卷羽鸡毛囊发育规律及卷羽候选基因KRT75遗传特征分析

doi:10.3864/j.issn.0578-1752.2015.04.20

摘要/Abstract

摘要： 【目的】研究卷羽鸡卷羽弯曲过程、结构特点、卷羽毛囊发育规律和卷羽候选基因KRT75序列特征及其在卷羽毛囊发育过程中的表达规律。【方法】通过对360只卷羽鸡从1日龄到300日龄卷羽发生情况进行观察，了解其羽毛出壳后弯卷过程；制作成年卷羽和片羽羽毛切片，了解卷羽羽轴、羽枝、羽小枝、羽小钩显微结构特点；对卷羽鸡和片羽鸡胚胎期8—19 d皮肤毛囊制作石蜡切片，阐明卷羽毛囊发生过程，分析卷羽和片羽毛囊发育异同；分别提取13胚龄卷羽和片羽鸡皮肤RNA，反转录为cDNA，连接pMD™ 18-T 载体，将连接产物加入DH5α感受态细胞中，转化涂板，挑取白色菌落摇菌后PCR鉴定，阳性菌液送测序，同时随机抽取15只300日龄片羽鸡和15只卷羽鸡，翅下静脉采血,血液基因组柱式小量提取试剂盒提取DNA,PCR产物纯化后测序，采用DNAMAN软件比对分析KRT75基因的遗传特征；分别提取卷羽和片羽胚胎期E 8—E 17d皮肤RNA，反转录成cDNA，根据SYBR试剂盒操作说明荧光定量KRT75基因在卷羽和片羽整个毛囊发育过程中的表达变化规律。【结果】卷羽鸡初生绒羽弯曲明显，以后逐渐弯曲，在第一次换羽结束时（约6周龄左右）全身羽毛显著弯曲；卷羽羽轴向外翻卷，羽小枝上着生羽钩，但羽小枝之间不能相互勾连形成闭合羽片；卷羽毛囊发育从胚胎期第8天开始到第16天结束，整个过程类似于片羽毛囊发育，卷羽毛囊在胚胎期第8—16天完成，整个过程和片羽毛囊发育过程基本相似，但在12—15胚龄卷羽毛囊髓质面积、羽小枝大小与片羽毛囊存在明显差异，其中在第12—14天，卷羽毛囊髓质面积要明显大于片羽，羽小枝板要明显小于片羽；卷羽鸡和片羽鸡KRT75基因CDS全长均为1 569bp，编码522个氨基酸，全序列没有发生69 bp的缺失突变，但在CDS区的3个SNP（954bp: T>C；967bp: T>C；978bp: C>T）可能是卷羽、片羽区别的分子标记；KRT75基因在片羽和卷羽中的表达变化存在明显差异，在片羽毛囊胚胎期E8-E17中表达量均很低，而在卷羽鸡12胚龄显著上调，且高表达量持续到15胚龄，16胚龄显著下调，其中在胚胎期第9、10、12-16天KRT75基因在卷羽中的表达量均极显著高于片羽（P<0.01），KRT75基因可能在卷羽羽轴髓质和羽小枝分化过程中起重要作用。【结论】初步研究表明卷羽鸡的卷羽并不是由于KRT75基因缺失突变引起，但KRT75可能与卷羽髓质和羽枝嵴形成有关。

关键词: 卷羽鸡, 毛囊发育, KRT75, SNP, 表达

Abstract: 【Objective】The Objective of this study is to analyzes the features and curve process of frizzled feather, the development of frizzled feather follice, sequence features and expression rules of candidate gene KRT75 in frizzled feather follicle development. 【Method】 The frizzled feathers of 360 frizzled chicks from 1 to 300 days were observedto know the curve process, and the microstructure of rachis, barbules, anf hooks between frizzled and contour feather were compared. The development of feather follicle between frizzled feather and contour feather at 8th in embryonic period was compared by Microscopic section technology. The total RNA from the embryonic 13 day skin of frizzled feather and contour feather was extracted, respectively, reverse transcripted cDNA，connected with the PMD-18T vector，the products were transformed into DH5α competent cells, coated plates, monoclonal colony was selected for PCR, and the positive plasmid was chosen for sequencing. In addition, 15 frizzled and contour feather chicks at 300 days were randomly selected to collect vein blood under the wing, blood genome pillar extraction kit was used to extract DNA, the PCR products were also sequenced after purification, and the DNAMAN software was used to analyze genetic characteristics of KRT75 gene. The total RNA was also extracted from embryonic 8 to 17 day skin of frizzled feather and contour feather; respectively, reverse transcripted cDNA, and the SYBR kit was used to analyze KRT75 gene expression during the formation of feather follicle. 【Result】 The down feather appeared disorder and curved in newborn frizzle chicks, the largest curvature of feather was observed at 6 weeks. The frizzled feather rachis curved outward, barbules could not hooked together to form a closed feather; the development of frizzled feather follicle and contour feather follicle was both from E8 to E16, there were some differences in the medulla and barb ridge between frizzled feather and normal one from E12 to E15, in the E12 to E14 day, the medulla of frizzled feather were bigger than contour feather, but the barbule plates were smaller than contour feather. The CDS of KRT75 gene was 1 569 bp both in frizzled feather and contour feather chickens, no 69 bp deletion mutation was detected in CDS region of frizzled chicken KRT75 gene. Three SNPs ( 954bp: T>C; 967bp: T>C; 978bp: C>T) were found compared frizzled chicken with Princess chicken. The expression of KRT75 was significantly different between frizzled feather and contour feather, KRT75 was low expression in contour feather follice but was highly expressed in frizzled feather follicle from E9 to E17, especially in E9,E10 and E12 to E15, the KRT75 of frizzled feather was highly significant than contour feather(P<0.01). 【Conclusion】 Frizzled feather of KiRin Chicken was not caused by 69 bp detection mutation of KRT75 gene. The three SNPs (955bp: T>C; 967bp: T>C; 978bp: C>T) could be used as molecular markers in distinguishing frizzled and contour feathers.

陶林，杜炳旺，张丽. 卷羽鸡毛囊发育规律及卷羽候选基因KRT75遗传特征分析[J]. 中国农业科学, 2015, 48(4): 821-830.

TAO Lin, DU Bing-wang, ZHANG Li. The Development of Frizzled Follicle and Genetic Characteristics of Candidate Gene KRT75 in Frizzled Feather Chicken[J]. Scientia Agricultura Sinica, 2015, 48(4): 821-830.

0
/ / 推荐

导出引用管理器 EndNote|Reference Manager|ProCite|BibTeX|RefWorks

链接本文: https://www.chinaagrisci.com/CN/10.3864/j.issn.0578-1752.2015.04.20

https://www.chinaagrisci.com/CN/Y2015/V48/I4/821

参考文献

[1] Aerts J, Crooijmans R, Cornelissen S, Hemmatian K, Veenendaal T, Jaadar A, et al. Integration of chicken genomic resources to enable whole-genome sequencing. Cytogenetic and Genome Research. 2004, 102(1-4): 297-303.

[2] Antin P B, Konieczka J H. Genomic resources for chicken. Developmental Dynamics, 2005, 232(4): 877-882.

[3] Burt D, Pourquie O. Chicken Genome—science nuggets to come soon. Science, 2003, 300(5626): 1669.

[4] Burt DW. Chicken genomics charts a path to the genome sequence. Briefings in Functional Genomics & Proteomics, 2004, 3(1): 60-67.

[5] 邱祥聘，杨山. 家禽学. 成都：四川科学技术出版社，1993: 38-39.

Qiu X P, Yang S. Poultry Science. Chengdu: Sichuan Science and Technology Publishing House,1993: 38-39. (in Chinese)

[6] Chuong C M. The making of a feather: Homeoproteins, retinoids and adhesion molecules. BioEssays, 1993, 15: 513-521.

[7] Chen SN, Wu P, Foley J, Foley A, McDonald ML, Juan WT, Huang CJ, Lai YT, Lo WS,Chen CF,Leal S M,Zhang H, WidelitzRB,Patel P I, Li WH, ChuongCM. The Chicken Frizzle Feather Is Due to an a-Keratin (KRT75) Mutation That Causes a Defective Rachis. Plos Genetics. 2012; 8(7):1-16.

[8] Lucas A, Stettenheim P. Avian Anatomy-Integument. Agricultural Handbook 362. Washington DC: Agricultural Research Services. US Department of Agriculture. 1972.

[9] Yu M K, Yue Z C, Wu P, Wu DY, Mayer JA, Medina M,Widelitz R B, Jiang TX,Chuong CM. The developmental biology of feather follicles. International Journal of Developmental Biology, 2004; 48: 181-192.

[10] Winter H, Schissel D, Parry D A D, Smith T A, Liovic M, Lane E B, Edler L, Langbein L, Jave-Suarez L F, Rogers M A, Wilde J, Peters G, Schweizer J. An Unusual Ala12Thr Polymorphism in the 1A -Helical Segment of the Companion Layer-Specific Keratin K6hf: Evidence for a Risk Factor in the Etiology of the Common Hair Disorder Pseudofolliculitis Barbae. Journal of Investigative Dermatology, 2004, 122:652-657.

[11] Schweizera J, Langbeinb L, Michael A, Wintera H. RogersHair follicle-specific keratins and their diseases. Experimental Cell Research, 2007,313(10): 2010-2020.

[12] 费荣梅，田秀华. 大鸨羽毛微观结构研究. 东北林业大学学报. 2002,30(1):40-43.

Fei R M, Tian X H. Microstructure research of feathers of great bustard. Journal of Northeast Forestry University, 2002, 30(1):40-43. (in Chinese)

[13] 赵红琼. 新疆南疆绒山羊皮肤毛囊结构研究. 新疆农业科学, 2002,39(4): 200-203.

Zhao H Q, Liu Z Q, Nie Y M. Studies on skin follicle structure of the Southern Xinjing Cahmere Goat. Xinjiang Agricultural Sciences, 2002,39(4): 200-203. (in Chinese)

[14] Hardy MH. The secret life of the hair follicle. Trends in Genetics, 1992, 8(2): 55-61.

[15] Paus R, Müller-Röver S, van der Veen C, Maurer M, Eichmüller S, Ling G. A comprehensive guide for the recognition and classification of distinct stages of hair follicle morphogenesis. Journal of Investigative Dermatology, 1999, 113(4): 523-532.

[16] Widelitz R B, Jiang TX, Yu M, Shen T, Shen JY, Wu P, Yu Z, Chuong CM. Molecular biology of feather morphogenesis:a testable model for evodevo research. Journal of Experimental Zoology Part B: Molecular and Development Evolution, 2003, 298(1):109-122.

[17] Maderson PF, Hiller U, Dove CC. Towards a comprehensive model of feather regeneration. Journal of Morphology, 2009, 270: 1166-1208.

[18] Alibardi L. Cytochemical and molecular characteristics of the process of cornification during feather morphogenesis. Prog Histochem Cytochem, 2008, 43: 1-69.

[19] Molla R, Mollb I, Wiestc W. Changes in the pattern of cytokeratin polypeptides in epidermis and hair follicles during skin development in human fetuses. Differentiation, 1982, 23: 170-178.

[20] Prum R O, Williamson S. Theory of the growth and evolution of feather shape . Journal of Experimental Zoology, 2001, 291:30–57.

[21] Schweizer J, Bowden P E, Coulombe P A, Langbein L, Lane E B, Magin T M, Maltais L, Omary M B, Parry D AD, Rogers M A, Wright M W. New consensus nomenclature for mammalian keratins. Journal of Cell Biology,2006, 174: 169-174.

[22] Winter H, Langbein L, Praetzel S, Jacobs M, Rogers M A, Leigh I M, Tidman N, Schweizer J. A Novel Human Type II Cytokeratin, K6hf, Specifically Expressed in the Companion Layer of the Hair Follicle. Journal of Investigative Dermatology, 1998, 111: 955-962.

[23] Wojcik S M, Longley M A, Roop D R. Discovery of a novel murine keratin 6 (K6) isoform explains the absence of hair and nail defects in mice deficient for K6a and K6b. Journal of Cell Biology, 2001, 154:619-630.

[24] Wang Z L, Wong P, Langbein L, Schweizer J, Coulombe P A. Journal of Investigative Dermatology, 2003, 121: 1276-1282.