Adverse effect of tannery waste leachates in transgenic <i>Drosophila melanogaster</i>: role of ROS in modulation of Hsp70, oxidative stress and apoptosis

Siddique, Hifzur R.; Gupta, Subash C.; Mitra, Kalyan; Bajpai, V.K.; Mathur, Neeraj; Murthy, Ramesh; Saxena, D. K.; Chowdhuri, D. Kar

doi:10.1002/jat.1332

Cited by 35 publications

(9 citation statements)

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“…Although elevated temperature is the classic inducer of heat shock proteins, it is now clear that a variety of other stresses including pesticides, heavy metals, solvents and effluents can induce heat shock proteins (Stringham et al 1992;Stringham and Candido 1994;Guven and de Pomerai 1995;Candido and Jones 1996;Mutwakil et al 1997;Chowdhuri et al 1999;Gupta et al 2005a,b;Nazir et al 2006;Gupta et al 2007a,b;Siddique et al 2007Siddique et al , 2008Siddique et al , 2009Bhargav et al 2008;Singh et al 2009). Under stress conditions, the newly synthesized stress proteins play an essential role in maintaining cellular homeostasis by assisting correct folding of nascent and stressaccumulated misfolded proteins, preventing protein aggregation or promoting selective degradation of misfolded or denatured proteins (Schlesinger 1990;Morimoto 1993;Sikora and Grzesiuk 2007;Saluja and Dudeja 2008).…”

Section: Heat Shock Responsementioning

confidence: 95%

“…hsp70, hsp83 and hsp26 tagged with reporter genes like β-galactosidase or GFP have been used to detect cellular stress caused by environmental chemicals or their mixtures. The assays designed allow for quantification of the extent of stress gene expression following environmental chemicals exposure, suggesting the extent of cellular toxicity inflicted by the chemicals (Chowdhuri et al 1999;Gupta et al 2005aGupta et al ,b, 2007aNazir et al 2006;Siddique et al 2007Siddique et al , 2008Siddique et al , 2009Bhargav et al 2008;Singh et al 2009). Another model organism, Caenorhabditis elegans, with both its hsp70 and hsp16 promoters tagged with the lacZ reporter gene, has been used to a great extent to examine the cellular toxicity of heavy metals or their mixtures (Stringham et al 1992;Stringham and Candido 1994;Guven and de Pomerai 1995;Candido and Jones 1996).…”

Section: Genetically Engineered Organismsmentioning

confidence: 98%

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Heat shock proteins in toxicology: How close and how far?

et al. 2010

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Section: Heat Shock Responsementioning

confidence: 95%

Section: Genetically Engineered Organismsmentioning

confidence: 98%

Heat shock proteins in toxicology: How close and how far?

et al. 2010

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“…Drosophila has hence found extensive use as a model organism in various fields including toxicology testing. [33][34][35][36][37][38] Concerns have been raised about the ethics and use of animals for toxicology research and testing, and emphasis now is given to the use of alternatives to mammals in research as well as education. The European Centre for the Validation of Alternative Methods (ECVAM) promotes scientific and regulatory acceptance of alternative methods for reducing, refining or replacing the use of laboratory animals 39,40 and recommends D. melanogaster as an alternative to animal models for testing and research.…”

Section: The Alkaline Comet Assay In Drosophila Melanogastermentioning

confidence: 99%

Detection of DNA Damage in Drosophila and Mouse

Dhawan

Bajpayee

Parmar

2009

The Comet Assay in Toxicology

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The single-cell gel electrophoresis (SCGE)/Comet assay has, since its inception, been widely used for the simple, sensitive and rapid determination of DNA damage and repair, quantitatively as well as qualitatively in individual cell populations. 1 Comet is the perfect acronym for credible observation and measurement of exposure to toxicants. The assay combines the simplicity of biochemical techniques for detecting DNA single-strand breaks with the single-cell approach of cytogenetic assays. The advantages of the assay include its need for small numbers of cells per sample (o10 000), collection of data at the level of the individual cell, allowing for robust statistical analyses, its sensitivity for detecting quantitative and qualitative DNA damage. The assay has versatility in detecting DNA single-and double-strand breaks, oxidative DNA damage, crosslinks as well as apoptosis and necrosis in proliferating or nonproliferating cells, and has thus gained popularity as a test for genetic toxicology. Single cells obtained from various organisms ranging from simple bacteria (prokaryotes) to complex humans (eukaryotes) have been used to monitor in vitro or in vivo genotoxicity of chemicals. 2 It has also been used Issues in Toxicology No 5

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“…Hsp70 is a highly responsive stress gene with fairly low specificity with respect to environmental stressor. Nonetheless, this reporter has served as a rapid readout of toxicity in larval and adult feeding assays of specific organophosphates as well as complex mixtures of industrial leachates [43,92]. In addition, immunohistochemical analysis of the reporter reveals tissue specific patterns of toxic insult that expose sex-linked differences in response [43].…”

Section: Examples Of Measurable Endpoints In Drosophila Toxicologymentioning

confidence: 99%

“…Reporter gene response could be monitored at any stage of development using modes of delivery summarized in Figure 1. For example, a simple assay would involve feeding E(spl)-lacZ larvae on media containing various concentrations or compositions of agents for a defined time and determining β-galactosidase levels in homogenates of larvae by standard chemical substrate assays [92]. Through optimization of larval sample handling techniques this approach could be adapted to a multi-well format for high throughput.…”

Section: Drosophotoxicology For the Futurementioning

confidence: 99%

Drosophotoxicology: The growing potential for Drosophila in neurotoxicology

Rand

2010

Neurotoxicology and Teratology

190

104

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Understanding neurotoxic mechanisms is a challenge of deciphering which genes and gene products in the developing or mature nervous system are targeted for disruption by chemicals we encounter in our environment. Our understanding of nervous system development and physiology is highly advanced due in large part to studies conducted in simple non-mammalian models. The paucity of toxicological data for the more than 80,000 chemicals in commercial use today, and the approximately 2,000 new chemicals introduced each year, make development of sensitive and rapid assays to screen for neurotoxicity paramount. In this article I advocate the use of Drosophila in the modern regimen of toxicological testing, emphasizing its unique attributes for assaying neurodevelopment and behavior. Features of the Drosophila model are reviewed and a generalized overall scheme for its use in toxicology is presented. Examples of where the fly has proven fruitful in evaluating common toxicants in our environment are also highlighted. Attention is drawn to three areas where development and application of the fly model might benefit toxicology the most: 1) optimizing sensitive endpoints for pathway-specific screening, 2) accommodating high throughput demands for analysis of chemical toxicant libraries, 3) optimizing genetic and molecular protocols for more rapid identification toxicant-by-gene interactions. While there are shortcomings in the Drosophila model, which exclude it from effective toxicological testing it certain arenas, conservation of fundamental cellular and developmental mechanisms between flies and man are extensive enough to warrant a central role for the Drosophila model in toxicological testing of today.

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Adverse effect of tannery waste leachates in transgenic Drosophila melanogaster: role of ROS in modulation of Hsp70, oxidative stress and apoptosis

Cited by 35 publications

References 53 publications

Heat shock proteins in toxicology: How close and how far?

Heat shock proteins in toxicology: How close and how far?

Detection of DNA Damage in Drosophila and Mouse

Drosophotoxicology: The growing potential for Drosophila in neurotoxicology

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