The Modifications of Longevity Regulating Pathway Resulting from Endurance Effort in Arabian Horses
By:
References
- Baghaiee B., Botelho Teixeira A.M., Tartibian B. (2016). Moderate aerobic exercise increases SOD-2 gene expression and decreases leptin and malondialdehyde in middle-aged men. Sci. Sports, 31.
- Bartlett J.D., Close G.L., Drust B., Morton J.P. (2014). The emerging role of p53 in exercise metabolism. Sports Med. Mar., 44: 303–309.
- Benjamini Y., Hochberg Y. (2000). On the adaptive control of the false discovery rate in multiple testing with independent statistics. J. Educ. Behav. Stat., 25: 60–83.
- Bollinger L., Bartel A., Weber C., Gehlen C. (2023). Pre-ride biomarkers and endurance horse welfare: analyzing the impact of the elimination of superoxide dismutase, δ-aminolevulinic-dehydratase, thiobarbituric acid reactive substances, iron, and serum amyloid A levels in elite 160 km endurance rides. Animals, 13: 1670–1680. Carapeto P.V., Aguayo-Mazzucato C. (2021). Effects of exercise on cellular and tissue aging. Aging (Albany NY), 13: 14522–14543.
- Carosi J.M., Fourrier C., Bensalem J., Sargeant T.J. (2022). The mTOR–lysosome axis at the centre of ageing. FEBS Open Biol., 12: 739–757.
- Coqueiro R.D.S., Soares T.J., Pereira R., Correia T.M.L., Coqueiro D.S.O., Oliveira M.V., Marques L.M., de Sá C.K.C., de Magalhães A.C.M. (2019). Therapeutic and preventive effects of exercise on cardiometabolic parameters in aging and obese rats. Clin Nutr ESPEN, 29: 203–212.
- Dashtiyan A.A., Sepehrimanesh M., Tanideh N., Esmaeil Afzalpour M. (2017). The effect of endurance training with and without vita-min E on expression of p53 and PTEN tumor suppressing genes in prostate glands of male rats. Biochimie Open, 4: 112–118.
- Du S., Zheng H. (2021). Role of FoxO transcription factors in aging and age-related metabolic and neurodegenerative diseases. Cell Biosci., 11.
- Figueiredo V.C., Roberts L.A., Markworth J.F., Barnett M.P., Coombes J.S., Raastad T., Cameron-Smith D. (2016). Impact of resistance exercise on ribosome biogenesis is acutely regulated by post-exercise recovery strategies. Physiol. Rep., 4.
- Ghosh S., Sinha J.K., Raghunath M. (2016). Epigenomic maintenance through dietary intervention can facilitate DNA repair process to slow down the progress of premature aging. IUBMB Life, 68: 717–721.
- Hanyuda A., Kim S.A., Martinez-Fernandez A., Qian Z.R., Yamauchi M., Nishihara R., Morikawa T., Liao X., Inamura K., Mima K., Cao Y., Zhang X., Wu K., Chan A.T., Giovannucci E.L., Meyerhardt J.A., Fuchs C.S., Shivdasani R.A., Ogino S. (2016). Survival benefit of exercise differs by tumor IRS1 expression status in colorectal cancer. Ann. Surg. Oncol., 3: 908–917.
- Kim J.H., Hwang K.H., Park K.S., Kong I.D., Cha S.K. (2015). Biological role of anti-aging protein klotho. J. Lifestyle Med. Mar., 5: 1–6.
- Krause C., Geißler C., Tackenberg. H., El Gammal A.T., Wolter S., Spranger J., Mann O., Lehnert H., Kirchner H. (2020). Multi-layered epigenetic regulation of IRS2 expression in the liver of obese individuals with type 2 diabetes. Diabetologia, 10: 2182–2193.
- Laker R.C., Drake J.C., Wilson R.J. (2017). Ampk phosphorylation of Ulk1 is required for targeting of mitochondria to lysosomes in exercise-induced mitophagy. Nat. Commun., 8: 548.
- Lenhare L., Crisol B.M., Silva V.R.R., Katashima C.K., Cordeiro A.V., Pereira K.D., Luchessi A.D., da Silva A.S.R., Cintra D.E., Moura
- L.P., Pauli J.R., Ropelle E.R. (2017). Physical exercise increases Sestrin 2 protein levels and induces autophagy in the skeletal muscle of old mice. Exp. Gerontol., 97: 17–21.
- Li L., Hao Z., Beibei Ch., Bingke Xi., Ruyuan Z., Yage L., Xuan D., Zimengwei Y., Dandan Z., Fangfang M., Sihua G., Orekhov A.N., Prentki M., Lili W., Shuzhen G., Dongwei Z. (2022). BaZiBuS-hen alleviates cognitive deficits and regulates Sirt6/NRF2/HO-1 and Sirt6/P53-PGC-1α-TERT signaling pathways in aging mice. J. Ethnopharmacol., 282: 114653.
- Liu G., Detloff M.R., Miller K.N., Santi L., Houlé J.D. (2011). Exercise modulates microRNAs that affect the PTEN/mTOR pathway in rats after spinal cord injury. Exp. Neurol. Jan., 233: 447–456.
- Liu H., Fergusson M.M., Castilho R.M., Liu J., Cao L., Chen J., (2007). Augmented Wnt signaling in a mammalian model of accelerated aging. Science, 317: 803–806.
- Mihaylova M., Shaw R. (2011). The AMPK signalling pathway coordinates cell growth, autophagy and metabolism. Nat. Cell Biol., 13: 1016–1023.
- Minig V., Kattan Z., Beeumen J., Brunner E., Becuwe P. (2009). Identification of DDB2 protein as a transcriptional regulator of constitutive SOD2 gene expression in human breast cancer cells, J. Biol. Chem., 12.
- Myćka G., Ropka-Molik K., Cywinska A., Szmatoła T., Stefaniuk-Szmukier M. (2023). Molecular insights into the lipid-carbohydrates metabolism switch under the endurance effort in Arabian horses. Equine Vet. J., 56.
- Ogino T., Matsunaga N., Tanaka T., Tanihara T., Terajima H., Yoshitane H., Fukada Y., Tsuruta A., Koyanagi S., Ohdo S. (2021). Post-transcriptional repression of circadian component CLOCK regulates cancer-stemness in murine breast cancer cells. Elife, 10.
- Phelps M., Pettan-Brewer C., Ladiges W., Yablonka-Reuveni Z. (2013). Decline in muscle strength and running endurance in Klotho deficient C57BL/6 mice. Biogerontology, 14: 729–739.
- Ren H., Chen Y., Zhu Z., Xia J., Liu S., Hu Y., Qin X., Zhang L., Ding Y., Xia S., Wang J. (2023). FOXO1 regulates Th17 cell-mediated hepatocellular carcinoma recurrence after hepatic ischemia-reper-fusion injury. Cell Death Dis., 14: 367.
- Ropka-Molik K., Stefaniuk-Szmukier M., Musiał A.D., Velie B.D. (2019). The genetics of racing performance in Arabian horses. Int. J. Genom., 2019: 9013239.
- Saleem A., Hood D.A. (2013). Acute exercise induces tumour suppressor protein p53 translocation to the mitochondria and promotes a p53-Tfam-mitochondrial DNA complex in skeletal muscle. J. Physiol., 591: 3625–3636.
- Sánchez-Álvarez M., Strippoli R., Donadelli M., Bazhin A.V., Cordani M. (2019). Sestrins as a therapeutic bridge between ROS and autophagy in cancer. Cancers (Basel), 11: 1415.
- Taormina G., Ferrante F., Vieni S., Grassi N., Russo A., Mirisola M.G. (2019). Longevity: lesson from model organisms. Genes, 10.
- Tyshkovskiy A., Ma S., Shindyapina A.V., Tikhonov S., Lee S.G., Bozaykut P., Castro J.P., Seluanov A., Schork N.J., Gorbunova V., Dmitriev S.E., Miller R.A., Gladyshev V.N. (2023). Distinct longevity mechanisms across and within species and their association with aging. Cell, 186.
- Wang F., Wang X., Liu Y., Zhang Z. (2021). Effects of exercise-induced ROS on the pathophysiological functions of skeletal muscle. Oxid. Med. Cell Longev., 2021: 3846122.
- Wang P.Y., Zhuang J., Hwang P.M. (2012). p53: exercise capacity and metabolism. Curr. Opin. Oncol., 24: 76–82.
- Webb A.E., Brunet A. (2014). FOXO transcription factors: key regulators of cellular quality control. Trends Biochem. Sci., 39: 159–169.
- Wehling-Henricks M., Li Z., Lindsey C., Wang Y., Welc S.S., Ramos J.N., Khanlou N., Kuro O.M., Tidball J.G. (2016). Klotho gene silencing promotes pathology in the mdx mouse model of Duchenne muscular dystrophy. Hum. Mol. Genet., 25.
- Xu H., Lu X., Wang C., Ning J., Chen M., Wang Y., Yuan K. (2022). Potential roles of PTEN on longevity in two closely related argopecten scallops with distinct lifespans. Front. Physiol., 13: 872562.
- Xu L., Liu Z., Wang H., Lu J., Xu J., Meng Y., Huang K., Liu B. (2023). SESN2 could be a potential marker for diagnosis and prognosis in glioma. Genes, 14.
- Yu Ch., Zhang P., Liu S. Niu Y., Fu L. (2023). SESN2 ablation weakens exercise benefits on resilience of gut microbiota following high-fat diet consumption in mice, Food Sci. Hum. Well., 12: 1961–1968.
Language: English
Page range: 1161 - 1170
Submitted on: Nov 28, 2023
Accepted on: Feb 19, 2024
Published on: Oct 24, 2024
Published by: National Research Institute of Animal Production
In partnership with: Paradigm Publishing Services
Publication frequency: 4 times per year
Keywords:
Related subjects:
© 2024 Grzegorz Myćka, Katarzyna Ropka-Molik, Anna Cywińska, Tomasz Szmatoła, Monika Stefaniuk-Szmukier, published by National Research Institute of Animal Production
This work is licensed under the Creative Commons Attribution 4.0 License.