The diverse functions of GAPDH: Views from different subcellular compartments

Tristan, Carlos A.; Shahani, Neelam; Sedlak, Thomas W.; Sawa, Akira

doi:10.1016/j.cellsig.2010.08.003

Cited by 540 publications

(486 citation statements)

References 86 publications

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“…[38][39][40][41][42]70,[85][86][87] In the following we discuss three topics: (a) the use of sucrose gradient fractionation in MS-based proteomics to obtain data about subcellular spatial distribution of proteins, (b) how the observed distributions might be related to MCF7 cells as cancer cells, and (c) the implications of our results for how such spatial distributions may relate to overall control of cellular function.…”

Section: Discussionmentioning

confidence: 99%

“…103,104 Furthermore, the spatial/functional dispersion of proteins can be connected to a plethora of different post-translational modifications, as exemplified by the wide-ranging, different functionalities of GAPDH. 85,86 Complementation of full-proteome scans using bottom-up proteomics with top-down proteomics methods that could rapidly and routinely fully characterize the transcriptional and post-translational features of a few tens of selected proteins seems to be a remaining task for proteomics. It would be desirable that conventional biological experiments, are routinely accompanied by verification by MSbased proteomics of the exact structures for the crucial proteins.…”

Section: The Influence Of Subcellular Protein Distributions On Cellulmentioning

confidence: 99%

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Spatial Distribution of Cellular Function: The Partitioning of Proteins between Mitochondria and the Nucleus in MCF7 Breast Cancer Cells

et al. 2012

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Section: Discussionmentioning

confidence: 99%

Section: The Influence Of Subcellular Protein Distributions On Cellulmentioning

confidence: 99%

Spatial Distribution of Cellular Function: The Partitioning of Proteins between Mitochondria and the Nucleus in MCF7 Breast Cancer Cells

et al. 2012

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“…Au tophagy is in di rectly mod u lated by meta bolic en zymes. Glyc er alde hyde 3 phos phate de hy dro ge nase (GAPDH) is in volved in mul ti ple cel lu lar processes based mainly on its sub cel lu lar lo cal iza tion [144]. Dur ing glu cose de pri va tion, GAPDH is phos pho ry lated by AMPK and is translo cated to the cell nu cleus where it in ter acts with NAD de pen dent deacety lase sir tuin 1 (Sirt1).…”

Section: Metabolic Regulation Of Cancer Cell Deathmentioning

confidence: 99%

Cancer metabolism in space and time: Beyond the Warburg effect

Danhier

Bański

Payen

et al. 2017

Biochimica et Biophysica Acta (BBA) - Bioenergetics

162

139

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Available online xxx Keywords:Can cer Me tab o lism Mi to chon dria Het ero gene ity Metas ta sis A B S T R A C T Al tered me tab o lism in can cer cells is piv otal for tu mor growth, most no tably by pro vid ing en ergy, re duc ing equiv a lents and build ing blocks while sev eral metabo lites ex ert a sig nal ing func tion pro mot ing tu mor growth and pro gres sion. A can cer tis sue can not be sim ply re duced to a bulk of pro lif er at ing cells. Tu mors are in deed com plex and dy namic struc tures where sin gle cells can het ero ge neously per form var i ous bi o log i cal ac tiv i ties with dif fer ent meta bolic re quire ments. Be cause tu mors are com posed of dif fer ent types of cells with meta bolic ac tiv i ties af fected by dif fer ent spa tial and tem po ral con texts, it is im por tant to ad dress me tab o lism tak ing into ac count cel lu lar and bi o log i cal het ero gene ity. In this re view, we de scribe this het ero gene ity also in meta bolic fluxes, thus show ing the rel a tive con tri bu tion of dif fer ent meta bolic ac tiv i ties to tu mor pro gres sion ac cord ing to the cel lu lar con text. This ar ti cle is part of a Spe cial Is sue en ti tled Res pi ra tory com plex I, edited by Giuseppe Gas parre, Ro drigue Rossig nol and Pierre Son veaux. Abbreviations: ACL, ATP cit rate lyase; AMPK, adeno sine monophos phate ki nase; ARG1, L argi nine me tab o liz ing en zyme arginase 1; BCAA, branched chain amino acid; Bcl2, B cell lym phoma 2; CAF, can cer as so ci ated fi brob last; CIC, can cer ini ti at ing cell; COX2, cy tochrome ox i dase; CSC, can cer stem cell; CREB, cyclic adeno sine monophos phate re sponse el e ment bind ing pro tein; DEC1, dif fer en tially ex pressed in chon dro cytes 1; EMT, ep ithe lial to mes enchy mal tran si tion; FAK, fo cal ad he sion ki nase; FAS, fatty acid syn thase; FBP, fruc tose 1,6 bis pho s phate; FDG PET, [ F] flu o rodeoxyglu cose positron emis sion to mog ra phy; GAPDH, glyc er alde hyde 3 phos phate de hy dro ge nase; HIF 1, hy poxia ac ti vated fac tor 1; HK2, hex ok i nase 2; HMGB1, high mo bil ity group box 1; HU VEC, hu man um bil i cal vein en dothe lial cell; IFN γ, in ter feron gamma; LDH, lac tate de hy dro ge nase; MEF, murine em bry onic fi brob last; MET, mes enchy mal to ep ithe lial tran si tion; MRI, mag netic res o nance imag ing; mTORC1, mam malian tar get of ra pamycin com plex 1; NSCLC, non small cell lung can cer; OX PHOS, ox ida tive phos pho ry la tion; PDAC, pan cre atic duc tal ade no car ci noma; PHD, pro lyl hy drox y lase; pHe, ex tra cel lu lar pH; pHi, in tra cel lu lar pH; PK, pyru vate ki nase; PPP, pen tose phos phate path way; REDD1, reg u lated in de vel op ment and DNA dam age re sponse 1; RhoA, Ras ho molog gene fam ily, mem ber A; ROS, re ac tive oxy gen species; SASP, senes cence as so ci ated se cre tory phe no type; SCO2, syn the sis of cy tochrome ox i dase 2; SGK 1, serum and glu co cor ti coid reg u lated ki nase 1 Sirt1, sir tuin 1; TAM, tu mor as so ci ated macrophage; TIGAR, TP53 in duced gly col y ...

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“…However, a pea (Pisum sativum) chloroplast GAPDH isoform has been shown to have uracil DNA glycosylase activity (Wang et al, 1999), and in mammals, GAPDH was shown to fulfill additional nonmetabolic functions, including posttranscriptional regulation, maintenance of DNA integrity, and apoptosis (Sirover, 2011;Tristan et al, 2011). In rat cells, stress conditions may cause nitrosylation of GAPDH catalytic Cys and interaction with Seven in absentia homolog1 (Siah1; an E3 ubiquitin ligase), whose nuclear localization signal drives the GAPDH-Siah1 complex into the nucleus, where the ubiquitinating activity of Siah1 promotes apoptosis (Hara et al, 2005).…”

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confidence: 99%

Nuclear Accumulation of Cytosolic Glyceraldehyde-3-Phosphate Dehydrogenase in Cadmium-Stressed Arabidopsis Roots

et al. 2013

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NAD-dependent glyceraldehyde-3-phosphate dehydrogenase (GAPDH) is a ubiquitous enzyme involved in the glycolytic pathway. It has been widely demonstrated that mammalian GAPDH, in addition to its role in glycolysis, fulfills alternative functions mainly linked to its susceptibility to oxidative posttranslational modifications. Here, we investigated the responses of Arabidopsis (Arabidopsis thaliana) cytosolic GAPDH isoenzymes GAPC1 and GAPC2 to cadmium-induced stress in seedlings roots. GAPC1 was more responsive to cadmium than GAPC2 at the transcriptional level. In vivo, cadmium treatments induced different concomitant effects, including (1) nitric oxide accumulation, (2) cytosolic oxidation (e.g. oxidation of the redox-sensitive Green fluorescent protein2 probe), (3) activation of the GAPC1 promoter, (4) GAPC1 protein accumulation in enzymatically inactive form, and (5) strong relocalization of GAPC1 to the nucleus. All these effects were detected in the same zone of the root tip. In vitro, GAPC1 was inactivated by either nitric oxide donors or hydrogen peroxide, but no inhibition was directly provided by cadmium. Interestingly, nuclear relocalization of GAPC1 under cadmium-induced oxidative stress was stimulated, rather than inhibited, by mutating into serine the catalytic cysteine of GAPC1 (C155S), excluding an essential role of GAPC1 nitrosylation in the mechanism of nuclear relocalization, as found in mammalian cells. Although the function of GAPC1 in the nucleus is unknown, our results suggest that glycolytic GAPC1, through its high sensitivity to the cellular redox state, may play a role in oxidative stress signaling or protection in plants.

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The diverse functions of GAPDH: Views from different subcellular compartments

Cited by 540 publications

References 86 publications

Spatial Distribution of Cellular Function: The Partitioning of Proteins between Mitochondria and the Nucleus in MCF7 Breast Cancer Cells

Spatial Distribution of Cellular Function: The Partitioning of Proteins between Mitochondria and the Nucleus in MCF7 Breast Cancer Cells

Cancer metabolism in space and time: Beyond the Warburg effect

Nuclear Accumulation of Cytosolic Glyceraldehyde-3-Phosphate Dehydrogenase in Cadmium-Stressed Arabidopsis Roots

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