中国超细毛羊（甘肃型）胎儿皮肤毛囊发育及其形态结构

doi:10.3864/j.issn.0578-1752.2013.09.020

中国农业科学 ›› 2013, Vol. 46 ›› Issue (9): 1923-1931.doi: 10.3864/j.issn.0578-1752.2013.09.020

中国超细毛羊（甘肃型）胎儿皮肤毛囊发育及其形态结构

吴瑜瑜, 岳耀敬, 郭婷婷, 王天翔, 郭健, 李桂英, 韩吉龙, 杨敏, 刘建斌, 孙晓萍, 李范文, 何玉琴, 杨博辉

1.甘肃农业大学生命科学技术学院，兰州 730070
2.中国农业科学院兰州畜牧与兽药研究所，兰州 730050
3.甘肃省绵羊繁育技术推广站，甘肃张掖 734031

收稿日期:2012-10-18 出版日期:2013-05-01 发布日期:2013-01-30
通讯作者: 通信作者何玉琴，E-mail：yuqinhe@126.com；通信作者杨博辉，E-mail：yangbh2004@163.com
作者简介:吴瑜瑜，E-mail：051380@163.com
基金资助:
国家绒毛用羊产业技术体系资助项目（CARS-40-03B）、中央级公益性科研院所基本科研业务费专项资金项目（BRF1610322012007，BRF1610322012014）

Study on Fetal Skin Hair Follicle Development and Morphology of China Super-Fine Merino (Gansu Type)

WU Yu-Yu, YUE Yao-Jing, GUO Ting-Ting, WANG Tian-Xiang, GUO Jian, LI Gui-Ying, HAN Ji-Long, YANG Min, LIU Jian-Bin, SUN Xiao-Ping, LI Fan-Wen, HE Yu-Qin, YANG Bo-Hui

1.College of Life Science and Technology of Gansu Agricultural University, Lanzhou 730070
2.Lanzhou Animal Husbandry and Veterinary Research Institute of Chinese Academy of Agricultural Sciences, Lanzhou 730050
3.Sheep Breeding Technology Promotion Stations of Gansu Province, Zhangye 734031, Gansu

Received:2012-10-18 Online:2013-05-01 Published:2013-01-30

摘要/Abstract

摘要： 【目的】探究中国超细毛羊（甘肃型）毛囊的组织结构与毛囊形态发生过程，为超细毛羊毛囊发育的分子调控机制研究奠定组织学基础。【方法】采用冰冻组织切片技术制作横切、纵切切片，在显微镜下观测照相。【结果】中国超细毛羊（甘肃型）毛囊结构包括连接组织鞘、外根鞘、内根鞘、毛干和毛球部。在胎龄87 d时初级毛囊发生形成毛芽，在初级毛囊基底部可见次级毛囊的囊泡结构。胎龄102 d时次级毛囊开始再分化。到胎龄138 d时，初级毛囊基本发育成熟。胎龄87—147 d，初级毛囊密度随胎龄增长逐渐降低，次级毛囊密度随胎龄增长逐渐升高，在胎龄102—117 d时次级毛囊增长迅速，在胎龄117 d时达到最大值（232.8±12.44）个/mm2,胎龄126 d时次级毛囊/初级毛囊比值达到最大值9.96。【结论】在胎龄84 d时初级毛囊开始发生，胎龄87 d时次级毛囊开始发生，胎龄102 d时在原始次级毛囊颈部隆突部开始再分化出再分化次级毛囊，胎龄108 d时原始次级毛囊大量再分化，胎龄 138 d时大部分初级毛囊和部分次级毛囊发育成熟；次级毛囊再分化是影响毛囊密度的最主要因素，它能有效地增加毛囊密度，提高羊毛细度。

关键词: 中国超细毛羊（甘肃型） , 毛囊结构 , 形态变化 , 再分化次级毛囊 , 次级毛囊/初级毛囊比值

Abstract: 【Objective】This study aims to research the organizational structure of China Super-Fine Merino hair follicles and hair follicle morphogenesis process, which will lay a histological basis for molecular regulation mechanism of Super-fine Merino hair follicle development.【Method】Tissue frozen section was conducted by embryonic skin of China Super-Fine Merino and the results were taken photography under a microscope.【Result】Results showed that the follicle structure of Super-fine Merino sheep consists of connective tissue sheath, outer root sheath, inner root sheath, hair shaft and hair bulb sections, as other mammals. Primary hair follicle occurred on 87th day of fetal period, vesicle structure of the secondary follicle could be found at the bottom of the primary hair follicle. At gestational 138 d, the primary basic hair follicle was mature. From gestational 87 d to 147 d, the density of primary follicle was gradually decreased and the density of secondary follicle was increased as the gestational age growing, meanwhile the density of primary follicle reached its maximum value (232.8±12.44) (per mm2) at gestational 117 d. The gestational Secondary Follicles to Primary Follicles ratio (S/P ratio) reached the maximum (9.96) at gestational age 126 d.【Conclusion】Primary follicles began to occur at 84 d of gestational age, and secondary hair follicle began to occur at 87 d of gestational age, gestational age 102 d in the original the secondary follicles neck bulge began regeneration to secondary-derived follicles, most of primary follicles and some of secondary hair follicle had matured. The differentiation of secondary hair follicle is a key factor which affected the density of hair follicle; it can effectively increase the density of hair follicle and improve the quality of the wool.

Key words: China Super-Fine Merino (Gansu type) , hair follicles structure , morphogenesis , secondary-derived follicles , S/P ratio

吴瑜瑜, 岳耀敬, 郭婷婷, 王天翔, 郭健, 李桂英, 韩吉龙, 杨敏, 刘建斌, 孙晓萍, 李范文, 何玉琴, 杨博辉. 中国超细毛羊（甘肃型）胎儿皮肤毛囊发育及其形态结构[J]. 中国农业科学, 2013, 46(9): 1923-1931.

WU Yu-Yu, YUE Yao-Jing, GUO Ting-Ting, WANG Tian-Xiang, GUO Jian, LI Gui-Ying, HAN Ji-Long, YANG Min, LIU Jian-Bin, SUN Xiao-Ping, LI Fan-Wen, HE Yu-Qin, YANG Bo-Hui. Study on Fetal Skin Hair Follicle Development and Morphology of China Super-Fine Merino (Gansu Type)[J]. Scientia Agricultura Sinica, 2013, 46(9): 1923-1931.

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参考文献

[1]魏云霞, 李宏. 甘肃高山细毛羊皮肤毛囊发育规律的研究. 中国草食动物, 2002(Suppl.1): 190-191.

Wei Y X, Li H. Study on development of skin and hair follicle in Gansu Alpine Merino. China Herbivores, 2002(Suppl.1): 190-191. (in Chinese)

[2]Carter H, Clarke W. The hair follicle group and skin follicle population of Australian Merino sheep. Australian Journal of Agricultural Research, 1957(8): 91-108.

[3]Barton S A, Purvis I W, Brewer H G. Are wool follicle characteristics associated with wool quality and production in hogget and adult sheep? Proceedings of the Association for the Advancement of Animal Breeding and Genetics, 2001, 14: 289-292.

[4]Abelson D L, Cam G R, Desilva U, Franklin I R. Gene expression in sheep skin and wool (hair). Genomics, 2004, 83(1): 95-105.

[5]Hardy M H, Lyne A G. The pre-natal development of wool follicles in Merino sheep. Division of Animal Health and Production, 1955, 9(3): 421-441.

[6]Davidson P, Hardy M H. The development of mouse vibrissae in vivo and in vitro. Journal of Anatomy, 1952, 86(4): 342-356.

[7]Kumamoto T, Shalhevet D, Matsue H. Hair follicles serve as local reservoirs of skin mast cell precursors. Blood, 2003, 102(5): 1654-1660.

[8]Gat U, DasGupta R, Degenstein L, Fuchs E. De novo hair follicle morphogenesis and hair tumors in mice expressing a truncated β-catenin in skin. Cell, 1998, 95(5): 605-614.

[9]Matsuzaki T, Yoshizato K. Role of hair papilla cells on induction and regeneration processes of hair follicles. Wound Repair and Regeneration, 1998, 6(6): 524-530.

[10]Rogers G E. Hair follicle differentiation and regulation. The International Journal of Developmental Biology, 2004, 48(2/3): 163-170.

[11]Rogers G E. Biology of the wool follicle: an excursion into a unique tissue interaction system waiting to be re-discovered. Experimental Dermatology, 2006, 15(12): 931-949.

[12]Di-Po N, Ng C Y, Tan N S, Yang Z Z, Brian A, Hemmings B A, Desvergne B, Michalik L, Wahli W. Epithelium-mesenchyme interactions control the activity of peroxisome proliferator activated receptor β/δ during hair follicle development. Molecular and Cellular Biology, 2005, 25(5): 1696-1712.

[13]Bernard B A. The life of human hair follicle revealed. Medicine Sciences, 2006, 12(22): 138-143.

[14]Millar S E. Molecular mechanisms regulating hair follicle development. The Journal of Investigative Dermatology, 2002, 118(2): 216-225.

[15]Mou C, Jackson B, Schneider P, Overbeek P A, Headon D J. Generation of the primary hair follicle pattern. Proceeding of the National Academy of Science of the United States of America, 2006, 103(24): 9075-9080.

[16]Parry A L, Nixon A J, Craven A J, Pearson A J. The microanatomy, cell replication, and Keratin gene expression of hair follicles during a photoperiod-induced growth cycle in sheep. Acta Anatomica, 1995, 154(4): 283-299.

[17]Stenn K S, Paus R. Controls of hair follicle cycling. Physiological Reviews, 2001, 81(1): 449-494.

[18]Driskell R R, Clavel C, Rendl M, Watt F M. Hair follicle dermal papilla cells at a glance. Journal of Cell Science, 2011, 124(8): 1179-1182.

[19]Yang C C, Cotsarelis G. Review of hair follicle dermal cells. Journal of Dermato- Logical Science, 2010, 57(1): 2-11.

[20]Enshell D, Lindon C, Kashiwagi M, Bruce A. Beta-catenin activity in the dermal papilla regulates morphogenesis and regeneration of hair. Developmental Cell, 2010, 18(4): 633-642.

[21]Gao J, DeRouen M, Chen C H, Nguyen M, Nguyen N T, Harada K, Ido H, Sekiguchi K, Morgan B A, Miner J H, Oro A E. Laminin-511 is an epithelial message promoting dermal papilla development and function during early hair morphogenesis. Genes and Development, 2008, 22(15): 2111-2124.

[22]Li A G, Koster M I, Wang X J. Roles of TGF-β signaling in epidermal/appendage development. Cytokine and Growth Factor Reviews, 2003, 14(2): 99-111.

[23]Shimomura Y, Christiano A. Biology and genetics of hair. Annual Review of Genomics and Human Genetics, 2010, 11: 109-132.

[24]张燕军, 尹俊, 李金泉, 李长青. 内蒙古阿尔巴斯绒山羊毛囊结构及形态发生过程研究. 中国农业科学, 2007, 40(5): 1017- 1023.

Zhang Y J, Yin J, Li J Q, Li C Q. Study on hair follicle structure and morphogenesis of the Inner Mongolian Arbas Cashmere goat. Scientia Agricultura Sinica, 2007, 40(5): 1017-1023. (in Chinese)

[25]姜笃银, 付小兵, 孙同柱, 陈伟, 盛志勇. FGF10及其受体对胎儿皮肤附件形成的诱导作用. 解放军医学杂志, 2003, 28(7): 583-586.

Jiang D Y, Fu X B, Sun T Z, Chen W, Sheng Z Y. The induction effects of FGF10 and ITS receptor on the formation of fetal skin appendage. Medical Journal Chinese People’s Liberation Army, 2003, 28(7): 583-586. (in Chinese)

[26]姜笃银, 付小兵. 毛囊干细胞的基因调节、生物学特征及其与疾病发生的关系. 解放军医学杂志, 2004, 29(4): 369-370.

Jiang D Y, Fu X B. The relation with illness of hair follicle stem cell gene regulation and biology character. Medical Journal Chinese People’s Liberation Army, 2004, 29(4): 369-370. (in Chinese)

[27]Ullrich R, Paus R. Molecular principles of hair follicle induction and morphogenesis. BioEssays: Newa and Reviews in Molecular, Cellular and Developmental Biology, 2005, 27(3): 247-261.

[28]Davidson P, Hardy M H. The development of mouse vibrissae in vivo and in vitro. Journal of Anatomy, 1952, 86(4): 342-356.

[29]Sheets T. Alpacas-A Guide to Getting Started Guide. Heritage Farm Suri Alpacas, www.ourheritagefarm. com.

[30]Moore G P M, Jackson N, Isaacs K, Brown G. Development and density of wool follicles in Merino sheep selected for single fibrecharacteristics. Australian Journal of Agricultural Research, 1996, 47(8): 1195-1201.

[31]Fuchs E. Scratching the surface of skin development. Nature, 2007, 445: 834-842.

[32]Mikkola M L. Genetic basis of skin appendage development. Seminars in Cell Developmental Biology, 2007, 18(2): 225-236.

[33]汪长寿, 曹贵方, 任秀娟. 蒙古绵羊皮肤毛囊细胞凋亡初步研究. 河套大学学报, 2012, 9(2): 21-25.

Wang C S, Cao G F, Ren X J. Mongolia sheep skin hair follicle cells apoptosis preliminary study. Hetao University Journal, 2012, 9(2): 21-25.

[34]杨雨江, 常青, 郭丹, 陈洋, 宋先忱, 姜怀志. 辽宁绒山羊胎儿皮肤中Bcl-2\Bax基因表达变化的研究. 中国草食动物科学, 2012, 49(3): 215-217.

Yang Y J, Chang Q, Guo D, Chen Y, Song X C, Jiang H Z. Liaoning Cashmere goats fetal skin Bcl-2\Bax gene expression research. China Herbivore Science, 2012, 49(3): 215-217. (in Chinese)

[35]Zimmermann K C, Green D R. How cells die: Apoptosis pathways. Journal of Allergy and Clinical Immunology, 2001, 108(4): S99-S103.

[36]Laulier C, Lopez B S. The secret life of Bcl-2: apoptosis-independent inhibition of DNA repairs by Bcl-2 family members. Mutation Research. 2012, 751(2): 247-257.

中国超细毛羊（甘肃型）胎儿皮肤毛囊发育及其形态结构

Study on Fetal Skin Hair Follicle Development and Morphology of China Super-Fine Merino (Gansu Type)

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