JoVE Journal > Immunology and Infection
Summary
Abstract
Introduction
Protocol
Resultados
Discussion
Divulgaciones
Acknowledgements
Materials
Referencias
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Inmunología y contagio

Zebrafish as a Model to Assess the Teratogenic Potential of Nitrite

Published: February 16, 2016
doi:
10.3791/53615
, , , ,
1Department of Biology,Indiana University of Pennsylvania

Summary

Exposure to teratogens may cause birth defects. Zebrafish are useful for determining the teratogenic potential of chemicals. We demonstrate the utility of zebrafish by exposing embryos to various levels of nitrite and also at different times of exposure. We show that nitrite can be toxic and cause severe developmental defects.

Abstract

High nitrate levels in the environment may result in congenital defects or miscarriages in humans. Presumably, this is due to the conversion of nitrate to nitrite by gut and salivary bacteria. However, in other mammalian studies, high nitrite levels do not cause birth defects, although they can lead to poor reproductive outcomes. Thus, the teratogenic potential of nitrite is not clear. It would be useful to have a vertebrate model system to easily assess teratogenic effects of nitrite or any other chemical of interest. Here, we demonstrate the utility of zebrafish (Danio rerio) to screen compounds for toxicity and embryonic defects. Zebrafish embryos are fertilized externally and have rapid development, making them a good model for teratogenic studies. We show that increasing the time of exposure to nitrite negatively affects survival. Increasing the concentration of nitrite also adversely affects survival, whereas nitrate does not. For embryos that survive nitrite exposure, various defects can occur, including pericardial and yolk sac edema, swim bladder noninflation, and craniofacial malformation. Our results indicate that the zebrafish is a convenient system for studying the teratogenic potential of nitrite. This approach can easily be adapted to test other chemicals for their effects on early vertebrate development.

Introduction

Teratogenesis is a process that disrupts the normal development of an embryo or fetus by causing permanent structural and functional abnormalities, growth retardation, or miscarriage in severe cases1. It can be caused by certain natural agents (teratogens), which interfere with embryonic development in multiple ways2. During human fetal development, common teratogens such as radiation, infectious agents, toxic metals, and organic chemicals have been reported to cause defects in epicanthic folds (the skin fold in the upper eye lid) and clinodactyly (curved finger or toe) through morphogenetic errors1.

Understanding the molecular mechanism of teratogenesis is the first step towards developing treatment and prevention. Several vertebrate models such as the African clawed frog (Xenopus laevis) and zebrafish (Danio rerio) have been used to determine the molecular pathways affected by teratogens. Previous studies have used zebrafish as a model for epidemiology, toxicology and teratogenesis3-7. Scholz et al. considered zebrafish as a "gold standard" for environmental toxicity assessment. This is due, in part, to the transparency of the zebrafish embryo, which allows researchers to visualize the developmental defect as it occurs8. Approximately 70% of human genes have orthologues in zebrafish, making zebrafish a desirable vertebrate model for studying human defects9.

Some epidemiological studies have suggested that nitrate and nitrite, commonly present in farm foods and water, are associated with birth defects or spontaneous abortions10,11, while other studies do not support this association12. Nitrate (NO3) and nitrite (NO2) are naturally present in soil and water. They are a source of nitrogen for plants and are a part of the nitrogen cycle13. Foods such as green beans, carrots, squash, spinach, and beets from farms that use fertilizers high in nitrate have significantly augmented levels of nitrate and nitrite7. Milk from cows fed with high nitrate foods and fish in high nitrate water (mainly from soil runoff30) can lead to humans consuming large amounts of nitrate and nitrite14. Nitrate and nitrite are also commonly used in food preservation, which dramatically increases the amount ingested by humans12.

Optimal levels of nitrate and nitrite play fundamental roles in physiological processes like vascular homeostasis and function, neurotransmission and immunological host defense mechanisms13-15. However, exposure to high levels of nitrate and nitrite may lead to adverse effects, especially in infants and children16. Ingested nitrate is further converted to nitrite in the oral cavity by microflora and in the gastrointestinal tract by intestinal microflora17.

Nitrate puts infants at a high risk for blue baby syndrome by oxidation of hemoglobin to methemoglobin, impairing hemoglobin from its oxygen carrying ability18. This results in the blue color of skin that extends to peripheral tissues in more severe cases. Inhibited oxygenation of tissues results in other symptoms, most severely leading to coma and death19,20. Similar symptoms are observed in babies and adults at higher concentrations of nitrate21. Elevated levels of methemoglobin in adults due to nitrite poisoning results in cyanosis, headache, breathing disorders31, and death if not treated due to complications related to vital tissue hypoxia32,33.

Nitrate ingested at higher levels can also result in various health complications. Childhood diabetes, recurrent diarrhea, and recurrent respiratory tract infections in children have been linked with high nitrate intake11,17,22. Chronic exposure to a high level of nitrate is associated with urination and spleen hemorrhaging. Acute high dose exposure to nitrates can lead to a wide spectrum of medical conditions like abdominal pain, muscle weakness, blood in stools and urine, fainting, and death11. Prenatal exposure to nitrate at high levels has been associated with neural tube and musculoskeletal defect11.

A recent report showed that treating zebrafish embryos with nitrite led to yolk sac edema, craniofacial and axial malformations, and swim bladder noninflation5. In this study, we demonstrate a method for treating zebrafish embryos with nitrate and nitrite to determine their teratogenic potential. Embryos were exposed to nitrite at different concentrations and different lengths of time. Ethanol was used as a positive control, since it is an established teratogen23. Our method showed that both high concentrations and long exposure times to nitrite were detrimental to survival and resulted in various phenotypes, ranging from mild (edema) to severe (gross developmental defects). Therefore, the zebrafish is a useful model for directly exploring the potential teratogenic effects of nitrate and nitrite on embryos to complement epidemiological studies.

Protocol

The procedures described in this protocol were approved by the Institutional Animal Care and Use Committee at the Indiana University of Pennsylvania. 1. Harvest Embryos Maintain zebrafish at 28.5 °C, pH 7, conductivity between 500-1,500 µS, and a light/dark cycle of 14 hr light and 10 hr dark24. Use wild-type strains such as Tü, AB or Tü/AB hybrid. Different strains may respond differently to chemical treatment25. Set up the fish …

Representative Results

Exposure to 300 mM ethanol for 22 hr had no effect on survival (data not shown), consistent with previous reports5,23,26. This is expected, as ethanol is a known teratogen and served as a positive control. Observed phenotypes included pericardial edema, swim bladder noninflation (Figure 1), craniofacial defects, and developmental delay (data not shown). Treatment with nitrite resulted in mild to sever…

Discussion

The method described here demonstrates the utility of zebrafish in assessing the teratogenic potential of nitrite and nitrate. Compared to other vertebrates, zebrafish have advantages that include high fecundity, external fertilization, optical transparency, and rapid development. Available mutants that lack pigmentation (such as the casper zebrafish36) also help to enhance visibility of internal organs. It is also easy to generate transgenic zebrafish with reporter genes to facilitate analysis in live fish<su…

Divulgaciones

The authors have nothing to disclose.

Acknowledgements

VK was funded by grants from the IUP Department of Biology and School of Graduate Studies and Research (Graduate Student Professional Development). CQD and TWS were supported by the IUP School of Graduate Studies and Research (Faculty Publication Costs/Incidental Research Expenses). We also thank members of the Diep laboratory for maintaining the zebrafish facility.

Materials

DREL/2010 instrument Hach 26700-03
Ethanol Sigma-Aldrich E7023
KIMAX glass Petri Dish VWR 89001-244
MS-222 Sigma-Aldrich E10521
NitraVer 5 Nitrate Reagent Hach 14034-46
NitriVer 3 Nitrite Reagent Hach 14065-99
Parafilm Fisher Scientific 3-374-10
Paraformaldehyde Sigma-Aldrich 158127
S6E stereomicroscope Leica 10446294
Sodium nitrate Fisher Scientific S343
Sodium nitrite Fisher Scientific S347
Transfer pipets Laboratory Products Sales L320072
Glass vials Fisher Scientific 03-338B
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Referencias

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  2. Brent, R. L. The cause and prevention of human birth defects: What have we learned in the past 50 years. Con Anom. 41 (1), 3-21 (2001).
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  4. Pamanji, R., et al. Toxicity effects of profenofos on embryonic and larval development of zebrafish (Danio rerio). Environ Toxicol Pharmacol. 39 (2), 887-897 (2015).
  5. Simmons, A. E., Karimi, I., Talwar, M., Simmons, T. W. Effects of nitrite on development of embryos and early larval stages of the zebrafish (Danio rerio). Zebrafish. 9 (4), 200-206 (2012).
  6. Mantecca, P., et al. Toxicity Evaluation of a New Zn-Doped CuO Nanocomposite With Highly Effective Antibacterial Properties. Toxicol Sci. , (2015).
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  8. Scholz, S., et al. The zebrafish embryo model in environmental risk assessment–applications beyond acute toxicity testing). Environ Sci Pollut Res Int. 15 (5), 394-404 (2008).
  9. Howe, K., et al. The zebrafish reference genome sequence and its relationship to the human genome. Nature. 496 (7446), 498-503 (2013).
  10. CDC. Spontaneous abortions possibly related to ingestion of nitrate-contaminated well water–LaGrange County, Indiana, 1991-1994. MMWR Morb Mortal Wkly Rep. 45 (26), 569-572 (1996).
  11. Brender, J. D., et al. Prenatal nitrate intake from drinking water and selected birth defects in offspring of participants in the national birth defects prevention study. Environ Health Perspect. 121 (9), 1083-1089 (2013).
  12. Huber, J. C., et al. Maternal dietary intake of nitrates, nitrites and nitrosamines and selected birth defects in offspring: a case-control study. Nutr J. 12, 34 (2013).
  13. Phillips, W. E. Naturally occurring nitrate and nitrite in foods in relation to infant methaemoglobinaemia. Food Cosmet Toxicol. 9 (2), 219-228 (1971).
  14. Moncada, S., Palmer, R. M., Higgs, E. A. Nitric oxide: physiology, pathophysiology, and pharmacology. Pharmacol Rev. 43 (2), 109-142 (1991).
  15. Gladwin, M. T., Crawford, J. H., Patel, R. P. The biochemistry of nitric oxide, nitrite, and hemoglobin: role in blood flow regulation. Free Radic Biol Med. 36 (6), 707-717 (2004).
  16. Gupta, S. K., et al. Recurrent acute respiratory tract infections in areas with high nitrate concentrations in drinking water. Environ Health Perspect. 108 (4), 363-366 (2000).
  17. Kross, B. C., Ayebo, A. D., Fuortes, L. J. Methemoglobinemia: nitrate toxicity in rural America. Am Fam Physician. 46 (1), 183-188 (1992).
  18. Greer, F. R., Shannon, M. Infant methemoglobinemia: the role of dietary nitrate in food and water. Pediatrics. 116 (3), 784-786 (2005).
  19. Sanchez-Echaniz, J., Benito-Fernandez, J., Mintegui-Raso, S. Methemoglobinemia and consumption of vegetables in infants. Pediatrics. 107 (5), 1024-1028 (2001).
  20. Virtanen, S. M., et al. Nitrate and nitrite intake and the risk for type 1 diabetes in Finnish children. Childhood Diabetes in Finland Study Group. Diabet Med. 11 (7), 656-662 (1994).
  21. Reimers, M. J., Flockton, A. R., Tanguay, R. L. Ethanol- and acetaldehyde-mediated developmental toxicity in zebrafish. Neurotoxicol Teratol. 26 (6), 769-781 (2004).
  22. Westerfield, M. . The zebrafish book: A guide for the laboratory use of zebrafish (Danio rerio). , (2007).
  23. Loucks, E., Carvan, M. J. Strain-dependent effects of developmental ethanol exposure in zebrafish. Neurotoxicol Teratol. 26 (6), 745-755 (2004).
  24. Bilotta, J., Barnett, J. A., Hancock, L., Saszik, S. Ethanol exposure alters zebrafish development: a novel model of fetal alcohol syndrome. Neurotoxicol Teratol. 26 (2), 737-743 (2004).
  25. Li, J., Jia, W., Zhao, Q. Excessive nitrite affects zebrafish valvulogenesis through yielding too much NO signaling. PLoS One. 9 (3), e92728 (2014).
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  29. Su, Y. F., Lu, L. H., Hsu, T. H., Chang, S. L., Lin, R. T. Successful treatment of methemoglobinemia in an elderly couple with severe cyanosis: two case reports. Journal of Medical Case Reports. 6 (290), (2012).
  30. Harvey, M., Cave, G., Chanwai, G. Fatal methaemoglobinaemia induced by self-poisoning with sodium nitrite. Emergency Medicine Australasia. 22, 463-465 (2010).
  31. Nishiguchi, M., Nushida, H., Okudaira, N., Nishio, H. An autopsy case of fatal methemoglobinemia due to ingestion of sodium. Forensic Research. 6, (2015).
  32. Avdesh, A., Chen, M., Martin-Iverson, M. T., Mondal, A., Ong, D., Rainey-Smith, S., et al. Regular Care and Maintenance of a Zebrafish (Danio rerio) Laboratory: An Introduction. J. Vis. Exp. (69), (2012).
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  34. White, R. M., et al. Transparent adult zebrafish as a tool for in vivo transplantation analysis. Cell Stem Cell. 2 (2), 183-189 (2008).
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Tags

ZebrafishDevelopmental ToxicologyTeratogenic EffectsNitriteEmbryonic DevelopmentExternal DevelopmentWild-type StrainsMatingFertilizationEthanolSodium Nitrite

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Keshari, V., Adeeb, B., Simmons, A. E., Simmons, T. W., Diep, C. Q. Zebrafish as a Model to Assess the Teratogenic Potential of Nitrite. J. Vis. Exp. (108), e53615, doi:10.3791/53615 (2016).
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