Paraquat induces irreversible actin cytoskeleton disruption in cultured human lung cells

Rsad2 mediates Bisphenol A-induced actin cytoskeletal disruption in mouse spermatocytes

Bisphenol A (BPA) is widely exposed in populations worldwide and has negative effects on spermatogenesis both in animals and humans. The homeostasis of the actin cytoskeleton in the spermatogenic epithelium is crucial for spermatogenesis. Actin cytoskeleton destruction in the seminiferous epithelium is one of the important reasons for BPA-induced spermatogenesis disorder. However, the underlying molecular mechanisms remain largely unexplored. Herein, we explored the role and mechanism of Rsad2, an interferon-stimulated gene in BPA-induced actin cytoskeleton disorder in mouse GC-2 spermatocyte cell lines. After BPA exposure, the actin cytoskeleton was dramatically disrupted and the cell morphology was markedly altered accompanied by a significant increase in Rsad2 expression both in mRNA and protein levels in GC-2 cells. Furthermore, the phalloidin intensities and cell morphology were restored obviously when interfering with the expression of Rsad2 in BPA-treated GC-2 cells. In addition, we observed a significant decrease in intracellular ATP levels after BPA treatment, while the ATP level was obviously upregulated when knocking down the expression of Rsad2 in BPA-treated cells compared to cells treated with BPA alone. Moreover, Rsad2 relocated to mitochondria after BPA exposure in GC-2 cells. BPA promoted Rsad2 expression by activating type I IFN-signaling in GC-2 cells. In summary, Rsad2 mediated BPA-induced actin cytoskeletal disruption in GC-2 cells, which provided data to reveal the mechanism of BPA-induced male reproductive toxicity.

Industrial, Biocide, and Cosmetic Chemical Inducers of Cholestasis

A frequent side effect of many drugs includes the occurrence of cholestatic liver toxicity. Over the past couple of decades, drug-induced cholestasis has gained considerable attention, resulting in a plethora of data regarding its prevalence and mechanistic basis. Likewise, several food additives and dietary supplements have been reported to cause cholestatic liver insults in the past few years. The induction of cholestatic hepatotoxicity by other types of chemicals, in particular synthetic compounds, such as industrial chemicals, biocides, and cosmetic ingredients, has been much less documented. Such information can be found in occasional clinical case reports of accidental intake or suicide attempts as well as in basic and translational study reports on mechanisms or testing of new therapeutics in cholestatic animal models. This paper focuses on such nonpharmaceutical and nondietary synthetic chemical inducers of cholestatic liver injury, in particular alpha-naphthylisocyanate, 3,5-diethoxycarbonyl-1,4-dihydrocollidine, methylenedianiline, paraquat, tartrazine, triclosan, 2-octynoic acid, and 2-nonynoic acid. Most of these cholestatic compounds act by similar mechanisms. This could open perspectives for the prediction of cholestatic potential of chemicals.

Genotoxic effects of glyphosate or paraquat on earthworm coelomocytes

The potential genotoxicity (nuclear anomalies, damage to single-strand DNA) and pinocytic adherence activity of two (glyphosate-based and paraquat-based) commercial herbicides to earthworm coelomocytes (immune cells in the coelomic cavity) were assessed. Coelomocytes were extracted from earthworms (Pheretima peguana) exposed to concentrations Collapse

Key Words

• coelomocytes
• comet assay
• earthworm
• glyphosate
• micronucleus assay
• paraquat
• pinocytic adherence activity

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MESH Headings

• Animals
• Cell Adhesion
• Comet Assay
• DNA Damage
• Glycine/analogs & derivatives
• Glycine/toxicity
• Herbicides/toxicity
• Micronucleus Tests
• Mutagens/toxicity
• Oligochaeta/cytology
• Oligochaeta/drug effects
• Oligochaeta/genetics
• Paraquat/pharmacology
• Paraquat/toxicity
• Pinocytosis
• Toxicity Tests, Acute
• Toxicity Tests, Subacute
• Glyphosate

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Grants Collapse

Affiliation(s)

Ptumporn Muangphra Biology Department, Faculty of Science, Silpakorn University, Nakhon Pathom 73000, Thailand
Wimon Kwankua
Ravi Gooneratne

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beta-Thymosins

The development of thymosin beta(4) from a thymic hormone to an actin-sequestering peptide and back to a cytokine supporting wound healing will be outlined. Thymosin fraction 5 consists of a mixture of polypeptides and improves immune response. Starting with fraction 5, several main peptides (thymosin alpha(1), polypeptide beta(1), and thymosin beta(4)) were isolated and tested for biological activity. However, none of the isolated peptides were really thymic hormones. They are all biological important peptides with diverse functions. Polypeptide beta(1) is identical to ubiquitin truncated by two C-terminal glycine residues. Several peptides related to thymosin beta(4) were isolated and sequenced from various species. Large amounts of thymosin beta(4) were found in many cells. It was postulated that the beta-thymosins might have a general function. The identification of a biological function of thymosin beta(4) was tedious. In 1990, Dan Safer and his colleagues recognized that thymosin beta(4) sequesters G-actin. The dissociation constant of the complex in the micromolar range allows for fast binding and release of G-actin. beta-Thymosins are the main intracellular G-actin-sequestering peptides in most vertebrate cells. Thymosin beta(4) is unstructured but folds into a stable conformation on binding to G-actin. It is present in the nucleus as well as the cytoplasm and might be responsible for sequestering nuclear actin. Several biological effects are attributed to thymosin beta(4), oxidized thymosin beta(4), or to ac-SDKP possibly generated from thymosin beta(4). However, very little is known about molecular mechanisms mediating the effects attributed to extracellular beta-thymosins.

Reproductive protein protects functionally sterile honey bee workers from oxidative stress

Research on aging shows that regulatory pathways of fertility and senescence are closely interlinked. However, evolutionary theories on social species propose that lifelong care for offspring can shape the course of senescence beyond the restricted context of reproductive capability. These observations suggest that control circuits of aging are remodeled in social organisms with continuing care for offspring. Here, we studied a circuit of aging in the honey bee (Apis mellifera). The bee is characterized by the presence of a long-lived reproductive queen caste and a shorter-lived caste of female workers that are life-long alloparental care givers. We focus on the role of the conserved yolk precursor gene vitellogenin that, in Caenorhabditis elegans, shortens lifespan as a downstream element of the insulin/insulin-like growth factor signaling cascade. Vitellogenin protein is synthesized at high levels in honey bee queens and is abundant in long-lived workers. We establish that vitellogenin gene activity protects worker bees from oxidative stress. Our finding suggests that one mechanistic explanation for patterns of longevity in bees is that a reproductive regulatory pathway has been remodeled to extend life. This perspective is of considerable relevance to research on longevity regulation that builds largely on inference from solitary model species.

Cell culture models of the respiratory tract relevant to pulmonary drug delivery

The respiratory tract holds promise as an alternative site of drug delivery due to fast absorption and rapid onset of drug action, with avoidance of hepatic and intestinal first-pass metabolism as an additional benefit compared to oral drug delivery. At present, the pharmaceutical industry increasingly relies on appropriate in vitro models for the faster evaluation of drug absorption and metabolism as an alternative to animal testing. This article reviews the various existing cell culture systems that may be applied as in vitro models of the human air-blood barrier, for instance, in order to enable the screening of large numbers of new drug candidates at low cost with high reliability and within a short time span. Apart from such screening, cell culture-based in vitro systems may also contribute to improve our understanding of the mechanisms of drug transport across such epithelial tissues, and the mechanisms of action how advanced drug carriers, such as nanoparticles or liposomes, can help to overcome these barriers. After all, the increasing use and acceptance of such in vitro models may lead to a significant acceleration of the drug development process by facilitating the progress into clinical studies and product registration.

Metabolism and bioactivation of toxicants in the lung. The in vitro cellular approach

Lung is a target organ for the toxicity of inhalated compounds. The respiratory tract is frequently exposed to elevated concentrations of these compounds and become the primary target site for toxicity. Occupational, accidental or prolonged exposure to a great variety of chemicals may result in acute or delayed injury to cells of the respiratory tract. Nevertheless, lung has a significant capability of biotransforming such compounds with the aim of reducing its potential toxicity. In some instances, the biotransformation of a given compound can result in the generation of more reactive, and frequently more toxic, metabolites. Indeed, lung tissue is known to activate pro-carcinogens (i.e. polycyclic aromatic hydrocarbons or N-nitrosamines) into more reactive intermediates that easily form DNA adducts. Lungs express several enzymes involved in the metabolising of xenobiotics. Among them, cytochrome P450 enzymes are major players in the oxidative metabolism as well metabolic bioactivation of many organic toxicants, including pro-carcinogens. Xenobiotic-metabolising P450 enzymes are expressed in bronchial and bronchiolar epithelium, Clara cells, type II pneumocytes, and alveolar macrophages Individual CYP isoforms have different patterns of localisation within pulmonary tissue. With the aid of sensitive techniques (i.e. reverse transcriptase-polymerase chain reaction, RT-PCR) it has become possible to detect CYP1A1, CYP1B1, CYP2A6, CYP2B6, CYP2E1 and CYP3A5 mRNAs in lung cells. Less conclusive results have been obtained concerning CYP2Cs, CYP2D6 and CYP3A4. CYP3A5 protein appears to be widely present in all lung samples and is localised in the ciliated and mucous cells of the bronchial wall, bronchial glands, bronchiolar ciliated epithelium and in type I and type II alveolar epithelium. Lung cells also express Phase II enzymes such as epoxide hydrolase, UGT1A (glucuronyl transferase) and GST-P1 (glutathione S-transferase), which largely act as detoxifying enzymes. A key question concerning organ-specific chemical toxicity is whether the actual target has the capacity to activate (or efficiently inactivate) chemicals. Results of several studies indicate that the different xenobiotic-metabolising CYPs, present in the human lung and lung-derived cell lines, likely contribute to in situ activation of pulmonary toxins, among them, pro-carcinogens. Some CYPs, in particular CYP1A, are polymorphic and inducible. Interindividual differences in the expression of these CYPs may explain the different risk of developing lung toxicity (possibly cancer), by agents that require metabolic activation. Few cell lines, principally A549, have been used with variable success as an experimental model for investigating the mechanisms of toxicity. Although RT-PCR analysis has evidenced the presence of the major human pulmonary CYP mRNAs, the measurable P450 specific activities are, however, far below those present in human lungs. Detection of the toxicity elicited by reactive metabolites requires the use of metabolically competent cells; consequently, better performing cells are needed to ensure realistic in vitro prediction of toxicity. Genetic manipulation of lung-derived cells allowing them to re-express key biotransformation enzymes appear to be a promising strategy to improve their functionality and metabolic performance.

Oxidative stress in rat cortical neurons and astrocytes induced by paraquat in vitro

Oxidative stress has been discussed as crucial mechanism of neuronal cell death in the adult brain. However, it was not clear until now whether neurons are more sensitive to oxidative stress than the other cells in the brain, e.g. astrocytes. Therefore both cell types were exposed to oxidative stress provoked by the redox-cycling compound paraquat. Cortical neurons were found to be more sensitive towards paraquat toxicity than astrocytes as shown by MTT and Neutral Red assay, two different cytotoxicity assays. Mitochondrial functions were determined by the mitochondrial membrane potential and intracellular ATP concentrations. Again cortical neurons were more severely impaired (by paraquat than astrocytes). The production of reactive oxygen species after paraquat exposure was much higher in cortical neurons than in astrocytes and correlated with a higher depletion of GSH (intracellular glutathion). Lipid peroxidation could be shown in astrocytes via the breakdown product malondialdehyde (MDA) whereas in cortical neurons 4-hydroxynonenal (4-HNE) was detected as this endpoint. If and how oxidative stress influences the antioxidant defense was determined via changes in the expression of antioxidant enzymes. Paraquat exposure lead to a 2-3 fold increase of catalase, MnSOD and CuZnSOD mRNA expression in astrocytes. In contrast to astrocytes, in cortical neurons catalase and MnSOD mRNA levels were only marginally elevated above 1.5-fold by treatment with paraquat. Expression levels of glutathione peroxidase (GPx) mRNA were the only one that were not changed in both cell types after paraquat exposure. It is concluded that the more marked increase in expression levels of antioxidant enzymes may render astrocytes more resistant to oxidative stress than neuronal cells.

The role of nitric oxide in paraquat-induced cytotoxicity in the human A549 lung carcinoma cell line

Paraquat (PQ) is a well-known pneumotoxicant that exerts its toxic effect by elevating intracellular levels of superoxide. In addition, production of pro-inflammatory cytokines has possibly been linked to PQ-induced inflammatory processes through reactive oxygen species (ROSs) and nitric oxide (NO). However, the role of NO in PQ-induced cell injury has been controversial. To explore this problem, we examined the effect of NO on A549 cells by exposing them to the exogenous NO donor NOC18 or to cytokines; tumor necrosis factor-alpha, interleukin-1 beta and interferon-gamma, as well as PQ. Although the exogenous NO donor on its own had no effect on the release of lactate dehydrogenase (LDH), remarkable release was observed when the cells were exposed to high concentrations of NOC18 and PQ. This cellular damage caused by 1 mM NOC18 plus 0.2 mM PQ was ascertained by phase contrast microscopy. On the other hand, NO derived from 25-50 microM NOC18 added into the medium improved the MTT reduction activity of mitochondria, suggesting a beneficial effect of NO on the cells. Incubation of A549 cells with cytokines increased in inducible NO synthase (iNOS) expression and nitrite accumulation, resulting in LDH release. PQ further potentiated this release. The increase in nitrite levels could be completely prevented by NOS inhibitors, while the leakage of LDH was not attenuated by the inhibition of NO production with them. On the other hand, ROS scavenging enzymes, superoxide dismutase and catalase, inhibited the leakage of LDH, whereas they had no effect on the increase in the nitrite level. These results indicate that superoxide, not NO, played a key role in the cellular damage caused by PQ/cytokines. Our in vitro models demonstrate that NO has both beneficial and deleterious actions, depending on the concentrations produced and model system used.

The dipyridyls paraquat and diquat attenuate the interaction of G-actin with thymosin beta4

Beta-thymosins sequester G-actin and preserve a pool of monomers of actin which constitute an important prerequisite for cellular function of the microfilament system. To study the influence of paraquat binding to G-actin on the interaction of G-actin with thymosin beta4 we determined the apparent dissociation constant of the G-actin-thymosin beta4 complex in the absence or presence of paraquat using an ultrafiltration assay. Paraquat (1,1'-dimethyl-4,4'-dipyridylium dichloride) attenuates this interaction in a concentration- and time-dependent manner. When exposed to 10 mM paraquat, the apparent dissociation constant increased 10-85-fold within 15 min to 24 h. After incubation for 24 h even a paraquat concentration as low as 100 microM increased the dissociation constant of the G-actin-thymosin beta4 complex from 0.66 microM to 0.82 microM (P < 0.05). Diquat (1,1'-ethylene-2,2'-dipyridylium dibromide) similarly weakens the interaction of G-actin and beta-thymosins. In none of the experiments was oxidation of the methionine residue or any other modification of thymosin beta4 detected. Therefore we conclude that the dipyridyls paraquat and diquat directly interact with G-actin and thereby impede the interaction between G-actin and thymosin beta4.

Synergistic cytotoxicity from nitric oxide and hyperoxia in cultured lung cells

Exogenous nitric oxide (NO) is being tested clinically for the treatment of pulmonary hypertension in infants and children. In most cases, these patients receive simultaneous oxygen (O2) therapy. However, little is known about the combined toxicity of NO + hyperoxia. To test this potential toxicity, human alveolar epithelial cells (A549 cells) and human lung microvascular endothelial lung cells were cultured in room air (control), hyperoxia (95% O2), NO (derived from chemical donors), or combined hyperoxia + NO. Control cells grew normally over a 6-day study period. In contrast, cell death from hyperoxia was evident after 4-5 days, whereas cells neither died nor divided in NO alone. However, cells exposed to both NO and hyperoxia began to die on day 2 and died rapidly thereafter. This cytotoxic effect was clearly synergistic, and cell death did not occur via apoptosis. As an indicator of peroxynitrite formation, nitrotyrosine-containing proteins were assayed using anti-nitrotyrosine antibodies. Two protein bands, at molecular masses of 25 and 35 kDa, were found to be increased in A549 cells exposed to NO or NO + hyperoxia. These results indicate that combined NO + hyperoxia has a synergistic cytotoxic effect on alveolar epithelial and lung vascular endothelial cells in culture.

Hydrogen peroxide-induced liver cell necrosis is dependent on AP-1 activation

To determine whether intracellular signaling events involved in apoptosis may also mediate necrosis, the role of the transcription factor AP-1 was investigated in a hepatoma cell model of cellular necrosis induced by oxidant stress. Treatment of the human hepatoma cell line HuH-7 with H2O2 caused dose-dependent necrosis as determined by light microscopy, fluorescent staining, and an absence of DNA fragmentation. H2O2 treatment led to increases in c-fos and c-jun mRNA levels, Jun nuclear kinase activity, and AP-1 DNA binding. AP-1 transcriptional activity measured with an AP-1-driven luciferase reporter gene was also increased. To determine whether this AP-1 activation contributed to H2O2-induced cell necrosis, HuH-7 cells were stably transfected with an antisense c-jun expression vector. Cells expressing antisense c-jun had decreased levels of AP-1 activation and significantly increased survival after H2O2 exposure. These data indicate that AP-1 activation occurs during oxidant-induced cell necrosis and contributes to cell death. Necrosis is therefore not always a passive process but may involve the activation of intracellular signaling pathways similar to those that mediate apoptosis.

Actin modifications and calcium homoeostasis in neurotoxicity. The case of organotin salts

The cytoskeleton is a major constituent of the neuronal cytoplasm; it controls cell shape and plays important roles in regulating various physiological processes. In neurons, actin filaments are involved in the growth of the neurite and the neurotransmitter release. Recent findings suggest that actin filaments play a role in modulating [Ca(2+)](i) responses to neurotoxic insults. The physiological functioning of the neural cell is critically dependent on the intracellular distribution of calcium. An increase of cytosolic free calcium can activate a number of intracellular reactions, including neurotransmitter release, protein phosphorylation, protease activity, and, eventually, cell death. Many neurotoxic agents with diverse mechanisms have been reported to affect mechanisms associated with calcium. Among these are organotin compounds: they can both raise the cytosolic and synaptosomal [Ca(2+)](i) concentrations and interfere with the [Ca(2+)](i) response evoked by different agonists. Furthermore, some of these compounds cause actin depolymerization. The interference of triethyltin (TET)-a compound inducing myelin vacuolization and brain oedema-with Ca(2+) homoeostasis and actin polymerization results in an adverse effect on neurotransmitter release in different neural cell lines. However, another neurotoxic organotin compound (trimethyltin, TMT) induces apoptosis in neural cells through the activation of a Ca(2+)-dependent pathway. In conclusion, the identification of the key changes in actin and Ca(2+) homoeostasis could give early information on neural cell perturbation resulting in altered functionality or even cell death.

Nuclear factor-kappaB is activated by hyperoxia but does not protect from cell death

Oxidative insults that are lethal to epithelial cells kill either via apoptosis or necrosis. Nuclear factor-kappaB (NF-kappaB) is a redox-sensitive transcription factor that is activated by oxidative insult, and NF-kappaB activation can protect cells from apoptosis. To test if NF-kappaB can protect from necrotic cell death caused by high levels of molecular O2 (hyperoxia), we exposed human alveolar epithelial (A549) cells to hyperoxia. NF-kappaB was shown to be activated and was translocated to the nucleus within minutes. Nuclear translocation persisted over the course of several days, and the levels of NF-kappaB protein and mRNA increased as well. In hyperoxia, NF-kappaB regulation was independent of mitogen-activated protein kinase (MAPK). In sharp contrast, there was neither nuclear translocation of NF-kappaB nor any increase in expression after exposure to H2O2 at a concentration where this oxidant induces both MAPK and widespread apoptosis. Despite the activation and increased expression of NF-kappaB in hyperoxia, this oxidant remained lethal to the cells. These observations confirm the notion that apoptosis occurs in the absence of NF-kappaB activation but indicate that protection from cell death by NF-kappaB is probably limited to apoptosis.

Cellular oxygen toxicity. Oxidant injury without apoptosis

All forms of aerobic life are faced with the threat of oxidation from molecular oxygen (O2) and have evolved antioxidant defenses to cope with this potential problem. However, cellular antioxidants can become overwhelmed by oxidative insults, including supraphysiologic concentrations of O2 (hyperoxia). Oxidative cell injury involves the modification of cellular macromolecules by reactive oxygen intermediates (ROI), often leading to cell death. O2 therapy, which is a widely used component of life-saving intensive care, can cause lung injury. It is generally thought that hyperoxia injures cells by virtue of the accumulation of toxic levels of ROI, including H2O2 and the superoxide anion (O2-), which are not adequately scavenged by endogenous antioxidant defenses. These oxidants are cytotoxic and have been shown to kill cells via apoptosis, or programmed cell death. If hyperoxia-induced cell death is a result of increased ROI, then O2 toxicity should kill cells via apoptosis. We studied cultured epithelial cells in 95% O2 and assayed apoptosis using a DNA-binding fluorescent dye, in situ end-labeling of DNA, and electron microscopy. Using all approaches we found that hyperoxia kills cells via necrosis, not apoptosis. In contrast, lethal concentrations of either H2O2 or O2- cause apoptosis. Paradoxically, apoptosis is a prominent event in the lungs of animals injured by breathing 100% O2. These data indicate that O2 toxicity is somewhat distinct from other forms of oxidative injury and suggest that apoptosis in vivo is not a direct effect of O2.