DNA Damage in Bat Blood Leukocytes Using a Chromatin Dispersion Test (CDT): Biomarker of Environmental Genotoxicity.

Environmental pollutants produce adverse effects on organisms and ecosystems. Biomonitoring and biomarkers offer a reasonable approach to make these assessments. Induced genetic changes can be using as a biomarker in organisms that react to a given compound in the ecosystem. Monitoring environmental genotoxicity necessitates the choice of model animals known as "sentinels or biological monitors" and the suitability of validated tests for DNA damage evaluation. We aimed to estimate the DNA damage produced by thermal stress in the leukocytes of the Mexican free-tailed bat (Tadarida brasiliensis). The DNA damage in bat leukocytes exposed to different temperatures (35 °C, 45 °C, and 55 °C) was evaluated by the adapted chromatin dispersion test (CDT) and the results were confirmed by the alkaline comet test. The CDT permitted a clear representation of leukocytes with fragmented DNA and of nonfragmented DNA. In addition, we detected nuclear anomalies in relation to cell death cellular swelling, nuclear fragmentation, and chromatin lysis. The alkaline comet assay revealed that the halos of diffuse chromatin include fragmented DNA. The assay of the method employing the CDT is well established, precise, and cost-effective for the routine quantitative analysis of DNA damage on the effect of the leukocytes of bats exposed to thermal stress. This could also apply as a sensitive screening tool for the evaluation of genotoxicity in environmental protection programs.

Metal Contents in Feathers from Birds (Rhynchopsitta terrisi, and Columba livia) with Different Ecological Niches.

The metal contaminants can be utilized as an ecological tool to analyze niche partition in birds. As environmental contamination biological indicators, essential (Zn, Cu, and Cr) and non-essential (Pb and Cd) metals in the flight feathers of the Maroon-fronted Parrot and Pigeon with different ecological niches were assessed. The feathers of the parrot were gathered at a national park (Parque Nacional Cumbres de Monterrey) and the feathers of pigeons were collected at an urban site, that is, the city of Monterrey, Mexico. An atomic absorption spectrophotometer was used to establish the concentration of metals in the feathers. Zn, Cu, Cr, Pb, and Cd were detected in the two studied samples. The results obtained in this study exhibited an increase in metal concentrations in pigeon feathers with respect to parrot feathers. In conclusion, employing parrot and pigeon feathers comprises an important tool to track trace-metal occurrence in the environment and metal accumulation in birds. This information is crucial to possess in order to minimize exposure to essential metals in species of wild birds with different ecological niches.

Thermal stress induces pyknosis in pigeon erythrocytes: digital image analysis.

Pyknosis or hypercondensation of chromatin is informative in the understanding of nucleosomal packing in translationally inactive chromatin and in the compression of cell death. However, mechanisms that result in the formation of avian erythrocytes with variant nuclear morphology are poorly understood.Purpose: In this work, we evaluated pyknosis in pigeon erythrocytes treated with thermal stress using Digital Image Analysis (DIA).Materials and methods: Pigeon erythrocytes were treated at thermal stress (33 °C, 43 °C, and 53 °C), and nuclear modifications were analyzed by DIA.Results: Our results showed that thermal stress induced DNA condensation. Based on DNA fluorescent staining and compaction, four subclasses with progressively more pyknotic nuclei each could be distinguished. Alkaline comet assay showed that the presence of pyknotic nuclei was associated with the DNA fragmentation typical of apoptosis. DIA analysis showed a decrease of nuclear area and a significant increase of fluorescence intensity with respect to non-pyknotic nucleus. Additionally we observed nuclear dissolution events associated with swell and loose membrane integrity.Conclusion: These findings can contribute to the evaluation of health and metabolic status in diagnostic cytology, especially in neoplastic conditions and infection by microorganisms.

Evaluation of the genotoxic effect of heavy metals in pigeons from urban and rural habitat in Monterrey, Mexico, using the chromatin dispersion assay.

PURPOSE: Evaluate genotoxic effect of heavy metals on Pigeon Erythrocytes (PE) from urban and rural habitat (outside of the city) in Monterrey, Mexico, using the chromatin dispersion assay. MATERIALS AND METHODS: We quantified metals concentrations (Cd, Hg, Cu and Pb) in tail feathers of 22 pigeons from an urban and a rural site in northeastern Mexico. DNA damage in peripheral blood erythrocytes was measured by chromatin dispersion assay in 13 pigeon living in urban habitat and in nine living in rural habitat as the control. MicroNucleus (MN) test was used to confirm levels of DNA damage. RESULTS: Birds in urban habitat had highest concentrations in feathers for all the metallic elements analysed with respect to birds in rural habitat. Concentrations of Cu and Hg showed a significant increase (p < 0.05). Our results showed a significant increase of DNA damage in urban-habitat pigeons compared with that of pigeons in rural area. These results were confirmed by a MN test. CONCLUSIONS: Our preliminary findings demonstrate that PE examination via chromatin dispersion assay is a reliable, precise and inexpensive morphological bioassay for evaluating environmental genotoxicity associated with heavy metals. Further studies for evaluating the individual participation of contaminants in DNA damage are needed.

Detection of DNA damage in pigeon erythrocytes using a chromatin dispersion assay.

The monitoring of environmental genotoxicity requires the selection of model organisms as 'sentinels' as well as the development of sensitive and reliable tests for the assessment of DNA damage. The aims of this study were to quantify genomic DNA strand breakage in the erythrocytes of Columba livia induced by thermal stress using the modified chromatin dispersion test and to validate the results by alkaline comet assay and DNA breakage detection-fluorescence in situ hybridization (DBD-FISH). The chromatin dispersion test allowed for clear visualization of erythrocyte cells with DNA damage and of cells with no DNA damage. DNA damage increased significantly with increase in temperature. Additionally, we observed nuclear abnormalities associated with apoptosis, such as karyorrhexis (nuclear disintegration) and karyolysis (nuclear dissolution). These results were validated by alkaline comet assay and DBD-FISH. In conclusion, this procedure is a reliable, precise, and inexpensive morphological bioassay for routine quantitative analysis of DNA breakage in pigeon erythrocytes induced by thermal stress. This method could also be useful as a practical screening tool for genotoxicity testing in environmental care.

Evaluation of environmental genotoxicity by comet assay in Columba livia.

The concentrations of recognized or suspected genotoxic and carcinogenic agents found in the air of large cities and, in particular, developing countries, have raised concerns about the potential for chronic health effects in the populations exposed to them. The biomonitoring of environmental genotoxicity requires the selection of representative organisms as "sentinels," as well as the development of suitable and sensitive assays, such as those aimed at assessing DNA damage. The aim of this study was to evaluate DNA damage levels in erythrocytes from Columba livia living in the metropolitan area of Monterrey, Mexico, compared with control animals via comet assay, and to confirm the results via Micronuclei test (MN) and DNA breakage detection-fluorescence in situ hybridization (DBD-FISH). Our results showed a significant increase in DNA migration in animals from the area assayed compared with that observed in control animals sampled in non-contaminated areas. These results were confirmed by MN test and DBD-FISH. In conclusion, these observations confirm that the examination of erythrocytes from Columba livia via alkaline comet assay provides a sensitive and reliable end point for the detection of environmental genotoxicants.