In ageing, the accumulation of damaged molecules provoked by oxidative stress and inflammation contributes to altered gene expressions and cellular dysfunction. The antioxidant system is crucial in order to prevent damage to intracellular molecules including DNA and, consequently, to avoid cellular dysfunction or neoplastic transformation. However, during serious DNA damage, the cells can activate a response characterized by cell cycle arrest and production of factors (mainly chemokines and cytokines) named "senescent associated secretory phenotype" (SASP) with the putative function to attract immune cells involved in the clearance of the senescent cells. This phenomenon named "cellular senescence" is, by one side, an important tumor suppressive mechanism but, on the other side, it contributes to impair tissue regenerative capacity and to possible transformation of neighbouring cells to cancer cells if a rapid clearance of the senescent cell doesn't occur. Therefore, preventing DNA damage via an optimal intracellular antioxidant defence is the key to reduce risk of cancer while keeping senescent changes at minimum. Zinc-bound Metallothioneins (MT), could play a key role in this prevention because they are antioxidant proteins and release zinc ions for several proteins and enzymes involved in antioxidant and DNA-repair responses. Reduced MT expression and intracellular zinc occur in some models of senescent cells. This process is of relevance since zinc ions released from MT could be implicated in the modulation of SASP. In chronic inflammation, such as in ageing, the dysfunction in zinc release from MT occurs, suggesting a potential contribution to the onset of senescent cells. Hence, MT could be directly or indirectly involved in the modulation of cellular senescent state and might represent a possible therapeutic target against the accumulation of dysfunctional senescent cells. © 2013 Bentham Science Publishers.
Metallothioneins, ageing and cellular senescence: A future therapeutic target / Mocchegiani, E.; Costarelli, L.; Basso, A.; Giacconi, R.; Piacenza, F.; Malavolta, M.. - In: CURRENT PHARMACEUTICAL DESIGN. - ISSN 1381-6128. - 19:9(2013), pp. 1753-1764. [10.2174/138161213805219595]
Metallothioneins, ageing and cellular senescence: A future therapeutic target
Malavolta M.Ultimo
Conceptualization
2013-01-01
Abstract
In ageing, the accumulation of damaged molecules provoked by oxidative stress and inflammation contributes to altered gene expressions and cellular dysfunction. The antioxidant system is crucial in order to prevent damage to intracellular molecules including DNA and, consequently, to avoid cellular dysfunction or neoplastic transformation. However, during serious DNA damage, the cells can activate a response characterized by cell cycle arrest and production of factors (mainly chemokines and cytokines) named "senescent associated secretory phenotype" (SASP) with the putative function to attract immune cells involved in the clearance of the senescent cells. This phenomenon named "cellular senescence" is, by one side, an important tumor suppressive mechanism but, on the other side, it contributes to impair tissue regenerative capacity and to possible transformation of neighbouring cells to cancer cells if a rapid clearance of the senescent cell doesn't occur. Therefore, preventing DNA damage via an optimal intracellular antioxidant defence is the key to reduce risk of cancer while keeping senescent changes at minimum. Zinc-bound Metallothioneins (MT), could play a key role in this prevention because they are antioxidant proteins and release zinc ions for several proteins and enzymes involved in antioxidant and DNA-repair responses. Reduced MT expression and intracellular zinc occur in some models of senescent cells. This process is of relevance since zinc ions released from MT could be implicated in the modulation of SASP. In chronic inflammation, such as in ageing, the dysfunction in zinc release from MT occurs, suggesting a potential contribution to the onset of senescent cells. Hence, MT could be directly or indirectly involved in the modulation of cellular senescent state and might represent a possible therapeutic target against the accumulation of dysfunctional senescent cells. © 2013 Bentham Science Publishers.I documenti in IRIS sono protetti da copyright e tutti i diritti sono riservati, salvo diversa indicazione.