Author
Scott R. Whittemore
Other affiliations: University of Miami, Uppsala University
Bio: Scott R. Whittemore is an academic researcher from University of Louisville. The author has contributed to research in topics: Spinal cord injury & Spinal cord. The author has an hindex of 59, co-authored 156 publications receiving 11069 citations. Previous affiliations of Scott R. Whittemore include University of Miami & Uppsala University.
Papers published on a yearly basis
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TL;DR: It is suggested that in vitro induction prior to transplantation will be necessary for these cells to differentiate into neurons or large numbers of oligodendrocytes, but a differentiated phenotype restricted to glial lineages is suggested.
497 citations
TL;DR: Investigation of nerve growth factor (NGF) mRNA and protein in the rat central nervous system revealed a widespread distribution of NGF-like reactivity in the adult brain, preferentially in fiber tracts.
Abstract: The presence of nerve growth factor (NGF) mRNA and protein in the rat central nervous system is documented. Blot-hybridization analysis showed an abundance of NGF mRNA in the hippocampus, cerebral cortex, and olfactory bulb. Enzyme immunoassay confirmed significant levels of a NGF-like protein in the hippocampus and cerebral cortex. Bioassay of a NGF-like immunoaffinity-purified protein from these regions was physiologically indistinguishable from NGF. Immunohistochemistry revealed a widespread distribution of NGF-like reactivity in the adult brain, preferentially in fiber tracts. NGF mRNA accumulation began at birth, with adult levels reached 3 weeks postnatally. Enzyme immunoassay detected the presence of a NGF-like protein in the embryonic rat brain. Postnatally, the level of NGF-like protein reached a maximum at 3 weeks. Additionally, a distinct fetal form of NGF may exist.
488 citations
TL;DR: NGF and central catecholaminergic neuronal function, NGF-induced alteration in adrenergic CNS function, and retrograde transport of NGF in Adrenergic pathways are studied.
485 citations
TL;DR: Compared signaling pathways activated by GDNF in two neuronal cell lines expressing different complements of GDNF receptors are compared to indicate the existence of novel signaling mechanisms directly or indirectly mediated by GFRα receptors acting in a cell-autonomous manner independently of Ret.
325 citations
TL;DR: The transplantation of SCs secreting increased amounts of BDNF improved the regenerative response across a transection site in the thoracic cord, and the largest response was from neurones known to express trkB.
Abstract: The infusion of BDNF and NT-3 into Schwann cell (SC) grafts promotes regeneration of brainstem neurones into the grafts placed in adult rat spinal cord transected at T8 (Xu et al., 1995b). Here, we compared normal SCs with SCs genetically modified to secrete human BDNF, grafted as trails 5 mm long in the cord distal to a transection site and also deposited in the transection site, for their ability to stimulate supraspinal axonal regeneration beyond the injury. SCs were infected with the replication-deficient retroviral vector pL(hBDNF)RNL encoding the human preproBDNF cDNA. The amounts of BDNF secreted (as detected by ELISA) were 23 and 5 ng/24 h per 106 cells for infected and normal SCs, respectively. Biological activity of the secreted BDNF was confirmed by retinal ganglion cell bioassay. The adult rat spinal cord was transected at T8. The use of Hoechst prelabelled SCs demonstrated that trails were maintained for a month. In controls, no SCs were grafted. One month after grafting, axons were present in SC trails. More 5-HT-positive and some DbetaH-positive fibres were observed in the infected vs. normal SC trails. When Fast Blue was injected 5 mm below the transection site (at the end of the trail), as many as 135 retrogradely labelled neurones could be found in the brainstem, mostly in the reticular and raphe nuclei (normal SCs, up to 22, mostly in vestibular nuclei). Numerous neurones were labelled in the ventral hypothalamus (normal SCs, 0). Also, following Fast Blue injection, a mean of 138 labelled cells was present in dorsal root ganglia (normal SCs, 46) and spinal cord (39 vs. 32) rostral to the transection. No labelled spinal neurones rostral to the transection were seen when SCs were not transplanted. Thus, the transplantation of SCs secreting increased amounts of BDNF improved the regenerative response across a transection site in the thoracic cord. Moreover, the enhanced regeneration observed with infected SCs may be specific as the largest response was from neurones known to express trkB.
317 citations
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TL;DR: It is now becoming clear that lipid micro-environments on the cell surface — known as lipid rafts — also take part in this process of signalling transduction, where protein–protein interactions result in the activation of signalling cascades.
Abstract: Signal transduction is initiated by complex protein-protein interactions between ligands, receptors and kinases, to name only a few. It is now becoming clear that lipid micro-environments on the cell surface -- known as lipid rafts -- also take part in this process. Lipid rafts containing a given set of proteins can change their size and composition in response to intra- or extracellular stimuli. This favours specific protein-protein interactions, resulting in the activation of signalling cascades.
6,080 citations
TL;DR: By better understanding AD inflammatory and immunoregulatory processes, it should be possible to develop anti-inflammatory approaches that may not cure AD but will likely help slow the progression or delay the onset of this devastating disorder.
4,319 citations
TL;DR: In this review particular emphasis is placed on the discrepancy between the concentrations ofadenosine, ADP, and ATP in the purine receptors of UDP and UTP.
Abstract: ### A. Overview
Extracellular purines (adenosine, ADP, and ATP) and pyrimidines (UDP and UTP) are important signaling molecules that mediate diverse biological effects via cell-surface receptors termed purine receptors. In this review particular emphasis is placed on the discrepancy between the
4,177 citations
TL;DR: The field of experimental embryology, which had been enthusiastically acclaimed in the mid-thirties, suffered from a sharp decrease in the enthusiasm that had inflamed the pioneers in this field, ever since R. G. Harrison delivered his celebrated lecture at the Royal Society in London in 1935.
Abstract: "Embryogenesis is in some way a model system. It has always been distinguished by the exactitude even punctitio, of its anatomical descriptions. An experiment by one of the great masters of embryology could be made the text of a discourse on scientific method. But something is wrong, or has been wrong. There is no theory of development in the sense in which Mendelism is a theory that accounts for the results of breeding experiments. There has therefore been little sense of progression or timeliness about embryological research. Of many papers delivered at embryological meetings, however good they may be in themselves . . . one too often feels that they might have been delivered five years beforehand without making anyone much the wiser, or deferred for five years without making anyone conscious of a great loss" (1). This feeling of frustration so incisively conveyed by these considerations by P. Medawar, pervaded, in the forties, the field of experimental embryology which had been enthusiastically acclaimed in the mid-thirties, when the upper lip of the amphibian blastopore brought this area of research to the forefront of the biological stage. The side branch of experimental neuroembryology, which had stemmed out from the common tree and was entirely devoted to the study of the tropic interrelations between neuronal cell populations and between these and the innervated organs and tissues, was then in its initial vigorous growth phase. It in turn suffered from a sharp decrease in the enthusiasm that had inflamed the pioneers in this field, ever since R. G. Harrison delivered his celebrated lecture on this topic at the Royal Society in London in 1935 (2). Although the alternate "wax and wane" cycles are the rule rather than the exception in all fields of human endeavor, in that of biological sciences the "wane" is all too often indicative of a justified loss of faith in the rational and methodical approach that had at first raised so much hope. A brief account of the state-of-the-art of experimental neuroembryology in the
3,061 citations