Versatility of thermoluminescence materials and radiation dosimetry – A review

Thermoluminescence (TL) materials exhibit a wide range of applications in different areas such as personal dosimetry, environmental dosimetry, medical research etc. Doping of different rare earth impurities in different hosts is responsible for changing the properties of materials useful for various applications in different fields. These materials can be irradiated by different types of beams such as γ‐rays, X‐rays, electrons, neutrons etc. Various radiation regimes, as well as their dose–response range, play an important role in thermoluminescence dosimetry. Several TL materials, such as glass, microcrystalline, nanostructured inorganic materials and recently developed materials, are reviewed and described in this article.     

The role of yeast DNA 3'-phosphatase Tpp1 and rad1/Rad10 endonuclease in processing spontaneous and induced base lesions

Tpp1 is a DNA 3'-phosphatase in Saccharomyces cerevisiae that is believed to act during strand break repair. It is homologous to one domain of mammalian polynucleotide kinase/3'-phosphatase. Unlike in yeast, we found that Tpp1 could confer resistance to methylmethane sulfonate when expressed in bacteria that lack abasic endonuclease/3'-phosphodiesterase function. This species difference was due to the absence of delta-lyase activity in S. cerevisiae, since expression of bacterial Fpg conferred Tpp1-dependent resistance to methylmethane sulfonate in yeast lacking the abasic endonucleases Apn1 and Apn2. In contrast, beta-only lyases increased methylmethane sulfonate sensitivity independently of Tpp1, which was explained by the inability of Tpp1 to cleave 3' alpha,beta-unsaturated aldehydes. In parallel experiments, mutations of TPP1 and RAD1, encoding part of the Rad1/Rad10 3'-flap endonuclease, caused synthetic growth defects in yeast strains lacking Apn1. In contrast, Fpg expression led to a partial rescue of apn1 apn2 rad1 synthetic lethality by converting lesions into Tpp1-cleavable 3'-phosphates. The collected experiments reveal a profound toxicity of strand breaks with irreparable 3' blocking lesions, and extend the function of the Rad1/Rad10 salvage pathway to 3'-phosphates. They further demonstrate a role for Tpp1 in repairing endogenously created 3'-phosphates. The source of these phosphates remains enigmatic, however, because apn1 tpp1 rad1 slow growth could be correlated with neither the presence of a yeast delta-lyase, the activity of the 3'-phosphate-generating enzyme Tdp1, nor levels of endogenous oxidation.     

Contractility and ischemic response of hearts from transgenic mice with altered sarcolemmal K(ATP) channels

The functional significance of ATP-sensitive K(+) (K(ATP)) channels is controversial. In the present study, transgenic mice expressing a mutant Kir6.2, with reduced ATP sensitivity, were used to examine the role of sarcolemmal K(ATP) in normal cardiac function and after an ischemic or metabolic challenge. We found left ventricular developed pressure (LVDP) was 15-20% higher in hearts from transgenics in the absence of cardiac hypertrophy. beta-Adrenergic stimulation caused a positive inotropic response from nontransgenic hearts that was not observed in transgenic hearts. Decreasing extracellular Ca(2+) decreased LVDP in hearts from nontransgenics but not in those from transgenics. These data suggest an increase in intracellular [Ca(2+)] in transgenic hearts. Additional studies have demonstrated hearts from nontransgenics and transgenics have a similar postischemic LVDP. However, ischemic preconditioning does not improve postischemic recovery in transgenics. Transgenic hearts also demonstrate a poor recovery after metabolic inhibition. These data are consistent with the hypothesis that sarcolemmal K(ATP) channels are required for development of normal myocardial function, and perturbations of K(ATP) channels lead to hearts that respond poorly to ischemic or metabolic challenges.     

Simulated microgravity perturbs actin polymerization to promote nitric oxide-associated migration in human immortalized Eahy926 cells

Apicomplexan parasites obligatorily invade and multiply within eukaryotic cells. Phylogenetically, they are related to a group of algae which, during their evolution, have acquired a secondary endosymbiont. This organelle, which in the parasite is called the apicoplast, is highly reduced compared to the endosymbionts of algae, but still contains many plant-specific biosynthetic pathways. The malaria parasite Plasmodium falciparum infects mammalian erythrocytes which are devoid of intracellular compartments and which largely lack biosynthetic pathways. Despite the limited resources of nutrition, the parasite grows and generates up to 32 merozoites which are the infectious stages of the complex life cycle. A large part of the intra-erythrocytic development takes place in the so-called parasitophorous vacuole, a compartment which forms an interface between the parasite and the cytoplasm of the host cell. In the course of parasite growth, the host cell undergoes dramatic alterations which on one hand contribute directly to the symptoms of severe malaria and which, on the other hand, are also required for parasite survival. Some of these alterations facilitate the acquisition of nutrients from the extracellular environment which are not provided by the host cell. Here, we describe the cell biologically unique interactions between an intracellular eukaryotic pathogen and its metabolically highly reduced host cell. We further discuss current models to explain the appearance of pathogen-induced novel physiological properties in a host cell which has lost its genetic programme.     

ATM activation in the presence of oxidative stress

The Ataxia-Telangiectasia mutated (ATM) kinase is regarded as the major regulator of the cellular response to DNA double strand breaks (DSBs). In response to DSBs, ATM dimers dissociate into active monomers in a process promoted by the Mre11-Rad50-Nbs1 (MRN) complex. ATM can also be activated by oxidative stress directly in the form of exposure to H₂O₂. The active ATM in this case is a disulfide-crosslinked dimer containing two or more disulfide bonds. Mutation of a critical cysteine residue in the FATC domain involved in disulfide bond formation specifically blocks ATM activation by oxidative stress. Here we show that ATM activation by DSB s is inhibited in the presence of H₂O₂ because oxidation blocks the ability of MRN to bind to DNA . However, ATM activation via direct oxidation by H₂O₂ complements the loss of MRN/DSB-dependent activation and contributes significantly to the overall level of ATM activity in the presence of both DSB s and oxidative stress.Key words: ATM, DNA repair, double-strand break, oxidative stress, ROS     

Chronic xanthine oxidase inhibition prevents myofibrillar protein oxidation and preserves cardiac function in a transgenic mouse model of cardiomyopathy

Heart failure is a clinical syndrome associated with elevated levels of oxygen-derived free radicals. Xanthine oxidase activity is believed to be one source of reactive oxygen species in the failing heart. Interventions designed to reduce oxidative stress are believed to have significant therapeutic potential in heart failure. This study tested the hypothesis that xanthine oxidase activity would be elevated in a mouse model of dilated cardiomyopathy and evaluated the effect of chronic oral allopurinol, an inhibitor of xanthine oxidase, on contractility and progressive ventricular dilation in these mice. Nontransgenic and transgenic mice containing a troponin I truncation were treated with oral allopurinol from 2-4 mo of age. Myocardial xanthine oxidase activity was threefold higher in untreated transgenic mice compared with nontransgenic mice. Analyses of myofilament proteins for modification of carbonyl groups demonstrated myofibrillar protein damage in untreated transgenic mice. Treatment with allopurinol for 2 mo suppressed xanthine oxidase activity and myofibrillar protein oxidation. Allopurinol treatment also alleviated ventricular dilation and preserved shortening fraction in the transgenic animals. In addition, cardiac muscle twitch tension was preserved to 70% of nontransgenic levels in allopurinol-treated transgenic mice, a significant improvement over untreated transgenic mice. These findings indicate that chronic inhibition of xanthine oxidase can alter the progression of heart failure in dilated cardiomyopathy.     

Identification of DNA 3'-phosphatase active site residues and their differential role in DNA binding, Mg2+ coordination, and catalysis

DNA 3'-phosphatase (Tpp1) from Saccharomyces cerevisiae, a homologue of human polynucleotide kinase/3'-phosphatase, has been shown to participate in DNA damage repair by removing 3'-phosphate blocking lesions. Tpp1 shows similarity to the l-2-haloacid dehalogenase superfamily of enzymes. By comparison to phosphoserine phosphatase, a well-studied member of this family, we designed conservative and nonconservative substitutions of likely active site residues of Tpp1 and tested them in a variety of assays. From the loss or impairment of activity, we identified D35, D37, T39, S88, K170, D206, and D218 as being involved in Tpp1 catalysis. D35 and K170 were the most critical since maximum inactivation was seen with even conservative mutations. Tpp1 bound DNA through its active site in a Mg(2+)-dependent manner and exhibited a preference for dsDNA. Although Tpp1 bound more strongly to DNA with a free 3' terminus, it also bound well to covalently closed DNA, suggesting a possible lesion scanning mechanism. DNA binding studies further indicated that Tpp1 coordinates Mg(2+) through D35 and D206 and contacts the DNA 3' end through D37. The removal of 3'-phosphate involved a phospho-Tpp1 intermediate, and our results support D35 as being the point of covalent attachment. On the basis of these similarities in mutant phenotypes of Tpp1 and phosphoserine phosphatase, we propose a reaction mechanism for Tpp1 which explains its strict phosphate specificity.     

Myosin binding protein C is differentially phosphorylated upon myocardial stunning in canine and rat hearts-- evidence for novel phosphorylation sites

Myocardial stunning is the transient cardiac dysfunction that follows brief episodes of ischemia and reperfusion without associated myocardial necrosis. Currently, there is limited knowledge about its cellular and biochemical mechanisms. In order to better understand the underlying mechanisms of contractile dysfunction associated with the stunning, comprehensive proteomic studies using 2-D DIGE were performed using a regional stunning model in canine heart. Cardiac myosin binding protein C (cMyBP-C), a regulatory myofilament protein associated with the thick filament, and nebulette, a thin filament associated protein, were differentially expressed. Phosphoprotein specific staining indicated both protein changes were due to phosphorylation. Subsequent phosphorylation mapping of canine cMyBP-C using IMAC and MS/MS identified five phosphorylation sites, including three novel sites. In order to further evaluate this finding in a different model, cMyBP-C phosphorylation was examined in a rat model of global stunning. In the rat model, stunning was associated with increased phosphorylation of cMyBP-C at a critical calcium/calmodulin-dependent kinase II site, and the increased phosphorylation was largely inhibited when stunning was prevented by either ischemic preconditioning or reperfusion in the presence of low-calcium buffer. These data indicate cMyBP-C phosphorylation plays an important role in myocardial stunning.     

Dexamethasone induced alterations in enzymatic and nonenzymatic antioxidant status in heart and kidney of rats

This study was designed to investigate the alterations in thiobarbituric acid reactants (TBA-reactants) and enzymatic and nonenzymatic antioxidant levels induced by dexamethasone (Dex) in heart and kidney and to find out whether these alterations induced by Dex and its hypertensive effect had any role in the maintenance of hypertension in this model. Administration of dexamethasone induced severe loss of body weight, significant increase in heart and kidney weights and also marked electrocardiographic changes. The protein content in heart and kidney increased significantly during Dex administration and returned to near normalcy after withdrawal. Total activity of lactate dehydrogenase showed a significant increase in heart till day 8 of treatment, whereas in serum, it exhibited a significant decrease. The activity of CK in heart showed an increase till day 8 of treatment and approached normalcy thereafter. In serum, CK exhibited a decrease till day 8, remaining insignificant thereafter. CKMB in heart showed an insignificant increase initially, reaching normal levels on Dex withdrawal, whereas in serum, it showed a significant decrease throughout the experimental period. Mean arterial pressure (MAP) and heart rate increased significantly, while a significant elevation in the ST segment was noticed during administration as well as after withdrawal of dex. The TBA-reactants levels were found to increase in heart and kidney during days 12 and 16 of administration with Dex and even after withdrawal of Dex, the levels were insignificantly elevated. The level of glutathione in heart and kidney increased from day 4 onwards and reached normalcy during the later stages of treatment and after withdrawal of Dex. The total sulfhydryl groups exhibited a significant increase in both heart and kidney throughout the experiment. The antioxidant enzymes such as catalase, superoxide dismutase, glutathione peroxidase and glutathione S-transferase exhibited a significant decrease in heart during Dex administration whereas, in kidney, they exhibited a significant increase during treatment and after withdrawal of Dex. Thus, Dex induced rise in mean arterial pressure, significant alterations in electrocardiographic parameters and also marked alterations in enzymatic and nonenzymatic antioxidant levels and in the TBA-reactants level in heart and kidney.