Supervision of cellular response to radiation by human interferon

Human interferon (HuIFN) conferred human RSa cells to increased resistance to ultraviolet light, 4-nitroquinoline-1-oxide and X-ray in association with enhancement of DNA-repair capacity. The HuIFN actions were summarized by the supervision of cellular response, possibly via plasminogen activator-like protease induction.     

The role of ATM and ATR in the cellular response to hypoxia and re-oxygenation

ATM and ATR are stress-response kinases which respond to a variety of insults including ionizing radiation, replication arrest, ultraviolet radiation and hypoxia/re-oxygenation. Hypoxia occupies a unique niche in the study of both ATR- and ATM-mediated checkpoint pathways. Hypoxia is a physiologically significant stress that occurs in virtually all solid tumors and differs from most other stresses in that it does not induce DNA damage. Previous studies have indicated that hypoxia provides a unique way to induce ATR in response to inhibition of DNA replication. During tumor expansion hypoxia is inevitably followed by periods of re-oxygenation which in vitro has been shown to induce significant levels of DNA damage and an ATM response. Therefore both ATR and ATM have a role to play in hypoxia/re-oxygenation.     

The effects of ionizing radiation on DNA: the role of thiols as radioprotectors

Electron loss from N-(2-mercaptopropionyl) glycine (PSH) gave an EPR detectable radical anion, PS-.SP(-). When the PSH derivative was frozen in aqueous DNA solutions to 77 K and exposed to ionizing radiation, normal damage to the DNA was detected by EPR spectroscopy. However, on annealing above 77 K, central EPR features for the DNA base radical cations and anions gave central features assigned to PS-.SP(-) sigma*-radical anions, together with outer features for 5-6-dihydro-5-thymyl radicals, TH.. It is proposed that on freezing, the PSH molecules are constrained into a glassy region around the DNA, and that, on annealing, electron donation gives PS. radicals, with loss of quanine radical-cations, G(.+). The PS. radicals were not detectable, but on reaction with another PSH molecule, gave good EPR spectra for PS-.SP(-) radical-anions. These results indicate that PSH had little effect on the yield of the other base radicals C(.-)/T(.-). Also, growth of TH. radicals, formed from protonated thymine radical-anions, T(.-), were detected. We conclude that the primary effect of PSH is to capture the G(.+) centers, and thus could either prevent or repair radiation damage to DNA.     

The role of cyclin D1 in response to long-term exposure to ionizing radiation

The health-related hazards resulting from long-term exposure to radiation remain unknown. Thus, an appropriate molecular marker is needed to clarify these effects. Cyclin D1 regulates the cell cycle transition from the G1 phase to the S phase. Cyclin D1 is degraded as a G1/S checkpoint after 10 Gy of single acute radiation exposure, whereas conversely, cyclin D1 is stabilized when human tumor cells are exposed to fractionated radiation (FR) with 0.5 Gy of x-rays for 31 d. In this article, we review new findings regarding cyclin D1 overexpression in response to long-term exposure to FR. Cyclin D1 overexpression is associated with induction of genomic instability in irradiated cells. Therefore, repression of cyclin D1 expression is likely to cancel the harmful effects of long-term exposure to FR. Thus cyclin D1 may be a marker of long-term exposure to radiation and is a putative molecular radioprotection target for radiation safety.     

Exploiting cell surface thiols to enhance cellular uptake

Efficient cellular delivery is one of the key issues that has hampered the therapeutic development of novel synthetic biomolecules such as oligonucleotides, peptides and nanoparticles. The highly specialized cellular plasma membrane specifically internalizes compounds through tightly regulated mechanisms. It is possible to exploit these natural mechanisms of cellular uptake with rationally designed reagents. Here, we discuss how thiol groups (-SH) naturally present on the cell surface (exofacial thiols) can be used to enhance cellular association and internalization of various materials bearing thiol-reactive groups in their structure. We propose that such thiol modifications should be considered in future design of synthetic biomolecules for optimized cellular delivery.     

The role of endogenous thiols in intrinsic radioprotection

Observations are reviewed from experiments performed to study the role of endogenous thiols in the radiation response of cells using a glutathione-deficient and a related glutathione-proficient cell strain. The effect of glutathione in the initial radical reactions was considered and the yield of single-strand DNA breaks was the end-point of the response. The rejoining of breaks and clonogenic survival were chosen as end-points when, in addition, the role of glutathione in the subsequent biochemical processes was studied. The results were interpreted to indicate that glutathione plays a role in both the radical and the biochemical reactions which follow irradiation. In the former case, it functions as a damage-restituting reactant, in general agreement with the 'competition model'. Some biochemical repair processes, in particular those concerned with the rejoining of breaks induced by radiation in the presence of oxygen or misonidazole, appear also to be critically dependent on glutathione. Due, probably, to its particular spatial distribution, endogenous glutathione is specific in the radical processes, and exogenous thiols cannot be substituted for it. No such specificity was indicated in the biochemical processes related to strand break rejoining.     

The role of regulatory networks of the cell response to damages in radiation effects

In view of modern knowledge and concepts about components, function and mechanisms of response of cell molecular structures to damaging effects, response which is generating specialized modules of reactions, it is shown that main components of the mechanism of maintenance of genome constancy at ionizing radiation exposure are checkpoints of cell cycle, DNA repair and apoptosis. They operate under the control of a genetic system at participation of Tp53 gene, corresponding protein and of regulatory networks formed by cascades of mitogen-activated protein kinases (MAPK). At ionizing radiation exposure the MAPK special modules participate in formation of radiation effect: ERK 1/2 (extracellular signal-regulated kinase 1 and 2), JNK/SAPK (c-Jun N-terminal kinase/stress activated protein kinase) and p38 MAPK. Executing physiological functions of maintenance of normal life activity of cells, they do not lose this capacity after exposure to ionizing radiation, participating in formation of radiation effect in a wide range of doses, and are inactivated only by exposure to very high doses. It is concluded that in light of the modern data the main problem is not a problem of mechanisms of biological effect of ionizing radiation but a problem of biological mechanisms of radiation exposure.     

Fluorometric quantitation of cellular and nonprotein thiols

A microfluorometric assay for thiols has been developed using the thiol-specific fluorochrome N-[4-(7-diethylamino-4-methyl-3-coumarinyl)phenyl]maleimide (CPM). The technique may be used to quantitate either cellular or plasma thiols over a range of 0.01 to 3.0 nmol and may be used with as few as 1-3 X 10(5) cells giving highly proportional and reproducible results. Values for nonprotein thiols obtained with this assay agree well with previous reports on glutathione (GSH) levels for both lymphocytes and plasma. Readings are determined with the aid of an automated fluorescence microplate reader which allows up to 96 samples, including standards, to be read at the same time. Cellular thiols accessible after lysis were also quantitated before and after treatment of intact cells with various thiol-reactive chemicals. Interestingly, HgCl2, bromoethanesulfonic acid, and N-ethylmaleimide differentially modified protein and nonprotein thiol levels.     

On the role of p53 in the cellular response to aneuploidy

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The cellular response to chromosome breakage

DNA double-strand breaks (DSBs) are among the most deleterious types of damage that can occur in the genome of eukaryotic cells because failure to repair them can lead to loss of genetic information and chromosome rearrangements. DSBs can arise by failures in DNA replication and by exposure to environmental factors, such as ionizing radiations and radiomimetic chemicals. Moreover, they might arise when telomeres undergo extensive erosion, leading to the activation of the DNA damage response pathways and the onset of apoptosis and/or senescence. Importantly, DSBs can also form in a programmed manner during development. For example, meiotic recombination and rearrangement of the immunoglobulin genes in lymphocytes require the generation of site- or region-specific DSBs through the action of specific endonucleases. Efficient DSB repair is crucial in safeguarding genome integrity, whose maintenance in the face of DSBs involves branched signalling networks that switch on DNA damage checkpoints, activate DNA repair, induce chromatin reorganization and modulate numerous cellular processes. Not surprisingly, defects in these networks result in a variety of diseases ranging from severe genetic disorders to cancer predisposition and accelerated ageing.     

The chromatin remodeler ISWI regulates the cellular response to hypoxia: role of FIH

The hypoxia-inducible factor (HIF) is a master regulator of the cellular response to hypoxia. Its levels and activity are controlled by dioxygenases called prolyl-hydroxylases and factor inhibiting HIF (FIH). To activate genes, HIF has to access sequences in DNA that are integrated in chromatin. It is known that the chromatin-remodeling complex switch/sucrose nonfermentable (SWI/SNF) is essential for HIF activity. However, no additional information exists about the role of other chromatin-remodeling enzymes in hypoxia. Here we describe the role of imitation switch (ISWI) in the cellular response to hypoxia. We find that unlike SWI/SNF, ISWI depletion enhances HIF activity without altering its levels. Furthermore, ISWI knockdown only alters a subset of HIF target genes. Mechanistically, we find that ISWI is required for full expression of FIH mRNA and protein levels by changing RNA polymerase II loading to the FIH promoter. Of interest, exogenous FIH can rescue the ISWI-mediated upregulation of CA9 but not BNIP3, suggesting that FIH-independent mechanisms are also involved. Of importance, ISWI depletion alters the cellular response to hypoxia by reducing autophagy and increasing apoptosis. These results demonstrate a novel role for ISWI as a survival factor during the cellular response to hypoxia.     

The in vitro cellular immune response to quartz

It is known that macrophages release into medium in vitro biologically active substances which modulate immune response. In recent years, increase attention has been directed towards the role of prostaglandin in macrophage function. Guinea pig splenic lymphocytes and peritoneal macrophage cultures were incubated with quartz (DQ12), Corundum and aspirin as prostaglandin inhibitor. Lymphocyte proliferation measured by 3H-thymidine incorporation, and lymphokine release by Bendixen-Soborg capillary test (MIF) were applied. EA rosetting and phagocytosis were determined for macrophage function assessment. Quartz suppressed the immune response evidenced by reduced 3H-thymidine incorporation and decreased lymphokine production. Aspirin (as a specific prostaglandin synthesis inhibitor) restored the affected by quartz immunological parameters. This observation gives support to the hypothesis that the immunological response to quartz involves macrophage prostaglandin release, presumably as a first step of lipid peroxidation.