草业学报 ›› 2026, Vol. 35 ›› Issue (7): 188-200.DOI: 10.11686/cyxb2025290
• 研究论文 • 上一篇
谢婧(
), 孟旭铭, 仓振, 华云涛, 周贤毅, 茆达干(
)
收稿日期:2025-07-14
修回日期:2025-09-09
出版日期:2026-07-20
发布日期:2026-05-21
通讯作者:
茆达干
作者简介:Corresponding author. E-mail: maodagan@njau.edu.cn基金资助:
Jing XIE(
), Xu-ming MENG, Zhen CANG, Yun-tao HUA, Xian-yi ZHOU, Da-gan MAO(
)
Received:2025-07-14
Revised:2025-09-09
Online:2026-07-20
Published:2026-05-21
Contact:
Da-gan MAO
摘要:
旨在对湖羊4/4直毛和4/4波浪形羔皮进行转录组测序,以分析影响羔皮性状的关键基因。采集4/4直毛和4/4波浪形羔皮羊的体侧部皮肤组织(n=4),提取总RNA进行转录组测序,筛选差异表达基因(DEGs),进行基因本体论(GO)和京都基因与基因组百科全书(KEGG)富集分析,并进一步开展KEGG通路的基因集富集分析(GSEA)及DEGs的转录因子预测。对7个DEGs进行实时荧光定量PCR验证(qRT-PCR),同时比较DEGs在不同花案面积个体羔皮直毛和波浪处的表达。结果显示,4/4直毛和4/4波浪形羔皮中共筛选出315个DEGs(阈值|log2FC|≥1且FDR<0.05),其中波浪形羔皮中274个基因下调,41个基因上调。GO分析发现,DEGs主要富集在细胞外结构组织、细胞外基质和整合素结合等3771个条目;KEGG分析显示,DEGs主要富集在细胞黏附分子、PI3K-AKT信号通路和RAS信号通路等209条通路。GSEA显示,DEGs主要与组氨酸代谢、肾素分泌和蛋白质消化吸收等通路相关;与4/4直毛形羔皮相比,富集到的与毛囊有关的RAS、PI3K-AKT和RAP1信号通路在4/4波浪形羔皮中呈下调趋势;转录因子预测发现编码转录因子(TFs)的差异基因共12个,其中上调基因2个,下调基因10个,主要包括SRY相关高迁移率族盒(SOX)、叉头框(FOX)和T盒(T-box)等TFs家族。qRT-PCR结果显示,筛选出的7个与羔皮性状相关的基因表达趋势与转录组测序结果一致,且IGF1和MFAP5基因在不同花案面积个体羔皮波浪处的表达量显著低于直毛处。综上,筛选出的AEBP1、IGF1、MMP27、MFAP5、RPTN、SPI1和THY1可作为影响羔皮性状的重要候选基因,为进一步解析湖羊波浪形羔皮形成的分子机制奠定基础。
谢婧, 孟旭铭, 仓振, 华云涛, 周贤毅, 茆达干. 基于转录组测序分析湖羊波浪形羔皮形成的关键基因[J]. 草业学报, 2026, 35(7): 188-200.
Jing XIE, Xu-ming MENG, Zhen CANG, Yun-tao HUA, Xian-yi ZHOU, Da-gan MAO. Analysis of key genes in Hu wavy pattern lambskin based on transcriptome sequencing[J]. Acta Prataculturae Sinica, 2026, 35(7): 188-200.
基因 Gene | 名称 Name | 基因库编号 Genebank number | 引物序列 Primer sequence ( | 产物长度 Product length (bp) |
|---|---|---|---|---|
| AEBP1 | AE结合蛋白1AE binding protein 1 | XM_012176971.5 | F: CTCATGCAATACCTGTGCCG | 142 |
| R: TCCCAAACTCTGAGCCCATC | ||||
| IGF1 | 胰岛素样生长因子1Insulin-like growth factor 1 | XM_027965761.2 | F: TTCTATCTGGCCCTGTGCTTG | 138 |
| R: CCCCGTGGGCTTGTTGAAATA | ||||
| MMP27 | 基质金属肽酶27Matrix metallopeptidase 27 | XM_004015972.5 | F: TGCTGTCTTGCCAGATTATCCC | 149 |
| R: GGGTCACTTCATCATACCTCCAG | ||||
| MFAP5 | 微纤维相关蛋白5Microfibril-associated protein 5 | XM_015094961.3 | F: TCAAGCCTTCTACCGATGACC | 70 |
| R: TTCTCATCCCGGCACTCTGT | ||||
| RPTN | 重复素Repetin | XM_060396929.1 | F: AGAATGGGGACTCCACCTCA | 93 |
| R: CTGGGTCATTTGGTCTCCTGA | ||||
| SPI1 | Spi-1原癌基因Spi-1 proto-oncogene | XM_027979753.3 | F: CAACGCCAAACGCACGAATA | 71 |
| R: TCCCAGTAATGGTCGCTGTG | ||||
| THY1 | Thy-1细胞表面抗原Thy-1 cell surface antigen | XM_060399793.1 | F: CCTCCTGCTGACAGTCTTACA | 132 |
| R: AACTCATACTGCATGGGCGT | ||||
| GAPDH | 甘油醛-3-磷酸脱氢酶Glyceraldehyde-3-phosphate dehydrogenase | NM_001190390.1 | F: TCGGAGTGAACGGATTTGGC | 76 |
| R: ACGATGTCCACTTTGCCAGT |
表1 实时荧光定量PCR引物序列
Table 1 qRT-PCR primer sequences
基因 Gene | 名称 Name | 基因库编号 Genebank number | 引物序列 Primer sequence ( | 产物长度 Product length (bp) |
|---|---|---|---|---|
| AEBP1 | AE结合蛋白1AE binding protein 1 | XM_012176971.5 | F: CTCATGCAATACCTGTGCCG | 142 |
| R: TCCCAAACTCTGAGCCCATC | ||||
| IGF1 | 胰岛素样生长因子1Insulin-like growth factor 1 | XM_027965761.2 | F: TTCTATCTGGCCCTGTGCTTG | 138 |
| R: CCCCGTGGGCTTGTTGAAATA | ||||
| MMP27 | 基质金属肽酶27Matrix metallopeptidase 27 | XM_004015972.5 | F: TGCTGTCTTGCCAGATTATCCC | 149 |
| R: GGGTCACTTCATCATACCTCCAG | ||||
| MFAP5 | 微纤维相关蛋白5Microfibril-associated protein 5 | XM_015094961.3 | F: TCAAGCCTTCTACCGATGACC | 70 |
| R: TTCTCATCCCGGCACTCTGT | ||||
| RPTN | 重复素Repetin | XM_060396929.1 | F: AGAATGGGGACTCCACCTCA | 93 |
| R: CTGGGTCATTTGGTCTCCTGA | ||||
| SPI1 | Spi-1原癌基因Spi-1 proto-oncogene | XM_027979753.3 | F: CAACGCCAAACGCACGAATA | 71 |
| R: TCCCAGTAATGGTCGCTGTG | ||||
| THY1 | Thy-1细胞表面抗原Thy-1 cell surface antigen | XM_060399793.1 | F: CCTCCTGCTGACAGTCTTACA | 132 |
| R: AACTCATACTGCATGGGCGT | ||||
| GAPDH | 甘油醛-3-磷酸脱氢酶Glyceraldehyde-3-phosphate dehydrogenase | NM_001190390.1 | F: TCGGAGTGAACGGATTTGGC | 76 |
| R: ACGATGTCCACTTTGCCAGT |
图 1 直毛和波浪形羔皮组织形态学特性P: 初级毛囊Primary hair follicle; S: 次级毛囊Secondary hair follicle.
Fig.1 Histomorphological characteristics of straight hair and wavy pattern lambskins
组别 Group | 次级毛囊数量/初级毛囊数量Number of secondary hair follicles/number of primary hair follicles (S/P) | 初级毛囊直径Primary hair follicle diameter (PD, μm) | 次级毛囊直径Secondary hair follicle diameter (SD, μm) |
|---|---|---|---|
| 4/4直毛 4/4 straight hair | 4.24±0.25a | 176.65±6.84a | 60.05±2.84a |
| 4/4波浪4/4 wavy pattern | 2.67±0.25b | 138.21±6.50b | 45.55±3.56b |
表2 直毛和波浪形羔皮毛囊比较
Table 2 Comparison of hair follicles between straight hair and wavy pattern lambskins
组别 Group | 次级毛囊数量/初级毛囊数量Number of secondary hair follicles/number of primary hair follicles (S/P) | 初级毛囊直径Primary hair follicle diameter (PD, μm) | 次级毛囊直径Secondary hair follicle diameter (SD, μm) |
|---|---|---|---|
| 4/4直毛 4/4 straight hair | 4.24±0.25a | 176.65±6.84a | 60.05±2.84a |
| 4/4波浪4/4 wavy pattern | 2.67±0.25b | 138.21±6.50b | 45.55±3.56b |
| 样本名称Sample | 原始测序读数Raw reads (bp) | 过滤后读数Clean reads (bp) | Q20 (%) | Q30 (%) | GC含量GC content (%) |
|---|---|---|---|---|---|
| S1 | 41094942 | 41094936 | 99.40 | 97.18 | 48.65 |
| S2 | 40508630 | 40508628 | 99.40 | 97.25 | 48.60 |
| S3 | 46929166 | 46924146 | 99.53 | 97.87 | 48.88 |
| S4 | 40044654 | 40044652 | 99.54 | 97.95 | 48.63 |
| W1 | 41862838 | 41859348 | 99.51 | 97.71 | 48.47 |
| W2 | 43925888 | 43925882 | 99.48 | 97.60 | 48.88 |
| W3 | 40125986 | 40125986 | 99.49 | 97.67 | 47.44 |
| W4 | 42378798 | 42375874 | 99.45 | 97.48 | 47.76 |
表3 数据质控表
Table 3 Data quality control sheet
| 样本名称Sample | 原始测序读数Raw reads (bp) | 过滤后读数Clean reads (bp) | Q20 (%) | Q30 (%) | GC含量GC content (%) |
|---|---|---|---|---|---|
| S1 | 41094942 | 41094936 | 99.40 | 97.18 | 48.65 |
| S2 | 40508630 | 40508628 | 99.40 | 97.25 | 48.60 |
| S3 | 46929166 | 46924146 | 99.53 | 97.87 | 48.88 |
| S4 | 40044654 | 40044652 | 99.54 | 97.95 | 48.63 |
| W1 | 41862838 | 41859348 | 99.51 | 97.71 | 48.47 |
| W2 | 43925888 | 43925882 | 99.48 | 97.60 | 48.88 |
| W3 | 40125986 | 40125986 | 99.49 | 97.67 | 47.44 |
| W4 | 42378798 | 42375874 | 99.45 | 97.48 | 47.76 |
图 2 湖羊4/4直毛和4/4波浪形羔皮的差异表达基因A: 差异表达基因的火山图Volcano map of differentially expressed genes; B: 差异表达基因聚类分析图Cluster analysis diagram of differentially expressed genes. S: 直毛Straight hair; W: 波浪Wavy pattern. Padj: 校正后P值Adjusted P-value; FC: 倍数变化Fold change. 下同The same below.
Fig.2 Differentially expressed genes in Hu lambskins with 4/4 straight hair and 4/4 wavy pattern
图3 差异表达基因的GO和KEGG通路富集分析A: GO富集分析GO enrichment analysis; B: KEGG富集分析KEGG enrichment analysis.
Fig.3 GO and KEGG pathway enrichment analysis of differentially expressed genes
图4 磷脂酰肌醇-3-激酶-蛋白激酶B信号通路相关差异基因聚类热图A: 生成磷脂酰肌醇3-激酶IA型的PI3K-AKT信号通路途径The PI3K-AKT signaling pathway for generating phosphatidylinositol 3-kinase type IA; B: 生成磷脂酰肌醇3-激酶IB型的PI3K-AKT信号通路途径The PI3K-AKT signaling pathway for generating phosphatidylinositol 3-kinase type IB.
Fig.4 Phosphatidylinositol-3-kinase-protein kinase B signaling pathway-related differential gene clustering heatmap
图6 实时荧光定量PCR检测候选基因表达量A: 4/4直毛和4/4波浪形羔皮7个候选基因表达Expression of seven candidate genes lambskins with 4/4 straight hairs and 4/4 wavy pattern; B: 不同波浪面积羔皮个体直毛与波浪处IGF1和MFAP5的表达Expression of IGF1 and MFAP5 at straight hair site and wavy pattern site in individual lambskins with different wavy areas. *: P<0.05; **: P<0.01.
Fig.6 Expression of candidate genes detected by real-time quantitative PCR
| [1] | Li Z N, Zhang Z L, Du J Z, et al. Morphological investigation on the formation of skin wavy pattern in the Huyang lambs. Scientia Agricultura Sinica, 1982, 15(3): 73-82. |
| 李志农, 张仲倫, 杜建中, 等. 湖羊羔皮花纹形成的形态学观察. 中国农业科学, 1982, 15(3): 73-82. | |
| [2] | Chen R H. Identification and grading of Hu lambskin. Journal of Economic Animal, 1980(1): 40-41. |
| 程瑞禾. 小湖羊皮的鉴定与分级. 毛皮动物饲养, 1980(1): 40-41. | |
| [3] | Chen F X.Tanning technology of chekiang lamb skin. China Leather, 2005, 34(5): 40, 46. |
| 程凤侠. 小湖羊皮鞣制工艺. 中国皮革, 2005, 34(5): 40, 46. | |
| [4] | Prost-Squarcioni C. Histology of skin and hair follicle. Médecine Sciences, 2006, 22(2): 131-137. |
| [5] | Sun W, Ni R, Yin J F, et al. Genome array of hair follicle genes in lambskin with different patterns. PLoS One, 2013, 8(7): e68840. |
| [6] | He M L, Lv X Y, Cao X K, et al. SOX18 promotes the proliferation of dermal papilla cells via the Wnt/beta-catenin signaling pathway. International Journal of Molecular Sciences, 2023, 24(23): 16672. |
| [7] | Li X B, Liu Z F, Liu Y, et al. Mining genes related to wool bending of Zhongwei Goat based on WGCNA and GSEA. Acta Veterinaria et Zootechnica Sinica, 2022, 53(9): 2930-2943. |
| 李晓波, 刘占发, 刘悦, 等. 基于WGCNA与GSEA方法挖掘调控中卫山羊羊毛弯曲相关基因. 畜牧兽医学报, 2022, 53(9): 2930-2943. | |
| [8] | Yu L J, Zhang Y H, Lazate·Ainiwaer, et al. Screening microRNAs related to wool crimp in Chinese Merino sheep. Xinjiang Agricultural Sciences, 2021, 58(3): 573-580. |
| 于丽娟, 张艳花, 拉扎特·艾尼瓦尔, 等. 中国美利奴羊羊毛弯曲相关microRNA的筛选. 新疆农业科学, 2021, 58(3): 573-580. | |
| [9] | Dong Y J, Hao X J, Wu J Q, et al. Exploration of the effect of SHH on wool bending through Krox20 regulation of IGFBP5 expression based on sheep keratinocytes. Acta Veterinaria et Zootechnica Sinica, 2023, 54(6): 2365-2375. |
| 董亚洁, 郝晓静, 吴晋强, 等. 基于绵羊角质形成细胞探究SHH通过Krox20调节IGFBP5的表达影响羊毛弯曲. 畜牧兽医学报, 2023, 54(6): 2365-2375. | |
| [10] | Yamamoto H, Flannery M L, Kupriyanov S, et al. Defective trophoblast function in mice with a targeted mutation of Ets2. Genes & Development, 1998, 12(9): 1315-1326. |
| [11] | Yang H Y L, Yang Y L, Fang C H, et al. Fetal skin hair follicle development and morphology of Chinese Merino (Xinjiang Junken type). Southwest China Journal of Agricultural Sciences, 2021, 34(1): 202-207. |
| 杨涵羽璐, 杨永林, 方晨辉, 等. 中国美利奴羊(新疆军垦型)胎儿期皮肤毛囊结构及形态学观察. 西南农业学报, 2021, 34(1): 202-207. | |
| [12] | Zhang Y J, Yin J, Li C Q, et al. Study on development of skin and hair follicle from fetal Inner Mongolian Arbas cashmere goats. Acta Veterinaria et Zootechnica Sinica, 2006, 37(8): 761-768. |
| 张燕军, 尹俊, 李长青, 等. 内蒙古阿尔巴斯绒山羊胎儿期皮肤毛囊发生发育规律研究. 畜牧兽医学报, 2006, 37(8): 761-768. | |
| [13] | Cloete E, Khumalo N P, Ngoepe M N. The what, why and how of curly hair: a review. Proceedings of the Royal Society A: Mathematical, Physical and Engineering Sciences, 2019, 475(2231): DOI: 10.1098/rspa.2019.0516. |
| [14] | Li X L, Tao J Z, Ding W, et al. Analysis of wool traits and its relationship in Tan sheep during the er-mao period. China Animal Husbandry & Veterinary Medicine, 2019, 46(2): 442-448. |
| 李向龙, 陶金忠, 丁伟, 等. 滩羊二毛期羊毛性状分析及其相关性研究. 中国畜牧兽医, 2019, 46(2): 442-448. | |
| [15] | Yang H, Yang Y L, Liu S R, et al. Correlation analysis of the physical and chemical properties of wool among strains of Chinese Merino (Xinjiang Junken type). China Animal Husbandry & Veterinary Medicine, 2011, 38(6): 37-40. |
| 杨华, 杨永林, 刘守仁, 等. 中国美利奴羊(新疆军垦型)品系间羊毛理化性能及性状相关分析. 中国畜牧兽医, 2011, 38(6): 37-40. | |
| [16] | Pickering N K, Blair H T, Hickson R E, et al. Genetic relationships between dagginess, breech bareness, and wool traits in New Zealand dual-purpose sheep. Journal of Animal Science, 2013, 91(10): 4578-4588. |
| [17] | Chen Y, Fan Z M, Wang X X, et al. PI3K/Akt signaling pathway is essential for de novo hair follicle regeneration. Stem Cell Research & Therapy, 2020, 11(1): 144. |
| [18] | Zhou H, Huang S N, Lv X Y, et al. Effect of CUX1 on the proliferation of Hu sheep dermal papilla cells and on the Wnt/β-catenin signaling pathway. Genes, 2023, 14(2): 423. |
| [19] | Urban J, Qi L, Zhao H, et al. Comparison of hair manifestations in cardio-facio-cutaneous and costello syndromes highlights the influence of the RAS pathway on hair growth. Journal of the European Academy of Dermatology and Venereology, 2020, 34(3): 601-607. |
| [20] | Wen F, Kumari N, Taylor Vi J G. RNA-seq and gene set enrichment analysis (GSEA) in peripheral blood mononuclear cells (PBMCs). Methods in Molecular Biology, 2025, 2880: 179-192. |
| [21] | Spitz F, Furlong E E M. Transcription factors: from enhancer binding to developmental control. Nature Reviews Genetics, 2012, 13(9): 613-626. |
| [22] | Christiano A M. Hair follicle epithelial stem cells get their sox on. Cell Stem Cell, 2008, 3(1): 3-4. |
| [23] | Yan R Q. Research of FoxN1 on crimping fomation of wool. Taiyuan: Shanxi Agricultural University, 2019. |
| 闫瑞琴. FoxN1对羊毛弯曲形成作用的研究. 太原: 山西农业大学, 2019. | |
| [24] | Grisanti L, Clavel C, Cai X Q, et al. Tbx18 targets dermal condensates for labeling, isolation, and gene ablation during embryonic hair follicle formation. Journal of Investigative Dermatology, 2013, 133(2): 344-353. |
| [25] | Liu R Q, Liu L D, Xu J D, et al. Identification of potential hub genes in alopecia areata. Experimental Dermatology, 2024, 33(10): e70002. |
| [26] | Wang S H, Wu T Y, Sun J Y, et al. Single-cell transcriptomics reveals the molecular anatomy of sheep hair follicle heterogeneity and wool curvature. Frontiers in Cell and Developmental Biology, 2021, 9: 800157. |
| [27] | Lee H, Kim S Y, Kwon N, et al. Single-cell and spatial transcriptome analysis of dermal fibroblast development in perinatal mouse skin: dynamic lineage differentiation and key driver genes. Journal of Investigative Dermatology, 2024, 144(6): 1238-1250. |
| [28] | Krieg P, Schuppler M, Koesters R, et al. Repetin (Rptn), a new member of the “fused gene” subgroup within the S100 gene family encoding a murine epidermal differentiation protein. Genomics, 1997, 43(3): 339-348. |
| [29] | Huber M, Siegenthaler G, Mirancea N, et al. Isolation and characterization of human repetin, a member of the fused gene family of the epidermal differentiation complex. Journal of Investigative Dermatology, 2005, 124(5): 998-1007. |
| [30] | Pospiech E, Lee S D, Kukla-Bartoszek M, et al. Variation in the RPTN gene may facilitate straight hair formation in Europeans and East Asians. Journal of Dermatological Science, 2018, 91(3): 331-334. |
| [31] | Zhao B R, Wu C L, Sammad A, et al. The fiber diameter traits of Tibetan cashmere goats are governed by the inherent differences in stress, hypoxic, and metabolic adaptations: an integrative study of proteome and transcriptome. BMC Genomics, 2022, 23(1): 191. |
| [32] | Angwin C, Ghali N, van Dijk F S. Case report: Two individuals with AEBP1-related classical-like EDS: Further clinical characterisation and description of novel AEBP1 variants. Frontiers in Genetics, 2023, 14: 1148224. |
| [33] | Damak S, Su H, Jay N P, et al. Improved wool production in transgenic sheep expressing insulin-like growth factor 1. Nature Biotechnology, 1996, 14(2): 185-188. |
| [34] | Jia B, Xi J F, Zhang S Y, et al. The developmental patterns of GH-r, IGF-1 and IGF-IR gene expression in sheep skin. Hereditas (Beijing), 2006, 28(9): 1078-1082. |
| [35] | Fu J Q, Zhang X Y, Wang D, et al. Analysis of the long non-coding and messenger RNA expression profiles in the skin tissue of super Merino and small-tailed Han sheep. Current Issues in Molecular Biology, 2024, 46(9): 9588-9606. |
| [36] | Diao X G, Duan C H, Yao L Y, et al. Melatonin promotes the development of secondary hair follicles in adult cashmere goats by activating the Keap1-Nrf2 signaling pathway and inhibiting the inflammatory transcription factors NFkappaB and AP-1. International Journal of Molecular Sciences, 2023, 24(4): 3403. |
| [37] | Jin M, Fan W Y, Lv S H, et al. LncRNA018392 promotes the proliferation of Liaoning cashmere goat skin fibroblasts by upregulating CSF1R through binding to SPI1. Molecular Biology Reports, 2024, 51(1): 920. |
| [38] | Liu Y, Guerrero-Juarez C F, Xiao F, et al. Hedgehog signaling reprograms hair follicle niche fibroblasts to a hyper-activated state. Developmental Cell, 2022, 57(14): 1758-1775. |
| [39] | Premanand A, Rajkumari B R. Bioinformatic analysis of gene expression data reveals Src family protein tyrosine kinases as key players in androgenetic alopecia. Frontiers in Medicine, 2023, 10: 1108358. |
| [40] | Ichikawa C, Izawa T, Juniantito V, et al. Rat hair follicle-constituting cells labeled by a newly-developed somatic stem cell-recognizing antibody: a possible marker of hair follicle development. Histology and Histopathology, 2013, 28(2): 257-268. |
| [41] | Sedov E, Koren E, Chopra S, et al. THY1-mediated mechanisms converge to drive YAP activation in skin homeostasis and repair. Nature Cell Biology, 2022, 24(7): 1049-1063. |
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