliferation rates were not modified by Wld(s), suggesting that later mitotic phases of the cell cycle remained unaltered. We also demonstrate that Wld(s) concurrently altered endogenous cell stress pathways. Conclusions We report a novel cellular phenotype in cells with altered neuronal vulnerability. We show that previous reports of diverse changes occurring downstream from Wld(s) expression converge upon modifications in cell cycle status. These data suggest a strong correlation between modified cell cycle pathways and altered vulnerability of axonal and synaptic compartments in post-mitotic, terminally differentiated neurons.
|Publication status||Published - 1 Jan 2008|