Unravelling the dissolution mechanism of polyphosphate glasses by 31P NMR spectroscopy: ligand competition and reactivity of intermediate complexes.

Phosphate glass dissolution can be tailored via compositional and subsequent structural changes, which is of interest for biomedical applications such as therapeutic ion delivery. Here, solid-state 31P nuclear magnetic resonance characterisation of 45P2O5-xCaO - (55 -x)Na2O glasses was correlated with dissolution studies using time-dependent liquid 31P NMR spectroscopy and quantitative chemical analysis. Glasses dissolved congruently in aqueous media, and the first dissolution stage was the hydration of phosphate chains. In deionised water and Tris buffer (pH0 7.4 or 7.9), trimetaphosphate rings and orthophosphates were the predominant species in solution, indicating relatively fast degradation. By contrast, long phosphate chains were identified in EDTA (pH0 10.0). Besides pH differences, coordination of phosphate species by metal cations appears to play a catalytic role in the hydrolysis mechanism via turning phosphorus atoms into suitable electrophiles for the subsequent nucleophilic attack by water. Hydrolysis rates were proportional to phosphate complex stability, with stronger complexes for chains than for rings. A competition between solvent and phosphate species for the metal ion occurred in the order EDTA > Tris > deionised water.

Phosphatase-dependent fluctuations in DNA-damage checkpoint activation at partially defective telomeres.

Telomeres protect the ends of eukaryotic chromosomes, and telomere shortening causes irreversible cell-cycle arrest through activation of the DNA-damage checkpoint. In this study, we found that deletion of PPH3, encoding a 2A-like protein phosphatase, accelerated telomere-shortening-mediated senescence without affecting normal telomere length or the telomere erosion rate in Saccharomyces cerevisiae. Moreover, the loss of PPH3 increased sensitivity to telomere dysfunction. The detection of telomere abnormalities by DNA-damage sensors was not an all-or-none response, implying that Pph3 helps determine the border between normal and dysfunctional telomeres by suppressing premature activation of the DNA-damage checkpoint.

TORC1, Tel1/Mec1, and Mpk1 regulate autophagy induction after DNA damage in budding yeast.

Target of rapamycin complex 1 (TORC1) protein kinase responds to various stresses including genotoxic stress. However, its molecular mechanism is poorly understood. Here, we show that DNA damage induces nonselective and selective autophagy in budding yeast. DNA damage caused the attenuation of TORC1 activity, dephosphorylation of Atg13, and autophagy induction. The TORC1-upstream Rag GTPase Gtr1 was not required for TORC1 inactivation and autophagy induction after DNA damage. Furthermore, DNA damage responsive protein kinases Mec1/ATM and Tel1/ATR, and stress-responsive mitogen-activated protein kinase Mpk1/Slt2 were required for the full induction of autophagy. Autophagic proteolysis was required for DNA damage tolerance in TORC1 inactive conditions. This study revealed that multiple protein kinases regulate DNA damage-induced autophagy.

Reversible DNA damage checkpoint activation at the presenescent stage in telomerase-deficient cells of Saccharomyces cerevisiae.

The telomere protects the ends of eukaryotic linear chromosomes, and its shortening or erosion is recognized as DNA damage, leading to loss of proliferation activity and, thus, cellular senescence at the population level. Here, using a GFP-based DNA damage checkpoint marker suited for single-cell observation of Saccharomyces cerevisiae cells, we correlated the checkpoint status of telomere-shortened cells with their behavior. We show that some cells possessing short telomeres retain proliferation capacity even after the DNA damage checkpoint is activated. At the presenescent stage, the activation of the checkpoint causes cell cycle delay, but does not induce permanent cell cycle arrest, eventually leading to the expansion of cell size that is characteristic of cellular senescence. Moreover, the proliferation capacity of checkpoint-activated cells is not dependent on homologous recombination or the checkpoint adaptation pathway. The retention of proliferation capacity is specific to the telomere-derived DNA damage response, suggesting that damaged telomeres differ functionally from other types of DNA damage. Our data establish the role of the presenescent stage in telomere shortening-induced senescence, which proceeds gradually and is associated with a variety of changes, including altered cell morphology and metabolism.