维生素A缺乏致斑马鱼胚胎体节不对称及后脑图式形成异常

doi:10.3724/SP.J.1005.2012.01159

[an error occurred while processing this directive]

HEREDITAS ›› 2012, Vol. 34 ›› Issue (9): 1159-1164.doi: 10.3724/SP.J.1005.2012.01159

• en • Previous Articles Next Articles

Vitamin A deficiency causes asymmetric somitogenesis and abnormal hindbrain patterning in zebrafish embryos

CAO Sha-Sha, JIA Wen-Shuang, ZHAO Qing-Shun

MOE Key Laboratory of Model Animal for Disease Study, Model Animal Research Center, Nanjing University, Nanjing 210061, China

Received:2012-03-01 Revised:2012-07-16 Online:2012-09-20 Published:2012-09-25

Abstract

Abstract: Retinoic acid (RA) plays essential roles in vertebrate embryogenesis. However, vertebrates cannot synthesize RA de novo. They synthesize it by two oxidative steps, first converting the precursor vitamin A into retinal by retinol dehy-drogenase, and then oxidizing retinal into RA irreversibly by retinal dehydrogenase. It is known that vitamin A deficiency (VAD) causes Vitamin A Deficiency Syndrome in animals including quail, mouse, rat, and human. However, little is known about the effects of VAD on zebrafish embryogenesis. In this study, we obtained zebrafish VAD embryos from the zebrafish fed a retinoids-free diet. By analyzing the VAD embryos, we found that VAD caused asymmetric somitogenesis and abnor-mal hindbrain patterning in zebrafish embryos. However, the phenotype of defected hindbrain in VAD embryos was not as severe as that in the embryos in which aldh1a2, the major gene that is responsible for RA synthesis in zebrafish early development, was knocked down, or the embryos treated with 10 mmol/L DEAB (diethylaminobenzaldehyde, inhibitor of retinal dehydrogenases). Our results indicated that the VAD embryos were short of but not free of vitamin A, and they might also have a RA generation pathway independent of retinal dehydrogenase.

Key words: zebrafish, vitamin A deficiency, somitogenesis, hindbrain patterning

CAO Sha-Sha, JIA Wen-Shuang, ZHAO Qing-Shun. Vitamin A deficiency causes asymmetric somitogenesis and abnormal hindbrain patterning in zebrafish embryos[J]. HEREDITAS, 2012, 34(9): 1159-1164.

References

[1] Ross SA, McCaffery PJ, Drager UC, De Luca LM. Reti-noids in embryonal development. Physiol Rev, 2000, 80(3): 1021-1054.
[2] Duester G. Retinoic acid synthesis and signaling during early organogenesis. Cell, 2008, 134(6): 921-931.
[3] Zhao D, McCaffery P, Ivins KJ, Neve RL, Hogan P, Chin WW, Dräger UC. Molecular identification of a major retinoic-acid-synthesizing enzyme, a retinaldehyde-specific dehydrogenase. Eur J Biochem, 1996, 240(1): 15-22.
[4] Begemann G, Schilling TF, Rauch GJ, Geisler R, Ingham PW. The zebrafish neckless mutation reveals a requirement for raldh2 in mesodermal signals that pattern the hindbrain. Development, 2001, 128(16): 3081-3094.
[5] Niederreither K, McCaffery P, Dräger UC, Chambon P, Dollé P. Restricted expression and retinoic acid-induced downregulation of the retinaldehyde dehydrogenase type 2 (RALDH-2) gene during mouse development. Mech Dev, 1997, 62(1): 67-78.
[6] Niederreither K, Subbarayan V, Dollé P, Chambon P. Em-bryonic retinoic acid synthesis is essential for early mouse post-implantation development. Nat Genet, 1999, 21(4): 444-448.
[7] Vermot J, Gallego LJ, Fraulob V, Niederreither K, Chambon P, Dollé P. Retinoic acid controls the bilateral sym-metry of somite formation in the mouse embryo. Sci-ence, 2005, 308(5721): 563-566.
[8] Wilson JG, Roth CB, Warkany J. An analysis of the syn-drome of malformations induced by maternal vitamin a deficiency. Effects of restoration of vitamin A at various times during gestation. Am J Anat, 1953, 92(2): 189-217.
[9] Thompson JN, Howell JM, Pitt GAJ, Mclaughlin CI. The biological activity of retinoic acid in the domestic fowl and the effects of vitamin A deficiency on the chick em-bryo. Br J Nutr, 1969, 23(3): 471-490.
[10] Grandel H, Lun K, Rauch GJ, Rhinn M, Piotrowski T, Houart C, Sordino P, Kuchler AM, Schulte-Merker S, Geisler R, Holder N, Wilson SW, Brand M. Retinoic acid signalling in the zebrafish embryo is necessary during pre-segmentation stages to pattern the anterior-posterior axis of the CNS and to induce a pectoral fin bud. Development, 2002, 129(12): 2851-2865.
[11] Kawakami Y, Raya Á, Raya RM, Rodríguez-Esteban C, Belmonte JCI. Retinoic acid signalling links left-right asymmetric patterning and bilaterally symmetric somito-genesis in the zebrafish embryo. Nature, 2005, 435(7039): 165-171.
[12] Kimmel CB, Ballard WW, Kimmel SR, Ullmann B, Schil-ling TF. Stages of embryonic development of the zebrafish. Dev Dyn, 1995, 203(3): 253-310.
[13] Xu F, Li K, Tian M, Hu P, Song W, Chen J, Gao X, Zhao QS. N-CoR is required for patterning the anterior-posterior axis of zebrafish hindbrain by actively repressing retinoid signaling. Mech Dev, 2009, 126(10): 771-780.
[14] Gu XX, Xu F, Song WL, Wang X, Hu P, Yang YM, Gao X, Zhao QS. A novel cytochrome p450, zebrafish Cyp26D1, is involved in metabolism of all-trans retinoic acid. Mol Endocrinol, 2006, 20(7): 1661-1672.
[15] Liang D, Zhang M, Bao J, Zhang LQ, Xu XF, Gao X, Zhao QS. Expressions of Raldh3 and Raldh4 during zebrafish early development. Gene Expr Patterns, 2008, 8(4): 248-253.
[16] Molotkov A, Ghyselinck NB, Chambon P, Duester G. Op-posing actions of cellular retinol-binding protein and al-cohol dehydrogenase control the balance between retinol storage and degradation. Biochem J, 2004, 383(Pt 2): 295-302.
[17] Collins MD, Mao GE. Teratology of retinoids. Annu Rev Pharmacol Toxicol, 1999, 39(1): 399-430.
[18] Perz-Edwards A, Hardison NL, Linney E. Retinoic acid-mediated gene expression in transgenic reporter zebrafish. Dev Biol, 2001, 229(1): 89-101.
[19] Pittlik S, Domingues S, Meyer A, Begemann G. Expression of zebrafish aldh1a3 (raldh3) and absence of aldh1a1 in tel

Metrics

Comments

www.chinagene.cn
备案号：京ICP备09063187号

Vitamin A deficiency causes asymmetric somitogenesis and abnormal hindbrain patterning in zebrafish embryos

PDF (PC)

Knowledge

Abstract

Cite this article

share this article

References

Related Articles 15

Recommended Articles

Metrics

Comments

[1]	Kailun Li, Jingao Lu, Xiaohui Chen, Wenqing Zhang, Wei Liu. The role of the allantoin in promoting fracture healing in osteoclast-deficient zebrafish [J]. Hereditas(Beijing), 2023, 45(4): 341-353.
[2]	Jing’ao Lu, Chunyan Huang, Zhiyin Lin, Zheng Tang, Ning Ma, Zhibin Huang. The role of the cd99l2 gene on leukocyte interstitial migration in zebrafish [J]. Hereditas(Beijing), 2022, 44(9): 798-809.
[3]	Pengfei Zheng, Haibo Xie, Panpan Zhu, Chengtian Zhao. Distribution pattern of floor plate neurons in zebrafish [J]. Hereditas(Beijing), 2022, 44(6): 510-520.
[4]	Tingting Zhang, Feng Liu. Study on a detection method of protein tyrosine sulfation modification in zebrafish [J]. Hereditas(Beijing), 2022, 44(2): 178-186.
[5]	Tingting Jia, Lei Lei, Xinyuan Wu, Shunyou Cai, Yixuan Chen, Yu Xue. Study on the mechanism of metformin on zebrafish skeletal development and damage repair [J]. Hereditas(Beijing), 2022, 44(1): 68-79.
[6]	Jiani Guo, Fan Liu, Lu Wang. Zebrafish blood disease models and applications [J]. Hereditas(Beijing), 2020, 42(8): 725-738.
[7]	Feng Xiong,Xunwei Xie,Luyuan Pan,Kuoyu Li,Liyue Liu,Yun Zhang,Linglu Li,Yonghua Sun. Development of resources, technologies and services at the China Zebrafish Resource Center [J]. Hereditas(Beijing), 2018, 40(8): 683-692.
[8]	Jingjin Xu, Wenjuan Zhang, Jingyi Wang, Liyun Yao, Yutian Pan, Yixin Ou, Yu Xue. The active component screening of Anoectochilus roxburghii and the functional study on inhibition of melanogenesis in zebrafish [J]. Hereditas(Beijing), 2017, 39(12): 1178-1187.
[9]	Shanshan Liu, Cuizhen Zhang, Gang Peng. Effects of starvation on the expression of feeding related neuropeptides in the larval zebrafish hypothalamus [J]. Hereditas(Beijing), 2016, 38(9): 821-830.
[10]	Fenghua Zhang, Houpeng Wang, Siyu Huang, Feng Xiong, Zuoyan Zhu, Yonghua Sun. A comparison of the knockout efficiencies of two codon-optimized Cas9 coding sequences in zebrafish embryos [J]. HEREDITAS(Beijing), 2016, 38(2): 144-154.
[11]	YAN Li-Feng GU Ai-Hua. Progress and application of zebrafish in regenerative medicine [J]. HEREDITAS, 2013, 35(7): 856-866.
[12]	LI Li, LUO Ling-Fei. Zebrafish as the model system to study organogenesis and regeneration [J]. HEREDITAS, 2013, 35(4): 421-432.
[13]	XU Ran-Ran ZHANG Cong-Wei CAO Yu WANG Qiang. mir122 deficiency inhibits differentiation of zebrafish hepa-toblast into hepatocyte [J]. HEREDITAS, 2013, 35(4): 488-494.
[14]	SHEN Yan, HUANG Peng, ZHANG Bo. A protocol for TALEN construction and gene targeting in zebrafish [J]. HEREDITAS, 2013, 35(4): 533-544.
[15]	LI Hui-Hui, HUANG Ping, DONG Wei, ZHU Zuo-Yan, LIU Dong. A brief history of zebrafish research——toward biomedicine [J]. HEREDITAS, 2013, 35(4): 410-420.