Neurofilaments Are Nonessential to the Pathogenesis of Toxicant-Induced Axonal Degeneration

Stone, J. D.; Peterson, Alan P.; Eyer, Joël; Oblak, Thomas G.; Sickles, Dale W.

doi:10.1523/jneurosci.21-07-02278.2001

Cited by 41 publications

(21 citation statements)

References 45 publications

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“…The neurotoxic action of AA was suggested to be due to effects on cells of the central and peripheral nervous system including changes in cellular metabolism (Howland et al, 1980;Brimijoin and Hammond,1985;Medrano and LoPachin, 1989;Exon, 2006), changes in gene transcription and protein synthesis (Cavanagh and Nolan, 1982a,b;Cavanagh, 1982;Cavanagh and Gysbers, 1983;Bisby and Redshaw, 1987;Lin et al, 2000;El-Alfy et al, 2011;Seale et al, 2012), effects on neurotransmitter levels and turn-over (Dixit et al, 1981;Uphouse and Russell, 1981;Aldous et al, 1983;Shi et al, 2012), binding to cellular proteins including damage to microtubular and neurofilamental proteins (Hashimoto and Aldridge, 1970;Tanii and Hashimoto, 1983;Carrington et al, 1991;Reagan et al, 1994;Abou-Donia, 1996, 1997;Lapadula et al, 1989;Xiwen et al, 1992), changes in ion distribution (Lehning et al, 1998;LoPachin and Lehning, 1994), and axonal transport (Chretien et al, 1981;Miller and Spencer, 1984;Gold et al, 1985;Moretto and Sabri, 1988;Logan and McLean, 1988;Harry et al, 1989;Sabri and Spencer, 1990;Martenson et al, 1995;Sickles et al, 1995Sickles et al, ,1996Stone et al, 2001). However, the minimal effects of AA-treatment, by up to a maximally tolerated dose, on: (i) gene expression related to cholinergic, noradrenergic, dopaminergic, GABAergic, or glutamatergic neurotransmitter systems; (ii) neurotransmitter levels related ...…”

Section: Mode Of Action Of Neurotoxicitymentioning

confidence: 99%

Scientific Opinion on acrylamide in food

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2015

EFS2

341

170

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EFSA was asked to deliver a scientific opinion on acrylamide (AA) in food. AA has widespread uses as an industrial chemical. It is also formed when certain foods are prepared at temperatures above 120 °C and low moisture, especially in foods containing asparagine and reducing sugars. The CONTAM Panel evaluated 43 419 analytical results from food commodities. AA was found at the highest levels in solid coffee substitutes and coffee, and in potato fried products. Mean and 95th percentile dietary AA exposures across surveys and age groups were estimated at 0.4 to 1.9 µg/kg body weight (b.w.) per day and 0.6 to 3.4 µg/kg b.w. per day, respectively. The main contributor to total dietary exposure was generally the category 'Potato fried products (except potato crisps and snacks)'. Preferences in home-cooking can have a substantial impact on human dietary AA exposure. Upon oral intake, AA is absorbed from the gastrointestinal tract and distributed to all organs. AA is extensively metabolised, mostly by conjugation with glutathione but also by epoxidation to glycidamide (GA). Formation of GA is considered to represent the route underlying the genotoxicity and carcinogenicity of AA. Neurotoxicity, adverse effects on male reproduction, developmental toxicity and carcinogenicity were identified as possible critical endpoints for AA toxicity from experimental animal studies. The data from human studies were inadequate for dose-response assessment. The CONTAM Panel selected BMDL 10 values of 0.43 mg/kg b.w. per day for peripheral neuropathy in rats and of 0.17 mg/kg b.w. per day for neoplastic effects in mice. The Panel concluded that the current levels of dietary exposure to AA are not of concern with respect to non-neoplastic effects. However, although the epidemiological associations have not demonstrated AA to be a human carcinogen, the margins of exposure (MOEs) indicate a concern for neoplastic effects based on animal evidence. © European Food SUMMARYFollowing a request from the European Commission, the Panel on Contaminants in the Food Chain (CONTAM Panel) was asked to deliver a scientific opinion on acrylamide (AA) in food. The Panel developed the draft scientific opinion which underwent a public consultation from 1 July 2014 to 15 September 2014. The comments received and how they were taken into account when finalising the scientific opinion were published in an EFSA Technical Report (EFSA, 2015).AA is a low molecular weight, highly water soluble, organic compound. It is used inter alia as an industrial chemical and in the production of polyacrylamides. Heightened concerns about exposure to AA arose in 2002 when it was discovered that it forms when certain foods are prepared at temperatures usually above 120 °C and low moisture. It forms, at least in part, due to a Maillard reaction between certain amino acids, such as asparagine, and reducing sugars. However, several other pathways and precursors have also been proposed to contribute to AA formation. AA forms in numerous baked or fried carbohydrate-rich f...

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Section: Mode Of Action Of Neurotoxicitymentioning

confidence: 99%

Scientific Opinion on acrylamide in food

Publication¹

2015

EFS2

341

170

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“…The administration of acrylamide also increases the expression of mRNA for NF proteins and the phosphorylation of NF in rats [444][445][446] but decreases their degradation [447]. However, acrylamide-induced neurotoxicity is not initiated exclusively through its action on axonal NF because NF-deficient mutant quiver quails, crayfish (a species lacking NF) and NFH-LacZ mice are sensitive to neurotoxic effects of acrylamide [448][449][450].…”

Section: Toxic Agents That Disorganise the Neurofilament Networkmentioning

confidence: 99%

Review of the Multiple Aspects of Neurofilament Functions, and their Possible Contribution to Neurodegeneration

et al. 2008

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Neurofilaments (NF) are the most abundant cytoskeletal component of large myelinated axons from adult central and peripheral nervous system. Here, we provide an overview of the complementary approaches, including biochemistry, cell biology and transgenic technology that were used to investigate the assembly, axonal transport and functions of NF in normal and pathological situations. Following their synthesis and assembly in the cell body, NFs are transported along the axon. This process is finely regulated via phosphorylation of the carboxy-terminal part of the two high-molecular-weight subunits of NF. The correct formation of an axonal network of NF is crucial for the establishment and maintenance of axonal calibre and consequently for the optimisation of conduction velocity. The frequent disorganisation of NF network observed in several neuropathologies support their contribution. However, despite the presence of NF mutations found in some patients, the exact relations between these mutations, the abnormal NF organisation and the pathological process remain a challenging field of investigation.

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“…ACR toxicity results in the accumulation of NFs, swelling of distal axons, increase in tubulovesicular bodies and progressive senorimotor impairment (Prineas, 1969;Spencer and Schaumburg, 1974). However, ACR causes similar behavioral impairment, axonal pathology and transport defects in mice genetically lacking NFs, suggesting that disruption of NFs is not required for ACR-mediated toxicity (Stone et al, 2001). Evidence suggesting that ACR-mediated toxicity acts specifically at the synapse comes from a study which observed terminal degeneration and behavioral deficits in the absence of any degenerative changes in the axon (Lehning et al, 2003).…”

Section: Cmt1mentioning

confidence: 99%