Effect of glutathione depletion on the cytotoxicity of xenobiotics and induction of single-strand DNA breaks by ionizing radiation in isolated hamster round spermatids

Male Infertility and Oxidative Stress: A Focus on the Underlying Mechanisms

Reactive oxygen species (ROS) play a critical role in defining the functional competence of human spermatozoa. When generated in moderate amounts, ROS promote sperm capacitation by facilitating cholesterol efflux from the plasma membrane, enhancing cAMP generation, inducing cytoplasmic alkalinization, increasing intracellular calcium levels, and stimulating the protein phosphorylation events that drive the attainment of a capacitated state. However, when ROS generation is excessive and/or the antioxidant defences of the reproductive system are compromised, a state of oxidative stress may be induced that disrupts the fertilizing capacity of the spermatozoa and the structural integrity of their DNA. This article focusses on the sources of ROS within this system and examines the circumstances under which the adequacy of antioxidant protection might become a limiting factor. Seminal leukocyte contamination can contribute to oxidative stress in the ejaculate while, in the germ line, the dysregulation of electron transport in the sperm mitochondria, elevated NADPH oxidase activity, or the excessive stimulation of amino acid oxidase action are all potential contributors to oxidative stress. A knowledge of the mechanisms responsible for creating such stress within the human ejaculate is essential in order to develop better antioxidant strategies that avoid the unintentional creation of its reductive counterpart.

Suppression of uric acid generation and blockade of glutathione dysregulation by L-arginine ameliorates dichlorvos-induced oxidative hepatorenal damage in rats

Dichlorvos is a known risk factor for organ toxicity. The liver and kidney are essential metabolic tissues but it is unclear whether or not there is associated redox dyshomeostasis in both organs in physiological and pathological states. Uric acid accumulation and glutathione dysregulation have been implicated in the aetiopathogenesis of organ damage. The antioxidant potentials of L-arginine have been shown in various conditions. The present study was thus designed to investigate the synchrony in hepatic and renal uric acid and glutathione status in dichlorvos-induced hepatorenal damage and to probe the possible therapeutic role of L-arginine. Twenty-one male Wistar rats were treated with standard rat diet and water, dichlorvos, or dichlorvos and L-arginine. Our findings revealed that dichlorvos significantly impaired hepatic and renal functions, increased hepatic and renal malondialdehyde, but reduced glutathione and activities of superoxide dismutase, catalase, and glutathione peroxidase. These events were accompanied by increased accumulation of plasma, hepatic, and renal uric acid as well as reduced body weight gain, and hepatic and renal weights. Histopathological examinations revealed hepatic and renal architectural derangement and cellular necrosis and degeneration in dichlorvos-exposed rats. Interestingly, L-arginine reversed dichlorvos-induced systemic, hepatic and renal synchronous redox dyshomeostasis. L-arginine administration also improved hepatic and renal cytoarchitecture. It is thus concluded that dichlorvos triggered synchronous uric acid generation and glutathione alterations in the liver and kidney. L-arginine confers protection against dichlorvos-induced hepatorenal damage via suppression of uric acid generation and blockade of glutathione dysregulation.

Single-Layered MoS2-PEI-PEG Nanocomposite-Mediated Gene Delivery Controlled by Photo and Redox Stimuli

Stimuli-responsive gene delivery systems maximize therapeutic efficacy by controlling the cytosolic conveyance and rate of effective gene release. We present herein a hybrid nanocomposite composed of a 2D nanomaterial, MoS2, modified by attaching two polymers (polyethylenimine (PEI) and polyethylenglycol (PEG)) via disulfide bonds. This MoS2-PEI-PEG nanocomposite interacts with DNA by electrostatic interaction, and accordingly forms a nanosized complex with high stability. Photothermal conversion of MoS2 nanosheet is employed in order to induce photothermally triggered endosomal escape upon the near infrared light irradiation. After endosomal escape, polymers are detached from the MoS2 nanosheet by the intracellular reducing agent, glutathione (GSH), resulting in effective gene release from the nanocomposite. This sequential process initiated by external and internal stimuli remarkably enhances gene delivery efficiency by effective endosomal escape and gene release without severe cytotoxicity. Our rationally designed MoS2 nanocomposite provides a spatiotemporally controllable platform to deliver genetic material into cells.

Hsp90 inhibitors and drug resistance in cancer: the potential benefits of combination therapies of Hsp90 inhibitors and other anti-cancer drugs

Hsp90 is a chaperone protein that interacts with client proteins that are known to be in the cell cycle, signaling and chromatin-remodeling pathways. Hsp90 inhibitors act additively or synergistically with many other drugs in the treatment of both solid tumors and leukemias in murine tumor models and humans. Hsp90 inhibitors potentiate the actions of anti-cancer drugs that target Hsp90 client proteins, including trastuzumab (Herceptin™) which targets Her2/Erb2B, as Hsp90 inhibition elicits the drug effects in cancer cell lines that are otherwise resistant to the drug. A phase II study of the Hsp90 inhibitor 17-AAG and trastuzumab showed that this combination therapy has anticancer activity in patients with HER2-positive metastatic breast cancer progressing on trastuzumab. In this review, we discuss the results of Hsp90 inhibitors in combination with trastuzumab and other cancer drugs. We also discuss recent results from yeast focused on the genetics of drug resistance when Hsp90 is inhibited and the implications that this might have in understanding the effects of genetic variation in treating cancer in humans.

Acute cyclophosphamide exposure has germ cell specific effects on the expression of stress response genes during rat spermatogenesis

Exposure of male rats to cyclophosphamide, a commonly used anticancer and immunosuppressive drug, has been shown to alter fertility and progeny outcome in a male germ cell phase-specific manner. The effect of toxicant exposure on male germ cells depends in part on the stress response mechanisms present during the different stages of spermatogenesis. To assess how acute cyclophosphamide exposure affects the expression of stress response genes, we examined the expression of 216 genes, using gene expression arrays, in isolated rat spermatogenic cell types (pachytene spermatocytes, round spermatids, and elongating spermatids). Cyclophosphamide exposure affected gene expression in all cell types but most dramatically in round spermatids. Increased transcript levels were observed for 30 genes in round spermatids compared to seven genes in pachytene spermatocytes and two in elongating spermatids. The expression of genes involved in apoptosis, DNA-damage recognition and repair, transcriptional activation, and in the heat shock protein-chaperone response was most affected by cyclophosphamide in round spermatids. Our results demonstrate that cyclophosphamide alters the expression of stress response genes during spermatogenesis in a germ cell-specific manner. The greater response of round spermatids to cyclophosphamide suggests that this cell type may be more susceptible to the damaging effects induced by this drug, possibly due to the chromatin remodeling that is taking place at this stage of spermatogenesis. This observation is consistent with the reported higher level of abnormal progeny outcome seen when the germ cells were first exposed to cyclophosphamide as round spermatids.

Using MT(-/-) mice to study metallothionein and oxidative stress

Mice with null mutations for metallothionein genes MT-1 and MT-2 were used to study the role that metallothionein plays in protecting cellular targets in vivo from oxidative stress. Wild-type (MT(+/+)) and MT-null (MT(-/-)) mice were treated with either saline or zinc and exposed to two types of oxidative stress: gamma-irradiation or 2-nitropropane. There was no alteration in the antioxidant defense system (superoxide dismutase, catalase, or glutathione peroxidase and glutathione levels) to compensate for the lack of the metallothionein in the MT(-/-) mice. The amount of oxidative damage to liver DNA, lipids, and proteins were similar for the MT(-/-) and MT(+/+) mice even though the levels of metallothionein in the livers of the saline- or zinc-pretreated MT(+/+) mice were 5- to 100-fold greater than found in the MT(-/-) mice. To determine if metallothionein can protect mice from the lethal effects of ionizing radiation, the mean survivals of MT(-/-) and MT(+/+) mice exposed to whole body gamma-irradiation were measured and found to be similar. However, the mean survival increased significantly after zinc pretreatment for both the MT(-/-) and MT(+/+) mice. These results demonstrate that tissue levels of metallothionein do not protect mice in vivo against oxidative stress.

Oxidative damage of mitochondrial and nuclear DNA induced by ionizing radiation in human hepatoblastoma cells

PURPOSE

Since reactive oxygen species (ROS) act as mediators of radiation-induced cellular damage, the aim of our studies was to determine the effects of ionizing radiation on the regulation of hepatocellular reduced glutathione (GSH), survival and integrity of nuclear and mitochondrial DNA (mtDNA) in human hepatoblastoma cells (Hep G2) depleted of GSH prior to radiation.

METHODS AND MATERIALS

GSH, oxidized glutathione (GSSG), and generation of ROS were determined in irradiated (50-500 cGy) Hep G2 cells. Clonogenic survival, nuclear DNA fragmentation, and integrity of mtDNA were assessed in cells depleted of GSH prior to radiation.

RESULTS

Radiation of Hep G2 cells (50-400 cGy) resulted in a dose-dependent generation of ROS, an effect accompanied by a decrease of reduced GSH, ranging from a 15% decrease for 50 cGy to a 25% decrease for 400 cGy and decreased GSH/GSSG from a ratio of 17 to a ratio of 7 for controls and from 16 to 6 for diethyl maleate (DEM)-treated cells. Depletion of GSH prior to radiation accentuated the increase of ROS by 40-50%. The depletion of GSH by radiation was apparent in different subcellular sites, being particularly significant in mitochondria. Furthermore, depletion of nuclear GSH to 50-60% of initial values prior to irradiation (400 cGy) resulted in DNA fragmentation and apoptosis. Consequently, the survival of Hep G2 to radiation was reduced from 25% of cells not depleted of GSH to 10% of GSH-depleted cells. Fitting the survival rate of cells as a function of GSH using a theoretical model confirmed cellular GSH as a key factor in determining intrinsic sensitivity of Hep G2 cells to radiation. mtDNA displayed an increased susceptibility to the radiation-induced loss of integrity compared to nuclear DNA, an effect that was potentiated by GSH depletion in mitochondria (10-15% intact mtDNA in GSH-depleted cells vs. 25-30% of repleted cells).

CONCLUSION

GSH plays a critical protective role in maintaining nuclear and mtDNA functional integrity, determining the intrinsic radiosensitivity of Hep G2. Although the DNA repair is a complex process that is not yet completely understood, the protective role of GSH probably does not seem to involve the repair of classical DNA damage but may relate to modification of DNA damage dependent signaling.

Transcriptional regulation of the heavy subunit chain of gamma-glutamylcysteine synthetase by ionizing radiation

Since glutathione (GSH) protects against oxidative stress, we determined the regulation of cellular GSH by ionizing radiation in human hepatoblastoma cells, HepG2. The levels of GSH increased in irradiated HepG2 due to a greater gamma-glutamylcysteine synthetase (gamma-GCS) activity, which was paralleled by gamma-GCS heavy subunit chain (gamma-GCS-HS) mRNA levels. Transcription of deletion constructs of the gamma-GCS-HS promoter cloned in a reporter vector was associated with activator protein-1 (AP-1), consistent with the DNA binding of AP-1 in nuclear extracts of irradiated HepG2. Hence, the transcriptional regulation of gamma-GCS by ionizing radiation emerges as an adaptive mechanism, which may be of significance to control the consequences of the oxidative stress induced by radiation.

Identification of a unique mu-class glutathione S-transferase in mouse spermatogenic cells

The fibrous sheath is a major cytoskeletal structure in the principal piece of the mammalian sperm flagellum. Two peptide sequences obtained from a tryptic digest of mouse fibrous sheath proteins exhibited high homology with mu-class glutathione S-transferases (GSTs). Using a DNA probe amplified from degenerate polymerase chain reaction (PCR) primers predicted from these two peptide sequences, a approximately 1.1 kb cDNA clone for fibrous sheath component 2 (Fsc2) was isolated which had 84% nucleic acid and 89% amino acid sequence identity with a previously reported mu-class human GST gene (hGSTM3; Campbell et al., 1990: J Biol Chem 265:4188-9193). Sequences corresponding to those of the two fibrous sheath peptides were present in the protein encoded by the Fsc2 cDNA. Northern analysis with the full length Fsc2 cDNA detected a approximately 1.1 kb mRNA in 12 of 15 somatic tissues examined, as well as in testis and isolated spermatogenic cells. However, 5'(nt--96 to 12) or 3'(nt 637 to 808) Fsc2 probes, containing mostly noncoding sequences, detected a approximately 1.1 kb mRNA abundant in testis and isolated spermatogenic cells, but absent or present at low levels in somatic tissues. Northern analysis with RNA from testes of mice of different postnatal ages and purified spermatogenic cell populations indicated that this transcript is first present during the meiotic phase of germ cell development. These results suggest that a previously unreported mu-class GST gene (mGSTM5.) is expressed at a specific time during the development of spermatogenic cells in the mouse. Immunoblot analysis indicated that a mu-class GST protein is associated with the fibrous sheath, suggesting that it becomes an integral part of the mouse sperm cytoskeleton.

Antioxidant system in rat testicular cells

The activity of the enzymes involved in the antioxidant defence--superoxide dismutase (SOD), glutathione peroxidase (GPx), reductase (GR), S-transferase (GST)--as well as the glutathione (GSH) levels were measured in different rat testicular cell populations. A differential distribution of these components among testicular cell types was clearly observed. Sertoli and peritubular cells had elevated SOD and GSH-dependent enzyme activities associated with a high GSH content. Compared with the somatic cells, pachytene spermatocytes (PS) and round spermatids (RS) presented a different antioxidant system characterized by higher SOD activity and GSH content associated with very low GSH-dependent enzyme activity. Spermatozoa exhibited the same enzymatic system as PS and RS but were devoid of GSH. Interstitial tissue displayed high GSH content, moderate SOD and GSH-related enzyme activity except for GPx which was very elevated. It is concluded that the different categories of testicular cells probably display a highly variable susceptibility to oxidative stress.

Induction and repair of DNA single-strand breaks and DNA base damage at different cellular stages of spermatogenesis of the hamster upon in vitro exposure to ionizing radiation

Alkaline elution has been used for quantitative detection of DNA damage caused by ionizing radiation in unlabeled somatic and germ cells. Both the induction and subsequent repair have been studied for two classes of DNA damage, viz. single-strand breaks (SSB), and base damage (BD) recognized by the gamma-endonuclease activity in a cell-free extract of Micrococcus luteus bacteria. The high sensitivity of the assay permitted the measurement of induction and repair of SSB and BD after in vitro exposure of hamster germ cells in different cellular stages of spermatogenesis (spermatocytes, round and elongated spermatids), and of bone-marrow cells, to biologically relevant doses (0-8 Gy) of 60Co gamma-rays. A dose-dependent increase was observed for both types of lesions, which was similar for most cell types. The elongated spermatids, however, showed a lower induction frequency of SSB (and perhaps BD). Spermatocytes, round spermatids and bone-marrow cells had normal, fast repair of the SSB when compared with the repair reported for cultured rodent cells and human lymphocytes. In contrast, the elongated spermatids showed hardly any SSB repair. The initial rate of repair of BD in spermatocytes and bone-marrow cells was in the same range as that for SSB, but only 60-70% of the initial BD was repaired within 1 h, whereas after that period no SSB were detectable. The round spermatids hardly repaired any BD within the first hour after irradiation, but after 7 h only a few BD could be detected. In elongated spermatids repair of BD could not be measured due to a high background level of this type of damage.

Immunochemical detection of DNA damage induction and repair at different cellular stages of spermatogenesis of the hamster after in vitro or in vivo exposure to ionizing radiation

An immunochemical method has been used to detect quantitatively DNA damage caused by ionizing radiation in germ cells. With this method, DNA strand breaks as well as lesions converted into breaks in alkaline medium are measured as a function of controlled partial unwinding of the DNA, a time-dependent process starting at each breakage site, followed by the determination of the relative amount of single-stranded regions by use of a single-strand specific monoclonal antibody. With this method the induction and repair of DNA damage in different cellular stages of spermatogenesis (spermatocytes, round and elongated spermatids) of the hamster were investigated. Germ cells were irradiated in vitro with 60Co-gamma-rays, at doses between 0 and 5 Gy. A linear dose-response relationship was observed. Spermatocytes and round spermatids had normal, fast repair of the lesions when compared with the repair of these sites in cultured V79 or CHO cells and human lymphocytes. The elongated spermatids, however, showed hardly any repair. Similar results were obtained after the in vivo gamma-irradiation of hamsters with doses of 0. 4, and 8 Gy and subsequent isolation of germ cells. The damage was still detectable in the elongated spermatids at 24 h after exposure. The results of the experiments show substantial differences in repair capacity between different stages of germ cell development. Because DNA is the major target for mutation induction, this assay may be useful for assessment of the genetic risk of exposure of male germ cells to ionizing radiation, in relation to the stage of development.