scholarly journals The Motor Neuron-Like Cell Line NSC-34 and Its Parent Cell Line N18TG2 Have Glycogen that is Degraded Under Cellular Stress

2021 ◽  
Author(s):  
Brigitte Pfeiffer-Guglielmi ◽  
Ralf-Peter Jansen
Keyword(s):  
Cell Line ◽  
Cell Lines ◽  
Glycogen Phosphorylase ◽  
Metabolic Stress ◽  
Neuronal Cell ◽  
Parent Cell ◽  
Normal Brain ◽  
Storage Site ◽  
Neuronal Cell Lines

AbstractBrain glycogen has a long and versatile history: Primarily regarded as an evolutionary remnant, it was then thought of as an unspecific emergency fuel store. A dynamic role for glycogen in normal brain function has been proposed later but exclusively attributed to astrocytes, its main storage site. Neuronal glycogen had long been neglected, but came into focus when sensitive technical methods allowed quantification of glycogen at low concentration range and the detection of glycogen metabolizing enzymes in cells and cell lysates. Recently, an active role of neuronal glycogen and even its contribution to neuronal survival could be demonstrated. We used the neuronal cell lines NSC-34 and N18TG2 and could demonstrate that they express the key-enzymes of glycogen metabolism, glycogen phosphorylase and glycogen synthase and contain glycogen which is mobilized on glucose deprivation and elevated potassium concentrations, but not by hormones stimulating cAMP formation. Conditions of metabolic stress, namely hypoxia, oxidative stress and pH lowering, induce glycogen degradation. Our studies revealed that glycogen can contribute to the energy supply of neuronal cell lines in situations of metabolic stress. These findings shed new light on the so far neglected role of neuronal glycogen. The key-enzyme in glycogen degradation is glycogen phosphorylase. Neurons express only the brain isoform of the enzyme that is supposed to be activated primarily by the allosteric activator AMP and less by covalent phosphorylation via the cAMP cascade. Our results indicate that neuronal glycogen is not degraded upon hormone action but by factors lowering the energy charge of the cells directly.

scholarly journals The motor neuron-like cell line NSC-34 and its parent cell line N18TG2 have glycogen that is degraded under cellular stress

2020 ◽  
Author(s):  
Brigitte Pfeiffer-Guglielmi ◽  
Ralf-Peter Jansen
Keyword(s):  
Cell Line ◽  
Energy Charge ◽  
Metabolic Stress ◽  
Neuronal Cell ◽  
Glycogen Metabolism ◽  
Active Role ◽  
Parent Cell ◽  
Normal Brain ◽  
Storage Site ◽  
Key Enzyme

AbstractBrain glycogen has a long and versatile history: Primarily regarded as an evolutionary remnant, it was then thought of as an unspecific emergency fuel store. A dynamic role for glycogen in normal brain function has been proposed later but exclusively attributed to astrocytes, its main storage site. Neuronal glycogen had long been neglected, but came into focus when sensitive technical methods allowed quantification of glycogen at low concentration range and the detection of glycogen metabolizing enzymes in cells and cell lysates. Recently, an active role of neuronal glycogen and even its contribution to neuronal survival could be demonstrated. Our studies continue these investigations on the function and regulation of neuronal glycogen metabolism. We demonstrate the presence of an active glycogen metabolism in the neuronal cell lines NSC-34 and N18TG2 and the mobilization of the glycogen stores under hypoxia, oxidative and acidic metabolic stress. The key enzyme in glycogen degradation is glycogen phosphorylase. Neurons express only the brain isoform (GPBB) that is supposed to be activated primarily by the allosteric activator AMP and less by covalent phosphorylation via the cAMP cascade. Our results indicate that neuronal glycogen is not degraded upon hormone action but by factors lowering the energy charge of the cells directly.

scholarly journals Role of the saturated fatty acid palmitate in the interconnected hypothalamic control of energy homeostasis and biological rhythms

2018 ◽  
Vol 315 (2) ◽  
pp. E133-E140 ◽  
Author(s):  
Erika K. Tse ◽  
Ashkan Salehi ◽  
Matthew N. Clemenzi ◽  
Denise D. Belsham
Keyword(s):  
Circadian Rhythms ◽  
Cell Lines ◽  
High Fat Diet ◽  
Energy Homeostasis ◽  
Clock Gene ◽  
Neuronal Cell ◽  
Whole Body ◽  
High Fat ◽  
Neuronal Cell Lines

The brain, specifically the hypothalamus, controls whole body energy and glucose homeostasis through neurons that synthesize specific neuropeptides, whereas hypothalamic dysfunction is linked directly to insulin resistance, obesity, and type 2 diabetes mellitus. Nutrient excess, through overconsumption of a Western or high-fat diet, exposes the hypothalamus to high levels of free fatty acids, which induces neuroinflammation, endoplasmic reticulum stress, and dysregulation of neuropeptide synthesis. Furthermore, exposure to a high-fat diet also disrupts normal circadian rhythms, and conversely, clock gene knockout models have symptoms of metabolic disorders. While whole brain/animal studies have provided phenotypic end points and important clues to the genes involved, there are still major gaps in our understanding of the intracellular pathways and neuron-specific components that ultimately control circadian rhythms and energy homeostasis. Because of its complexity and heterogeneous nature, containing a diverse mix cell types, it is difficult to dissect the critical hypothalamic components involved in these processes. Of significance, we have the capacity to study these individual components using an extensive collection of both embryonic- and adult-derived, immortalized hypothalamic neuronal cell lines from rodents. These defined neuronal cell lines have been used to examine the impact of nutrient excess, such as palmitate, on circadian rhythms and neuroendocrine signaling pathways, as well as changes in vital neuropeptides, leading to the development of neuronal inflammation; the role of proinflammatory molecules in this process; and ultimately, restoration of normal signaling, clock gene expression, and neuropeptide synthesis in disrupted states by beneficial anti-inflammatory compounds in defined hypothalamic neurons.

On the Application of Cultured Neuronal Cell Lines in Neurotoxicological Studies: Cytotoxicity of Acrylamide

1983 ◽  
Vol 11 (3) ◽  
pp. 135-145
Author(s):  
Erik Walum
Keyword(s):  
Cell Lines ◽  
Culture Medium ◽  
Neuroblastoma Cells ◽  
Neuronal Cell ◽  
Leucine Incorporation ◽  
Biochemical Process ◽  
Neurite Retraction ◽  
Mouse Neuroblastoma ◽  
Neuronal Cell Lines

Summary Acrylamide, a well known neurotoxic compound, was used in a first evaluation of cultured mouse neuroblastoma cells as an alternative to animal models for neurotoxicological studies. Hence, the effects of acrylamide on the growth, size, morphology and leucine incorporation of three neuroblastoma (41A3, N18 and N1E115), one neuroblastoma x glioma hybrid (NG108CC15), two glioma (138MG and C6) and two fibroblast (RLF and RMC) cell lines were studied. It was found that the concentration of acrylamide needed to inhibit the growth by 50% in 24 hr was similar in all cell lines, i.e. around 2 x 10-4g/ml culture medium. In the two cell lines, N1E115 and NG108CC15, acrylamide at this concentration caused neurite retraction and at higher concentrations (5 x 10-4g/ml) a decrease in cell viability. In a concentration range of 5 x 10-5 - 5 x 10-4g/ml acrylamide did not affect cell size, or at 2 x 10-4g/ml incorporation of leucine into trichloroacetic acid precipitable material. It is suggested that acrylamide interferes with a biochemical process common to all the tested cells, but of greater importance in differentiated nerve cells than in others. Whether this process is consistent with the in vivo target for the neurotoxic action of acrylamide remains to be unravelled.

Breakpoint junctions of chromosome 9p deletions in two human glioma cell lines

1994 ◽  
Vol 14 (11) ◽  
pp. 7604-7610
Author(s):  
H M Pomykala ◽  
S K Bohlander ◽  
P L Broeker ◽  
O I Olopade ◽  
M O Díaz
Keyword(s):  
Cell Line ◽  
Cell Lines ◽  
Lymphoblastic Leukemia ◽  
Repetitive Sequences ◽  
Leukemia Cell ◽  
Chromosome 9 ◽  
Breakpoint Junction ◽  
Leukemia Cell Lines ◽  
Long Interspersed Nuclear Elements

Interstitial deletions of the short arm of chromosome 9 are associated with glioma, acute lymphoblastic leukemia, melanoma, mesothelioma, lung cancer, and bladder cancer. The distal breakpoints of the deletions (in relation to the centromere) in 14 glioma and leukemia cell lines have been mapped within the 400 kb IFN gene cluster located at band 9p21. To obtain information about the mechanism of these deletions, we have isolated and analyzed the nucleotide sequences at the breakpoint junctions in two glioma-derived cell lines. The A1235 cell line has a complex rearrangement of chromosome 9, including a deletion and an inversion that results in two breakpoint junctions. Both breakpoints of the distal inversion junction occurred within AT-rich regions. In the A172 cell line, a tandem heptamer repeat was found on either side of the deletion breakpoint junction. The distal breakpoint occurred 5' of IFNA2; the 256 bp sequenced from the proximal side of the breakpoint revealed 95% homology to long interspersed nuclear elements. One- and two-base-pair overlaps were observed at these junctions. The possible role of sequence overlaps, and repetitive sequences, in the rearrangement is discussed.

Differentiated Neuronal Cell Lines as Donor Tissue for Transplantation into the CNS

1987 ◽  
Vol 495 (1 Cell and Tiss) ◽  
pp. 767-770 ◽  
Author(s):  
MARY F. D. NOTTER ◽  
JEFFREY H. KORDOWER ◽  
DON M. GASH
Keyword(s):  
Cell Lines ◽  
Neuronal Cell ◽  
Donor Tissue ◽  
Neuronal Cell Lines
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