JoVE Journal > Immunology and Infection
Summary
Abstract
Introduction
Protocol
Results
Discussion
Disclosures
Acknowledgements
Materials
References
Automatic Translation
Please note that all translations are automatically generated. Click here for the English version.
Immunology and Infection

斑马鱼作为一种模型来评估亚硝酸盐的潜在致畸

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

Summary

接触致畸可能导致出生缺陷。斑马鱼是确定的化学物质的致畸潜在有用的。我们通过暴露胚胎各级亚硝酸盐,并且也在曝光不同的时间证明斑马鱼的效用。我们表明,亚硝酸盐可能是有毒的,并导致严重的发育缺陷。

Abstract

在环境中的高硝酸盐水平可能导致在人体中的先天性缺陷或流产。据推测,这是由于硝酸根的由肠道和唾液细菌转化为亚硝酸盐。然而,在其他哺乳动物的研究中,高亚硝酸盐的含量不导致出生缺陷,尽管它们可能会导致差的生殖结局。因此,亚硝酸盐的致畸潜在不明确。这将是有脊椎动物模型系统轻松评估亚硝酸盐或任何其他感兴趣的化学物质的致畸作用非常有用。这里,我们证明斑马鱼( 斑马鱼 )的工具来筛选毒性和胚胎缺陷化合物。斑马鱼胚胎受精外,并有快速发展,使他们致畸研究的一个很好的模式。我们表明,增加曝光时间以负亚硝酸盐影响生存。增加亚硝酸盐的浓度也有不利影响的生存,而硝酸盐没有。对于胚胎塔ŧ生存亚硝酸盐暴露,可能会出现各种缺陷,包括心包和卵黄囊水肿,鱼鳔noninflation和颅面畸形。我们的结果表明,该斑马鱼是研究亚硝酸盐的致畸电位的方便的系统。这种方法可以容易地适用于测试其他化学品的早期脊椎动物发育的影响。

Introduction

畸变是由造成永久性的结构和功能异常,生长发育迟缓,或流产情况严重扰乱了1胚胎或胎儿的正常发育过程。它可以通过某些天然剂(致畸),其与胚胎发育以多种方式2干扰引起的。在人的胎儿发育,共同致畸如辐射,感染剂,有毒金属,和有机化工已报道引起epicanthic褶皱(弯曲手指或脚趾)通过形态发生错误的缺陷(皮肤褶皱中的上眼睑)和五指1。

理解致畸的分子机制是朝着显影治疗和预防的第一步。一些脊椎动物模型如非洲爪蛙( 爪蟾 )和斑马鱼( 斑马鱼 )已被用来确定受terat的分子途径ogens。以前的研究已经使用斑马鱼作为流行病学,毒理学和致畸3-7的典范。 Scholz 。考虑斑马鱼作为“金标准”环境毒性评估。这是由于在某种程度上,对斑马鱼胚胎,这允许它发生8研究者形象化发育缺陷的透明度。人类基因的大约70%的具有在斑马鱼直系同源物,使得斑马鱼的理想脊椎动物模型研究人类的缺陷9。

一些流行病学研究表明,硝酸盐和亚硝酸盐,通常存在于农场的食物和水,与出生缺陷或自然流产10,11相关联,而其它研究不支持此关联12。硝酸盐(NO 3 – )和亚硝酸根(NO 2 – )是在土壤和水自然存在。它们是氮植物的来源,并且是n的一部分itrogen周期13。食物,如绿豆,胡萝卜,南瓜,菠菜,甜菜,并从使用化肥高硝酸盐农场显著增强硝酸盐和亚硝酸盐7的水平。从高硝酸盐的食物和鱼高硝酸盐水(主要是从土壤中流失30)喂牛奶会导致人体消耗大量的硝酸盐和亚硝酸盐14。硝酸盐和亚硝酸盐也常用于食品保鲜,这大大增加了由人类12摄取的量使用。

硝酸盐和亚硝酸盐的最佳水平像血管稳态和功能,神经传递及免疫宿主防御机制13-15生理过程中发挥根本性的作用。然而,暴露于高水平的硝酸盐和亚硝酸盐的可能导致不利的影响,特别是在婴儿和儿童16。摄入硝酸盐是由微生物,并在第进一步转化为亚硝酸盐在口腔中由肠道菌群16 E胃肠道。

硝酸盐使婴儿在蓝色婴儿综合症高风险的血红蛋白氧化成高铁血红蛋白,其携氧能力18损害血红蛋白。这导致皮肤的蓝色延伸到在更严重的情况下外周组织。在其他症状组织结果抑制氧化,最严重导致昏迷和死亡19,20。类似症状中的婴儿和成人在较高浓度的硝酸21的观察。由于紫绀,头痛亚硝酸盐中毒导致高铁血红蛋白成人水平升高,呼吸障碍31,死如不及时治疗,由于涉及重要组织缺氧32,33并发症。

硝酸盐在较高水平的摄入也可以导致各种健康并发症。儿童糖尿病,反复腹泻和反复呼吸道感染患儿已与硝酸盐摄入11,17,22相连。长期暴露于高水平硝酸盐与排尿和脾出血有关。急性高剂量照射硝酸盐可导致像腹痛,肌肉无力,便血和尿,昏厥,甚至死亡11医疗条件范围广泛。在较高水平产前暴露于硝酸一直与神经管缺陷的肌肉骨骼相关的11。

最近的一份报告显示,治疗斑马鱼胚胎与亚导致卵黄囊水肿,颅面和轴向畸形和鱼鳔noninflation 5。在这项研究中,我们证明了治疗斑马鱼的胚胎与硝酸盐和亚硝酸盐,以确定他们的致畸潜力的方法。胚胎在不同浓度和不同的时间长度暴露于亚硝酸盐。乙醇用作阳性对照,因为它是一个既定的致畸23。 Ø乌尔法表明,两种高浓度,长的曝光时间为亚硝酸盐不利于生存和导致各种表型,从轻度(水肿),重度(毛发育缺陷)。因此,斑马鱼是直接在探索胚胎硝酸盐和亚硝酸盐的潜在致畸作用,以补充流行病学研究的有用模型。

Protocol

在本协议中所描述的程序进行的机构动物护理和使用委员会在宾夕法尼亚州印第安纳大学的批准。 1.收获胚胎在28.5℃,pH为7,500-1,500μS之间电导率维持斑马鱼,和14小时光照和10小时黑暗的24的光/暗周期。使用野生型菌株,如涂,AB或TU / AB混合。不同的菌株可能有不同的反应化学处理25。 建立了鱼通过鱼加水系统到配合坦克交配收获鸡蛋的前一?…

Representative Results

曝光至300mM乙醇22小时对存活率(数据未示出),与以前的报告5,23,26一致没有影响。这是意料之中的,因为乙醇是一种已知的致畸,并担任阳性对照。观测到的表型包括心包水肿,鱼鳔noninflation(图1),颅面畸形和发育迟缓(数据未示出)。 用亚硝酸盐处理导致轻度至对生存造成严重影响,这取决于曝光?…

Discussion

这里介绍的方法证明了评估硝酸盐和亚硝酸盐的潜在致畸斑马鱼的效用。相比其他脊椎动物斑马鱼有优势,包括高繁殖力,体外受精,光学透明,快速发展。缺乏色素沉着(如斑马鱼的Casper 36)可用的突变体也有助于增强内脏器官的知名度。它也很容易产生与报告基因的转基因斑马鱼便于分析在活鱼37。因为斑马鱼基因组与人类保守的,从他们的研究中获得的信息可以导致在人中<…

Disclosures

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
DOWNLOAD MATERIALS LIST

References

  1. Gilbert-Barness, E. Teratogenic causes of malformations. Ann Clin Lab Sci. 40 (2), 99-114 (2010).
  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).
  3. Lin, S., Zhao, Y., Nel, A. E. Zebrafish: an in vivo model for nano EHS studies. Small. 9 (9-10), 1608-1618 (2013).
  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).
  7. Jensen, F. B. Nitric oxide formation from nitrite in zebrafish. J Exp Biol. 210, 3387-3394 (2007).
  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).
  26. . . Methods for chemical analysis of water and wastes. , (1983).
  27. Loucks, E., Ahlgren, S. Assessing teratogenic changes in a zebrafish model of fetal alcohol exposure. J Vis Exp. (61), (2012).
  28. Addiscott, T. M. Fertilizers and nitrate leaching. Agricultural Chemicals and the Environment, Issues in Environmental Science and Technology. , 1-26 (1996).
  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).
  33. Kimmel, C. B., Ballard, W. W., Kimmel, S. R., Ullmann, B., Schilling, T. F. Stages of embryonic development of the zebrafish. Dev Dyn. 203 (3), 253-310 (1995).
  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).
  35. Tsang, M. Zebrafish: A tool for chemical screens. Birth Defects Res C Embryo Today. 90 (3), 185-192 (2010).

Tags

ZebrafishDevelopmental ToxicologyTeratogenic EffectsNitriteEmbryonic DevelopmentExternal DevelopmentWild-type StrainsMatingFertilizationEthanolSodium Nitrite
check_url/53615?article_type=t

Play Video
PDF
DOI
DOWNLOAD MATERIALS LIST
Cite This Article
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).
Download Citation
Reprints and Permissions

View Video

To prove you're not a robot, please enter the text in the image below

CAPTCHA Image
Play CAPTCHA Audio
Refresh Image