Results 21 to 30 of about 104,202 (300)

Aerobic glycolysis and lymphocyte transformation [PDF]

Biochemical Journal, 1978
1. The role of enhanced aerobic glycolysis in the transformation of rat thymocytes by concanavalin A has been investigated. Concanavalin A addition doubled [U-14C]glucose uptake by rat thymocytes over 3h and caused an equivalent increased incorporation into protein, lipids and RNA. A disproportionately large percentage of the extra glucose taken up was
Hume, David A., Radik, Judith L., Ferber, Ernst, Weidemann, Maurice J.   +3 more
openaire   +3 more sources

NOX4-derived ROS-induced overexpression of FOXM1 regulates aerobic glycolysis in glioblastoma

BMC Cancer, 2021
Background Increased expression of the transcription factor Forkhead box M1 (FOXM1) has been reported to play an important role in the progression and development of multiple tumors, but the molecular mechanisms that regulate FOXM1 expression remain ...
Xiangsheng Su, Yihang Yang, Qing Yang, Bo Pang, Shicheng Sun, Yanjun Wang, Qiujiang Qiao, Changfa Guo, Huanting Liu, Qi Pang   +9 more
doaj   +1 more source

HES1 promotes aerobic glycolysis and cancer progression of colorectal cancer via IGF2BP2-mediated GLUT1 m6A modification

Cell Death Discovery, 2023
Aerobic glycolysis has been shown to play a key role in tumor cell proliferation and metastasis. However, how it is directly regulated is largely unknown.
Jiayu Wang, Mengxin Zhu, Jinghan Zhu, Juntao Li, Xingchao Zhu, Kun Wang, Kanger Shen, Kexi Yang, Xiangyu Ni, Xin Liu, Guangbo Zhang, Qinhua Xi, Tongguo Shi, Weichang Chen   +13 more
doaj   +1 more source

Aerobic Glycolysis Is Essential for Normal Rod Function and Controls Secondary Cone Death in Retinitis Pigmentosa

Cell Reports, 2018
Aerobic glycolysis accounts for ∼80%–90% of glucose used by adult photoreceptors (PRs); yet, the importance of aerobic glycolysis for PR function or survival remains unclear.
Lolita Petit, Shan Ma, Joris Cipi, Shun-Yun Cheng, Marina Zieger, Nissim Hay, Claudio Punzo   +6 more
doaj   +1 more source

Development of an Aerobic Glycolysis Index for Predicting the Sorafenib Sensitivity and Prognosis of Hepatocellular Carcinoma

Frontiers in Oncology, 2021
Hepatocellular carcinoma (HCC) is a deadly tumor with high heterogeneity. Aerobic glycolysis is a common indicator of tumor growth and plays a key role in tumorigenesis.
Yu Pan, Yu Pan, Yu Pan, Yu Pan, Yu Pan, Yu Pan, Geng-yuan Hu, Geng-yuan Hu, Geng-yuan Hu, Shi Jiang, Shi Jiang, Shi Jiang, Shi Jiang, Shi Jiang, Shi Jiang, Shun-jie Xia, Shun-jie Xia, Shun-jie Xia, Shun-jie Xia, Shun-jie Xia, Shun-jie Xia, Hendi Maher, Hendi Maher, Hendi Maher, Hendi Maher, Hendi Maher, Hendi Maher, Zhong-jie Lin, Zhong-jie Lin, Zhong-jie Lin, Zhong-jie Lin, Zhong-jie Lin, Zhong-jie Lin, Qi-jiang Mao, Qi-jiang Mao, Qi-jiang Mao, Qi-jiang Mao, Qi-jiang Mao, Qi-jiang Mao, Jie Zhao, Jie Zhao, Jie Zhao, Jie Zhao, Jie Zhao, Liu-xin Cai, Liu-xin Cai, Liu-xin Cai, Liu-xin Cai, Liu-xin Cai, Ying-hua Xu, Jun-jie Xu, Jun-jie Xu, Jun-jie Xu, Jun-jie Xu, Jun-jie Xu, Xiu-jun Cai, Xiu-jun Cai, Xiu-jun Cai, Xiu-jun Cai, Xiu-jun Cai   +59 more
doaj   +1 more source

Explicit consideration of topological and parameter uncertainty gives new insights into a well-established model of glycolysis [PDF]

, 2013
Previous models of glycolysis in the sleeping sickness parasite Trypanosoma brucei assumed that the core part of glycolysis in this unicellular parasite is tightly compartimentalized within an organelle, the glycosome, which had previously been shown to ...
Achcar, Albert, Bakker, Bakker, Bakker, Bakker, Blattner, Chevalier, Clarkson, Clarkson, Cronín, Fairlamb, Fairlamb, Gualdron-López, Gualdrón-López, Guerra-Giraldez, Haanstra, Haanstra, Hammond, Helfert, Häusler, Michels, Miškovíc, Murabito, Opperdoes, Rizk, Satish Kumar, Steiger, Tran, Visser, Wang   +30 more
core   +1 more source

Cardiosphere-derived cells demonstrate metabolic flexibility that Is influenced by adhesion status [PDF]

, 2017
Adult stem cells demonstrate metabolic flexibility that is regulated by cell adhesion status. The authors demonstrate that adherent cells primarily utilize glycolysis, whereas suspended cells rely on oxidative phosphorylation for their ATP needs.
Abraham, M. Roselle, Afzal, Junaid, Aon, Miguel A, Chan, Angel, Foster, D. Brian, Guan, Yufan, Karakas, Mehmet Fatih, O\u27Rourke, Brian, Pomper, Martin, Rathmell, Jeffrey, Tsui, Benjamin, Vakrou, Styliani, Wahl, Richard, Woldemichael, Kirubel   +13 more
core   +2 more sources

Quercetin Antagonizes Glucose Fluctuation Induced Renal Injury by Inhibiting Aerobic Glycolysis via HIF-1α/miR-210/ISCU/FeS Pathway

Frontiers in Medicine, 2021
Background and Objective: Glucose fluctuation (GF) has been reported to induce renal injury and diabetic nephropathy (DN). However, the mechanism still remains ambiguous.
Wei-long Xu, Su Liu, Nan Li, Li-fang Ye, Min Zha, Chang-yin Li, Yue Zhao, Qiang Pu, Jin-jing Bao, Xing-jie Chen, Jiang-yi Yu, Ying-hao Pei   +11 more
doaj   +1 more source

Metabolism within the tumor microenvironment and its implication on cancer progression: an ongoing therapeutic target [PDF]

, 2018
Since reprogramming energy metabolism is considered a new hallmark of cancer, tumor metabolism is again in the spotlight of cancer research. Many studies have been carried out and many possible therapies have been developed in the last years.
Abdel-Aziz, Ahmadzadeh, Al-Zhoughbi, Albina, Alkan, Allard, Allen, Altman, Alves-Filho, Amelio, Araújo, Argilés, Arora, Arts, Aslanian, Astaldi, Attieh, Augsten, Auvinen, Babbar, Baker, Balasubramanian, Baltazar, Bauer, Bello-Fernandez, Beloribi-Djefaflia, Berchner-Pfannschmidt, Berge, Berrone, Birendra, Bloch-Frankenthal, Bock, Bock, Bonuccelli, Boros, Boudreau, Boukalova, Britten, Brooks, Broome, Bueno, Buqué, Burnet, Cadamuro, Cahlin, Cantelmo, Cao, Carito, Carmeliet, Carmeliet, Caro, Carrascosa, Casazza, Caspani, Catane, Cavalcante, Chakravarty, Chakravarty, Chakravarty, Chang, Chang, Chang, Chappell, Chaudhary, Chen, Chen, Chen, Chiarini, Chittezhath, Choi, Choi, Clark, Clem, Clem, Cohen, Colegio, Collins, Commisso, Covarrubias, Covarrubias, Dang, Dang, Das, Dasgupta, Daurkin, DeBerardinis, DeBerardinis, Delgoffe, Delgoffe, Dell’ Antone, Desai, DiNapoli, Dirat, Dobrina, Doherty, Dong, Draoui, Dufour, Eason, Eelen, El Sayed, Elia, Elwood, Eminel, Fallarino, Farabegoli, Farber, Feun, Fields, Figueras, Filipp, Fischer, Flaig, Flint, Floor, Floridi, Folkman, Folkman, Franklin, Gacche, Ganeshan, Garber, García-Caballero, García-Faroldi, García-Faroldi, Gatenby, Gazi, Geiger, Gentric, Gerner, Gershtein, Ghashghaeinia, Gonen, Goveia, Granchi, Grieninger, Grivennikov, Gross, Gunnink, Guo, Guo, Guppy, Guth, Halestrap, Han, Hanahan, Hanahan, Hanai, Harjes, Harjes, Haskell, Hatzivassiliou, Hayakawa, Hessini, Hitosugi, Ho, Ho, Hoff, Holm, Hosono, Huang, Hubler, Hui, Häusler, Hée, Ignatenko, Ioannesyants, Ip, Jiménez-Valerio, Jiménez-Valerio, Jochems, Johansen, Jones, Kabat, Kafkewitz, Kamphorst, Kamphorst, Kamphorst, Kannan, Karpel-Massler, Katt, Kawasaki, Kelly, Kim, Klimp, Ko, Koliaraki, Kouidhi, Koukourakis, Kridel, Krishna, Kroemer, Krützfeldt, Kubatka, Kucharzewska, la Cueva, Labow, Laing, Lampropoulou, Le, Lechowski, Lee, Lee, Leek, Leighton, Leopold, LePage, Lerma Barbaro, Li, Lin, Liu, Liu, Liu, Liu, Liu, Liu, Liu, Lopes-Coelho, Lu, Lucca, Lukey, Lunt, Luo, López-Lázaro, Löb, Ma, Madaan, Maity, Marchiq, Martinez-Outschoorn, Martinez-Outschoorn, Maráz, Mashima, Masri, Matusewicz, McCann, McKee, McLaughlin, Medina, Medina, Merchan, Meyer, Mider, Missiaen, Mitra, Mockler, Moreno-Sánchez, Morrison, Mu, Murray-Stewart, Márquez, Márquez, Nacev, Nancolas, Newsholme, Nieman, Nisoli, Noman, Norrby, Noy, Nurjhan, Nyberg, Ocaña, Ohmura, Oka, Opitz, Orimo, Pallangyo, Palm, Panda, Papandreou, Parra-Bonilla, Parry, Pascual, Pasquier, Patsoukis, Pavlides, Pavlova, Pelicano, Pellerin, Pennisi, Penny, Peters, Pisarsky, Pizer, Polanski, Polet, Pollard, Polyak, Possemato, Potente, Potente, Prager, Prager, Pushkina, Pérez-Escuredo, Quatromoni, Quesada, Quesada, Rabold, Ramjiawan, Rashid, Rattigan, Reihill, Reitzer, Ribatti, Ribatti, Ribeiro, Richard, Rider, Roberts, Rodríguez-González, Rodríguez-Prados, Rohle, Romero, Romero-García, Roy, Roy, Ruan, Ruiz-Pérez, Russell, Ryu, Saez, Salimian Rizi, Salimian Rizi, Samal, Samudio, Santos, Sanuphan, Sasaki, Saulnier Sholler, Scherz-Shouval, Schoors, Schulze, Segura, Sekar, Selak, Seltzer, Serafini, Shapot, Shapot, Shapot, Sharkia, Shime, Shin, Shurbaji, Sieber, Siu, Skelton, Song, Sonveaux, Sonveaux, Souba, Sousa, Spahr, Spinelli, Spolarics, Stacpoole, Stern, Stuart, Stumvoll, Su, Sukumar, Sánchez-López, Tachibana, Takigawa, Talekar, Tanese, Tang, Tannahill, Tebbe, Thomas, Thomas, Thornburg, Tisdale, Torosian, Torres, Trudeau, Ullah, Uray, Urdiales, Vander Heiden, Vander Heiden, Varricchi, Vasudevan, Velaei, Vera, Vornovitskaya, Végran, Wagner, Wakil, Wang, Wang, Wang, Wang, Warburg, Warburg, Wen, Whitaker-Menezes, Williams-Ashman, Wilson, Wood, Woodward, Woster, Wu, Wu, Xie, Yamanishi, Yang, Yang, Yau, Yen, Yoshida, Yoshizaki, Yu, Yuan, Yuan, Yuan, Yun, Zabala-Letona, Zahalka, Zhan, Zhang, Zhang, Zhang, Zhang, Zhang, Zhao, Zheng, Zhou, Zhu, Ziegler   +431 more
core   +2 more sources

Advances in the study of aerobic glycolytic effects in resistance to radiotherapy in malignant tumors [PDF]

PeerJ, 2023
Aerobic glycolysis is a metabolic mode of tumor cells different from normal cells that plays an important role in tumor proliferation and distant metastasis.
Yuyi Liu, Zhengfu Feng, Pingmei Zhang, Honghao Chen, Song Zhu, Xin Wang   +5 more
doaj   +2 more sources