[1]Louis H A,Pino J D,Schmeichel K L,et al. Comparison of three members of the cysteine-rich protein family reveals functional conservation and divergent patterns of gene expression[J]. Journal of Biological Chemistry,1997,272(43):27484-27491.
[2]Bach I. The LIM domain:regulation by association[J]. Mechanisms of Development,2000,91(1/2):5-17.
[3]Ostendorff H P,Peirano R I,Peters M A,et al. Ubiquitination-dependent cofactor exchange on LIM homeodomain transcription factors[J]. Nature,2002,416(6876):99-103.
[4]Sánchez-García I,Rabbits T H. The LIM domain:a new structural motif found in zinc-finger-like proteins[J]. Trends in Genetics,1994,10(9):315-320.
[5]Morgan M J,Madgwick A J A. The fourth member of the FHL family of LIM proteins is expressed exclusively in the testis[J]. Biochemical and Biophysical Research Communications,1999,255(2):251-255.
[6]Xie Z Q,Xu Y,Wei X J,et al. Four and a half LIM domains protein 2 mediates bortezomib-induced osteogenic differentiation of mesenchymal stem cells in multiple myeloma through p53 signaling and β-catenin nuclear enrichment[J]. Frontiers in Oncology,2021,11:729799.
[7]Lee S M Y,Tsui S K W,Chan K K,et al. Chromosomal mapping of a skeletal muscle specific LIM-only protein FHL3 to the distal end of the short arm of human chromosome 1[J]. Somatic Cell and Molecular Genetics,1998,24(3):197-202.
[8]Coghill I D,Brown S,Cottle D L,et al. FHL3 is an actin-binding protein that regulates α-actinin-mediated actin bundling:FHL3 localizes to actin stress fibers and enhances cell spreading and stress fiber disassembly[J]. The Journal of Biological Chemistry,2003,278(26):24139-24152.
[9]Han S S,Cui C,Wang Y,et al. FHL3 negatively regulates the differentiation of skeletal muscle satellite cells in chicken[J]. 3 Biotech,2019,9(6):206.
[10]Cottle D L,McGrath M J,Cowling B S,et al. FHL3 binds MyoD and negatively regulates myotube formation[J]. Journal of Cell Science,2007,120(Pt 8):1423-1435.
[11]Zhang Y X,Li W T,Zhu M F,et al. FHL3 differentially regulates the expression of MyHC isoforms through interactions with MyoD and pCREB[J]. Cellular Signalling,2016,28(1):60-73.
[12]Zuo B,Xiong Y Z,Deng C Y,et al. cDNA cloning,genomic structure and polymorphism of the Porcine FHL3 gene[J]. Animal Genetics,2004,35(3):230-233.
[13]Zuo B,Xiong Y Z,Yang H,et al. Full-length cDNA,expression pattern and association analysis of the Porcine FHL3 gene[J]. Asian-Australasian Journal of Animal Sciences,2007,20(10):1473-1477.
[14]Damon M,Denieul K,Vincent A,et al. Associations between muscle gene expression pattern and technological and sensory meat traits highlight new biomarkers for pork quality assessment[J]. Meat Science,2013,95(3):744-754.
[15]Rohrer G A,Nonneman D J,Miller R K,et al. Association of single nucleotide polymorphism (SNP) markers in candidate genes and QTL regions with pork quality traits in commercial pigs[J]. Meat Science,2012,92(4):511-518.
[16]张鑫. 基于RNA-Seq技术筛选寒泊羊肌肉生长发育相关基因的研究[D]. 邯郸:河北工程大学,2020:39-41.
[17]安清明,王星,吴震洋,等. 基于转录组挖掘不同性别贵州白山羊肌肉生长发育的关键基因及PI3K/ATK信号通路分析[J]. 华北农学报,2022,37(3):213-222.
[18]李文涛. 利用转基因小鼠模型研究FHL3基因对不同肌纤维类型形成的影响[D]. 武汉:华中农业大学,2016:43-46.
[19]许海洋. FHL3基因调控肌肉生长和肌纤维类型转化的功能研究[D]. 武汉:华中农业大学,2018:56-62.
[20]Meeson A P,Shi X Z,Alexander M S,et al. Sox15 and Fhl3 transcriptionally coactivate Foxk1 and regulate myogenic progenitor cells[J]. The EMBO Journal,2007,26(7):1902-1912.
[21]康建兵,罗卫星,王锋,等. 贵州白山羊LEPR基因多态性[J]. 基因组学与应用生物学,2015,34(9):1870-1874.
[22]陈志,罗卫星,刘若余,等. 贵州白山羊GFI1B基因多态性与生长性状的相关性[J]. 基因组学与应用生物学,2013,32(2):159-164.
[23]孙振梅,陈祥,龙威海,等. 贵州地方山羊ADIPOQ基因外显子1和3多态性研究[J]. 基因组学与应用生物学,2015,34(3):500-505.
[24]贾小姣,陈亚乐,王诗佳,等. 9个山羊品种微卫星DNA遗传多样性分析[J]. 安徽农业大学学报,2019,46(5):779-784.
[25]易爽,刘宏涛,张文涛,等. 放牧务川白山羊羔羊生产性能相关性研究[J]. 湖北畜牧兽医,2021,42(11):11-13.