Mice with a complete deficiency of p73 have severe neurological and immunological defects due to the absence of all TAp73 and DeltaNp73 isoforms. As part of our ongoing program to distinguish the biological functions of these isoforms, we generated mice that are selectively deficient for the DeltaNp73 isoform. Mice lacking DeltaNp73 (DeltaNp73(-/-) mice) are viable and fertile but display signs of neurodegeneration. Cells from DeltaNp73(-/-) mice are sensitized to DNA-damaging agents and show an increase in p53-dependent apoptosis. When analyzing the DNA damage response (DDR) in DeltaNp73(-/-) cells, we discovered a completely new role for DeltaNp73 in inhibiting the molecular signal emanating from a DNA break to the DDR pathway. We found that DeltaNp73 localizes directly to the site of DNA damage, can interact with the DNA damage sensor protein 53BP1, and inhibits ATM activation and subsequent p53 phosphorylation. This novel finding may explain why human tumors with high levels of DeltaNp73 expression show enhanced resistance to chemotherapy.
The Snail transcription factor plays a key role in regulating diverse developmental processes but is not thought to play a role in mammalian neural precursors. Here, we have examined radial glial precursor cells of the embryonic murine cortex and demonstrate that Snail regulates their survival, self-renewal, and differentiation into intermediate progenitors and neurons via two distinct and separable target pathways. First, Snail promotes cell survival by antagonizing a p53-dependent death pathway because coincident p53 knockdown rescues survival deficits caused by Snail knockdown. Second, we show that the cell cycle phosphatase Cdc25b is regulated by Snail in radial precursors and that Cdc25b coexpression is sufficient to rescue the decreased radial precursor proliferation and differentiation observed upon Snail knockdown. Thus, Snail acts via p53 and Cdc25b to coordinately regulate multiple aspects of mammalian embryonic neural precursor biology.
We have previously demonstrated that neuronal oxytocin mRNA increases during the pubertal development of female rats. In this paper we have examined the factors that regulate this developmental increase in both male and female rats. Northern blot analysis demonstrated that neural oxytocin mRNA increased 5- to 10-fold from postnatal day 20 (P20) to P60 in animals of both sexes, coincident with puberty. Mature male rats and females at all stages of the estrous cycle expressed similar levels of neural oxytocin mRNA. Pubertal up-regulation of oxytocin mRNA was largely, but not completely, inhibited by prepubescent gonadectomy, indicating a requirement for intact gonads as well as some other as yet undefined factor(s). Pubertal treatment of gonadectomized animals with estradiol or testosterone abolished the effects of gonadectomy; treated animals expressed levels of neural oxytocin mRNA similar to those in controls. However, treatment of prepubertal animals with estradiol or testosterone from P10 to P20 had no effect on oxytocin mRNA levels, suggesting that neural maturation or other factors are necessary requisites for steroid sensitivity. To determine whether neural activin played any role in regulating oxytocin mRNA during puberty, we examined levels of inhibin/activin βA-chain mRNA. This mRNA was expressed at similar levels in all brain regions and did not vary as a function of gonadectomy or steroid treatment, making it unlikely that activin mediates the observed changes. Together, these data indicate that neural oxytocin mRNA is induced by gonadal steroids during puberty, and suggest a mechanism for coordinating development of reproductive functions with other pubertal changes.
ADVERTISEMENT RETURN TO ISSUEPREVArticleNEXTTandem repeats of a specific alternating purine-pyrimidine DNA sequence adjacent to protamine genes in the rainbow trout that can exist in the Z formJudd M. Aiken, Freda D. Miller, Fred Hagen, Debbie I. McKenzie, Stephen A. Krawetz, Johan H. van de Sande , J. B. Rattner, and Gordon H. DixonCite this: Biochemistry 1985, 24, 22, 6268–6276Publication Date (Print):October 1, 1985Publication History Published online1 May 2002Published inissue 1 October 1985https://pubs.acs.org/doi/10.1021/bi00343a034https://doi.org/10.1021/bi00343a034research-articleACS PublicationsRequest reuse permissionsArticle Views41Altmetric-Citations7LEARN ABOUT THESE METRICSArticle Views are the COUNTER-compliant sum of full text article downloads since November 2008 (both PDF and HTML) across all institutions and individuals. These metrics are regularly updated to reflect usage leading up to the last few days.Citations are the number of other articles citing this article, calculated by Crossref and updated daily. Find more information about Crossref citation counts.The Altmetric Attention Score is a quantitative measure of the attention that a research article has received online. Clicking on the donut icon will load a page at altmetric.com with additional details about the score and the social media presence for the given article. Find more information on the Altmetric Attention Score and how the score is calculated. Share Add toView InAdd Full Text with ReferenceAdd Description ExportRISCitationCitation and abstractCitation and referencesMore Options Share onFacebookTwitterWechatLinked InRedditEmail Other access optionsGet e-AlertscloseSupporting Info (1)»Supporting Information Supporting Information Get e-Alerts
The transplantation of Schwann cells (SCs) holds considerable promise as a therapy for spinal cord injury, but the optimal source of these cells and the best timing for intervention remains debatable. Previously, we demonstrated that delayed transplantation of SCs generated from neonatal mouse skin-derived precursors (SKP-SCs) promoted repair and functional recovery in rats with thoracic contusions. Here, we conducted two experiments using neonatal rat cells and an incomplete cervical injury model to examine the efficacy of acute SKP-SC transplantation versus media control (Experiment 1) and versus nerve-derived SC or dermal fibroblast (Fibro) transplantation (Experiment 2). Despite limited graft survival, by 10 weeks after injury, rats that received SCs from either source showed improved functional recovery compared with media- or fibroblast-treated animals. Compared with media treatment, SKP-SC-transplanted rats showed enhanced rubrospinal tract (RST) sparing/plasticity in the gray matter (GM) rostral to injury, particularly in the absence of immunosuppression. The functional benefits of SC transplantations over fibroblast treatment correlated with the enhanced preservation of host tissue, reduced RST atrophy, and/or increased RST sparing/plasticity in the GM. In summary, our results indicate that: (1) early transplantation of neonatal SCs generated from skin or nerve promotes repair and functional recovery after incomplete cervical crush injury; (2) either of these cell types is preferable to Fibros for these purposes; and (3) age-matched SCs from these two sources do not differ in terms of their reparative effects or functional efficacy after transplantation into the injured cervical spinal cord.
AbstractOne of the fundamental questions in neurobiology is how mammalian neurons survive for an organism's lifetime in the face of normal ongoing "wear and tear" that, in the case of neurons in the peripheral nervous system, even includes physical damage. Elucidating the mechanisms that control neuronal survival is of importance not only for our understanding of normal development of neuronal circuitry, but also to devise treatments for pathological situations such as traumatic injury, or neurodegenerative conditions. In this review, we will cover the emerging evidence that p63 plays an essential role in regulating neuronal life and death decisions in the nervous system working in concert with its two other family members, p53 and p73.
Animals such as amphibians have an incredible capacity for regeneration with some being able to regrow their tail or appendages. Although some mammalian tissues like the skin and bones can repair following injury, there are only a few examples of true multilineage regeneration, including the distal portion of the digit tip. In both amphibians and mammals, however, to achieve successful repair or regeneration, it is now appreciated that intact nerve innervation is a necessity. Here, we review the current state of literature and discuss recent advances that identify axon-derived signals, Schwann cells, and nerve-derived mesenchymal cells as direct and indirect supporters of adult tissue homeostasis and repair. We posit that understanding how nerves positively influence repair and regeneration could lead to targeted regenerative medicine strategies to enhance tissue repair in humans.
The extracellular signal-regulated kinase (ERK) cascade, a key component of mitogen-activated protein kinase signalling, is important in synaptic plasticity, in mediating mitogenic and trophic effects, as well as for cell proliferation in normal and transformed non-neuronal cells. Here, we explored phosphorylated ERK immunoreactivity (pERK-IR) following hypoxic-ischaemic (HI) insult in postnatal day 7–8 mice (equivalent to approx 31–32 week human gestation) by unilateral carotid artery occlusion, followed by hypoxia (8% O2/N2). Exposure to 30 min HI resulted in massive increase in forebrain pERK-IR followed by strong white matter (WM) damage, but only mild involvement of the overlying cortical grey matter. Mapping for activated pERK revealed a time-clock sequence of cellular events, beginning with periventricular WM axons (15–45 min post HI onset), followed by white and grey matter glia and cortical neurons (1–4 h post HI onset), returning to normal by 8 h. Systemic inhibition of MEK1/2 with SL327 resulted in significant decrease in WM damage. This could point to activated MEK1/2 and ERK as promising targets for therapeutic intervention in neonatal brain damage, and in prevention of periventricular leukomalacia.
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