p38 and Chk1 kinases: different conductors for the G(2)/M checkpoint symphony.

The mechanism controlling G(2)/M checkpoint activation after DNA damage was thought to be mediated primarily by nuclear Chk1/Chk2 kinases. Recent evidence indicates that this checkpoint is more complex, involving at least two different biochemical systems that target the Cdc25B and Cdc25C phosphatases. Following genotoxic stress, different kinases integrate signaling from the damaged DNA and other damaged cellular components to regulate Cdc25 inactivation. Our current model for G(2)/M checkpoint activation after genotoxic stress is discussed emphasizing the roles for Chk1 and p38 kinases in checkpoint regulation.     

Role of Gadd45a in Wip1-dependent regulation of intestinal tumorigenesis

Conversion of intestinal stem cells into tumor-initiating cells is an early step in Apc^Min-induced polyposis. Wild-type p53-induced phosphatase 1 (Wip1)-dependent activation of a DNA damage response and p53 has a permanent role in suppression of stem cell conversion, and deletion of Wip1 lowers the tumor burden in Apc^Min mice. Here we show that cyclin-dependent kinase inhibitor 2a, checkpoint kinase 2, and growth arrest and DNA damage gene 45a (Gadd45a) exert critical functions in the tumor-resistant phenotype of Wip1-deficient mice. We further identified Gadd45a as a haploinsufficient gene in the regulation of Wip1-dependent tumor resistance in mice. Gadd45a appears to function through its ability to activate the Jnk-dependent signaling pathway that in turn is a necessary mediator of the proapoptotic functions of p53 that respond to activation of the β-catenin signaling pathway. We propose that silencing of Gadd45a is sufficient to override p53 activation in the presence of active β-catenin under conditions of an enhanced DNA damage response.     

The 5'-deoxyadenylic acid molecule conformational capacity: quantum-mechanical investigation using density functional theory (DFT)

Exhaustive conformational analysis of the 5'-deoxyadenylic acid molecule, has been carried out by the quantum-mechanical density functional theory method at the MP2/6-311++G(d,p)//DFT B3LYP/6-31G(d,p) theory level. As many as 726 of its conformations have been revealed with the relative gas phase Gibbs energies under standard conditions from 0 to 12.1 kcal/mole. It has been shown, that the energetically most favorable conformation has north sugar puckering and synorientation of the nitrogenous base and is stabilized by intramolecular O(p1)H(p1)-N3 and O3'H-O(p) hydrogen bonds. Four conformations have been shown to have their geometry similar to that of AI-DNA and four - of BI-DNA. One conformer of the 5'-deoxyadenylic acid molecule is similar to its sodium salt hexahydrate structure in crystalline state resolved by the X-ray diffraction method and taken from literature. It is shown that effective charges of C4' and C5' atoms are the most sensitive to the molecule conformation ones. The role of the intramolecular OH-N hydrogen bonds in formation of the 5'-deoxyadenylic acid molecule structure has been demonstrated.     

The simplest molecular model of 2'-deoxyribopolinucleotides sugar-phosphate backbone: quantum-chemical adequacy check

The physical adequacy of the simplest molecular model "sugar residue (SR)--phosphate group (PG)--SR" of 2'-deoxyribopolinucleotides sugar-phosphate backbone is confirmed at DFT B3LYP/6-31++G(d,p) and DFT B3LYP/6-31G(d,p) of quantum-chemical methods. It is proved that complicacy of the model to the "SR-PG-SR-PG-SR" and higher levels does not noticeably change the numerical values of torsion angles. Also these angles depend negligibly on counterion nature (e.g. Na+ to Li+, K+ or Cs+ change) and transition from vacuum to continuum approximation with medium dielectrical values of 1.4, 24.9, and 78.4. It is shown that model loses its adequacy when PG is the end link.     

How flexible are DNA constituents? The quantum-mechanical study

Relaxed force constants (RFCs) and vibrational root-mean-square deviations have been evaluated by the original calculation method for conformational parameters of the DNA structural units and their constituents: nucleic acid bases (uracile, thymine, cytosine, adenine and guanine) and their 'building blocks' (benzene, pyrimidine, imidazole and purine molecules), as well as the DNA backbone structural units: tetrahydrofuran, 1,2-dideoxyribose, methanol and orthophosphoric acid. It has been found that the RFCs for nomenclature torsions beta, gamma, epsilon; and sugar pseudorotation angle P in 1,2-dideoxyribose are sensible to the molecule conformation and their values are in the range of 1-25 kcal/(mole·rad2) obeying the inequality K(γ)> K(ε) > K(ρ) > K(β). The RFCs values for endocyclic torsions of nucleic acid bases six-member rings lie within 15-45?kcal/(mole·rad2) in pyrimidines and within 20-60?kcal/(mole·rad2) in purines. It is shown that the quantum zero-point motion effectively neglects the amino group non-planarity in cytosine, adenine and partially in guanine.     

Wip1-dependent regulation of autophagy, obesity, and atherosclerosis

Obesity and atherosclerosis-related diseases account for over one-third of deaths in the western world. Controlling these conditions remains a major challenge due to an incomplete understanding of the molecular pathways involved. Here, we show that Wip1 phosphatase, a known negative regulator of Atm-dependent signaling, plays a major role in controlling fat accumulation and atherosclerosis in mice; specifically, Wip1 deficiency prevents both conditions. In the course of atherosclerosis, deletion of Wip1 results in suppression of macrophage conversion into foam cells, thus preventing the formation of atherosclerotic plaques. This process appears to be independent of p53 but rely on a noncanonical Atm-mTOR signaling pathway and on selective autophagy in regulation of cholesterol efflux. We propose that the Wip1-dependent control of autophagy and cholesterol efflux may provide avenues for treating obesity and atherosclerosis.     

Wip1 phosphatase modulates ATM-dependent signaling pathways

Deletion of Ppm1d, the gene encoding the Wip1 phosphatase, renders cells resistant to transformation and mice resistant to tumor development. Here, we report that deficiency of Wip1 resulted in activation of the ataxia-telangiectasia mutated (ATM) kinase. In turn, overexpression of Wip1 was sufficient to reduce activation of the ATM-dependent signaling cascade after DNA damage. Wip1 dephosphorylated ATM Ser1981, a site critical for ATM monomerization and activation, and was critical for resetting ATM phosphorylation as cells repaired damaged DNA. We propose that the Wip1 phosphatase is an integral component of an ATM-dependent signaling pathway.     

Wip1 phosphatase regulates p53-dependent apoptosis of stem cells and tumorigenesis in the mouse intestine

Colorectal cancer is one of the major causes of cancer-related deaths. To gain further insights into the mechanisms underlying its development, we investigated the role of Wip1 phosphatase, which is highly expressed in intestinal stem cells, in the mouse model of APC(Min)-driven polyposis. We found that Wip1 removal increased the life span of APC(Min) mice through a significant suppression of polyp formation. This protection was dependent on the p53 tumor suppressor, which plays a putative role in the regulation of apoptosis of intestinal stem cells. Activation of apoptosis in stem cells of Wip1-deficient mice, but not wild-type APC(Min) mice, increased when the Wnt pathway was constitutively activated. We propose, therefore, that the Wip1 phosphatase regulates homeostasis of intestinal stem cells. In turn, Wip1 loss suppresses APC(Min)-driven polyposis by lowering the threshold for p53-dependent apoptosis of stem cells, thus preventing their conversion into tumor-initiating stem cells.     

Mice Deficient for the Wild-Type p53-Induced Phosphatase Gene (Wip1) Exhibit Defects in Reproductive Organs, Immune Function, and Cell Cycle Control

The Wip1 gene is a serine/threonine phosphatase that is induced in a p53-dependent manner by DNA-damaging agents. We show here that Wip1 message is expressed in moderate levels in all organs, but is present at very high levels in the testes, particularly in the postmeiotic round spermatid compartment of the seminiferous tubules. We have confirmed that Wip1 mRNA is induced by ionizing radiation in mouse tissues in a p53-dependent manner. To further determine the normal biological function of Wip1 in mammalian organisms, we have generated Wip1-deficient mice. Wip1 null mice are viable but show a variety of postnatal abnormalities, including variable male runting, male reproductive organ atrophy, reduced male fertility, and reduced male longevity. Mice lacking Wip1 show increased susceptibility to pathogens and diminished T- and B-cell function. Fibroblasts derived from Wip1 null embryos have decreased proliferation rates and appear to be compromised in entering mitosis. The data are consistent with an important role for Wip1 in spermatogenesis, lymphoid cell function, and cell cycle regulation.