Home > Archive>Volume 48, Issue 9, 2024 >099601-099601. DOI:10.11964/jfc.20240114344
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Advances of fish muscle growth
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    Abstract:

    Fish is a vital source of animal-based protein due to its abundant muscle content. The objective of fish aquaculture is to enhance muscle fibers hyperplasia and hypertrophy through optimal breeding conditions and technologies, thereby accelerating muscle growth and increasing the economic viability of industry. The fundamental processes of fish muscle growth involve hyperplasia and hypertrophy of muscle fibers, coupled with the ongoing fusion of muscle cells, culminating in the development of larger myotubes or thicker myofibers. Before the differentiation of myotubes into two distinct muscle fibers—white (fast) and red (slow) muscle tissues—the cells undergo gradual specilization, assembling and expressing muscle-specific proteins, including various myosin isoforms. This review summarizes the latest insights into fish muscle growth, encompassing cell proliferation, migration, differentiation, cell-cell fusion and muscle fibers formation. It also identifies key regulatory factors (pax3, pax7, myf5, myod, myog and mrf4) and the GH-IGF signaling pathway that influence muscle development. The review elucidates the transition of mononucleated muscle cells into syncytial fibers during growth and development. Notably, two novel gene orthologs, mymk and mymx, are implicated in muscle cell fusion and are conserved across vertebrate. The determinants of fusion, such as cell adhesion molecules, fusogens, and actin cytoskeletal regulators, which facilitate the formation of finger-like projections, are crucial for muscle cell fusion. This review further explores potential aquatic genetic resources for breeding to enhance muscle growth and discusses dietary approaches to improve fish meat quality. By integrating these findings, we introduce a novel perspective on muscle growth enhancement through nutritional and genetic interventions. Collectively, this review offers a comprehensive overview of aquaculture traits development, focusing on rapid growth and enhanced muscle quality.

    Reference
    [1] 王丹, 吴反修. 中国渔业统计年鉴[M]. 北京: 中国农业出版社, 2023.
    Wang D, Wu F X. China Fishery Statistical yearbook[M]. Beijing: China Agriculture Press, 2023 (inChinese).
    [2] 石军, 褚武英, 张建社. 鱼类肌肉生长分化与基因表达调控[J]. 水生生物学报, 2013, 37(6): 1145-1152.
    Shi J, Chu W Y, Zhang J S. Muscle growth, differentiation and gene expression regulation in fish[J]. Acta Hydrobiologica Sinica, 2013, 37(6): 1145-1152 (in Chinese).
    [3] Talbot J, Maves L. Skeletal muscle fiber type: using insights from muscle developmental biology to dissect targets for susceptibility and resistance to muscle disease[J]. Wiley Interdisciplinary Reviews: Developmental Biology, 2016, 5(4): 518-534.
    [4] Wu M P, Chang N C, Chung C L, et al. Analysis of titin in red and white muscles: crucial role on muscle contractions using a fish model[J]. BioMed Research International, 2018, 2018: 1-11.
    [5] Jackson H E, Ingham P W. Control of muscle fibre-type diversity during embryonic development: the zebrafish paradigm[J]. Mechanisms of Development, 2013, 130(9-10): 447-457.
    [6] Hromowyk K J, Talbot J C, Martin B L, et al. Cell fusion is differentially regulated in zebrafish post-embryonic slow and fast muscle[J]. Developmental Biology, 2020, 462(1): 85-100.
    [7] Biga P R, Goetz F W. Zebrafish and giant danio as models for muscle growth: determinate vs. indeterminate growth as determined by morphometric analysis[J]. American Journal of Physiology-Regulatory, Integrative and Comparative Physiology, 2006, 291(5): R1327-R1337.
    [8] Perez É S, Duran B O S, Zanella B T T, et al. Understanding fish muscle biology in the indeterminate growth species pacu (Piaractus mesopotamicus)[J]. Comparative Biochemistry and Physiology Part A: Molecular & Integrative Physiology, 2023, 285: 111502.
    [9] Stickland N C. Growth and development of muscle fibres in the rainbow trout (Salmo gairdneri) [J]. Journal of Anatomy, 1983, 137(Pt 2): 323.
    [10] Wang Y X, Rudnicki M A. Satellite cells, the engines of muscle repair[J]. Nature Reviews Molecular Cell Biology, 2012, 13(2): 127-133.
    [11] Relaix F, Rocancourt D, Buckingham M. A Pax3/Pax7-dependent population of skeletal muscle progenitor cells[J]. Nature, 2005, 435(7044): 948-953.
    [12] Zammit P S, Partridge T A, Yablonka-Reuveni Z. The skeletal muscle satellite cell: the stem cell that came in from the cold[J]. Journal of Histochemistry and Cytochemistry, 2006, 54: 1177-1191.
    [13] Abmayr S M, Pavlath G K. Myoblast fusion: lessons from flies and mice[J]. Development, 2012, 139(4): 641-656.
    [14] Buckingham M, Relaix F. The role of Pax genes in the development of tissues and organs: Pax3 and Pax7 regulate muscle progenitor cell functions[J]. Annual Review of Cell and Developmental Biology, 2007, 23: 645-673.
    [15] Tremblay P, Dietrich S, Mericskay M, et al. A crucial role for Pax3 in the development of the hypaxial musculature and the long-range migration of muscle precursors[J]. Developmental Biology, 1998, 203: 49-61.
    [16] Maroto M, Reshef R, Münsterberg A E, et al. Ectopic Pax-3 activates MyoD and Myf-5 expressionin embryonic mesoderm and neural tissue[J]. Cell, 1997, 89: 139-148.
    [17] Seale P, Sabourin L A, Girgis-Gabardo A, et al. Pax7 is required for the specification of myogenic satellite cells[J]. Cell, 2000, 102: 777-786.
    [18] Berberoglu M A, Gallagher T L, Morrow Z T, et al. Satellite-like cells contribute to pax7-dependent skeletal muscle repair in adult zebrafish[J]. Developmental Biology, 2017, 424(2): 162-180.
    [19] Wang M, Song W, Jin C, et al. Pax3 and pax7 exhibit distinct and overlapping functions in marking muscle satellite cells and muscle repair in a marine teleost, Sebastes schlegelii[J]. International Journal of Molecular Sciences, 2021, 22(7): 3769.
    [20] Rallière C, Jagot S, Sabin N, et al. Dynamics of pax7 expression during development, muscle regeneration, and in vitro differentiation of satellite cells in the trout[J]. BioRxiv, 2023: 2023.07. 19.549701.
    [21] Keenan S R, Currie P D. The developmental phases of zebrafish myogenesis[J]. Journal of Developmental Biology, 2019, 7(2): 12.
    [22] Massari M E, Murre C. Helix-loop-helix proteins: regulators of transcription in eucaryotic organisms[J]. Molecular and Cellular Biology, 2000, 20(2): 429-440.
    [23] Bentzinger C F, Wang Y X, Rudnicki M A. Building muscle: molecular regulation of myogenesis[J]. Cold Spring Harbor Perspectives in Biology, 2012, 4(2): a008342.
    [24] Buckingham M, Rigby P W J. Gene regulatory networks and transcriptional mechanisms that control myogenesis[J]. Developmental cell, 2014, 28(3): 225-238.
    [25] Buckingham M. Making muscle in mammals[J]. Trends Genet, 1992, 8: 144-148.
    [26] Ott M O, Bober E, Lyons G, et al. Early expression of the myogenic regulatory gene, myf-5, in precursor cells of skeletal muscle in the mouse embryo[J]. Development, 1991, 111(4): 1097-1107.
    [27] Rudnicki M A, Braun T, Hinuma S, et al. Inactivation of MyoD in mice leads to up-regulation of the myogenic HLH gene Myf-5 and results in apparently normal muscle development[J]. Cell, 1992, 71(3): 383-390.
    [28] Rudnicki M A, Schnegelsberg P N J, Stead R H, et al. MyoD or Myf-5 is required for the formation of skeletal muscle[J]. Cell, 1993, 75(7): 1351-1359.
    [29] Kassar-Duchossoy L, Gayraud-Morel B, Gomès D, et al. Mrf4 determines skeletal muscle identity in Myf5: Myod double-mutant mice[J]. Nature, 2004, 431(7007): 466-471.
    [30] Hasty P, Bradley A, Morris J H, et al. Muscle deficiency and neonatal death in mice with a targeted mutation in the myogenin gene[J]. Nature, 1993, 364(6437): 501-506.
    [31] De Almeida F L A, Pessotti N S, Pinhal D, et al. Quantitative expression of myogenic regulatory factors MyoD and myogenin in pacu (Piaractus mesopotamicus) skeletal muscle during growth[J]. Micron, 2010, 41(8): 997-1004.
    [32] Zhu X, Li Y L, Liu L, et al. Molecular characterization of Myf5 and comparative expression patterns of myogenic regulatory factors in Siniperca chuatsi[J]. Gene Expression Patterns, 2016, 20(1): 1-10.
    [33] Duran B O S, Fernandez G J, Mareco E A, et al. Differential microRNA expression in fast-and slow-twitch skeletal muscle of Piaractus mesopotamicus during growth[J]. PLoS One, 2015, 10(11): e0141967.
    [34] Hammond C L, Hinits Y, Osborn D P S, et al. Signals and myogenic regulatory factors restrict pax3 and pax7 expression to dermomyotome-like tissue in zebrafish[J]. Developmental Biology, 2007, 302(2): 504-521.
    [35] Hinits Y, Osborn D P S, Hughes S M. Differential requirements for myogenic regulatory factors distinguish medial and lateral somitic, cranial and fin muscle fibre populations[J]. Development, 2009, 136(3): 403-14.
    [36] Ganassi M, Badodi S, Ortuste Quiroga H P, et al. Myogenin promotes myocyte fusion to balance fibre number and size[J]. Nature Communications, 2018, 9: 4232.
    [37] Hinits Y, Osborn D P S, Carvajal J J, et al. Mrf4 (myf6) is dynamically expressed in differentiated zebrafish skeletal muscle[J]. Gene Expression Patterns, 2007, 7(7): 738-745.
    [38] Schnapp E, Pistocchi A S, Karampetsou E, et al. Induced early expression of mrf4 but not myog rescues myogenesis in the myod/myf5 double-morphant zebrafish embryo[J]. Journal of Cell Science, 2009, 122(4): 481-488.
    [39] Chen E H, Olson E N. Unveiling the mechanisms of cell-cell fusion[J]. Science, 2005, 308(5720): 369-373.
    [40] Di Gioia S A, Connors S, Matsunami N, et al. A defect in myoblast fusion underlies Carey-Fineman-Zitersyndrome[J]. Nature Communication, 2017, 8: 16077.
    [41] Alrohaif H, Töpf A, Evangelista T, et al. Whole-exome sequencing identifies mutations in MYMK in a mild form of Carey-Fineman-Ziter syndrome[J]. Neurology Genetics, 2018, 4(2): 1-3.
    [42] Millay D P. Regulation of the myoblast fusion reaction for muscle development, regeneration, and adaptations[J]. Experimental Cell Research, 2022, 415(2): 113134.
    [43] Millay D P, O’Rourke J R, Sutherland L B, et al. Myomaker is a membrane activator of myoblast fusion and muscle formation[J]. Nature, 2013, 499(7458): 301-305.
    [44] Millay D P, Gamage D G, Quinn M E, et al. Structure-function analysis of myomaker domains required for myoblast fusion[J]. Proceedings of the National Academy of Sciences, 2016, 113(8): 2116-2121.
    [45] Luo W, Li E, Nie Q, et al. Myomaker, regulated by MYOD, MYOG and miR-140-3p, promotes chicken myoblast fusion[J]. International Journal of Molecular Sciences, 2015, 16(11): 26186-26201.
    [46] Ma J, Zhu Y, Zhou X, et al. miR-205 regulates the fusion of porcine myoblast by targeting the myomaker gene[J]. Cells, 2023, 12(8): 1107.
    [47] Bi P, Ramirez-Martinez A, Li H, et al. Control of muscle formation by the fusogenic micropeptide myomixer[J]. Science, 2017, 356(6335): 323-327.
    [48] Quinn M E, Goh Q, Kurosaka M, et al. Myomerger induces fusion of non-fusogenic cells and is required for skeletal muscle development[J]. Nature Communications, 2017, 8(1): 15665.
    [49] Zhang Q, Vashisht A A, O’Rourke J, et al. The microprotein Minion controls cell fusion and muscle formation[J]. Nature Communications, 2017, 8(1): 15664.
    [50] Leikina E, Gamage D G, Prasad V, et al. Myomaker and myomerger work independently to control distinct steps of membrane remodeling during myoblast fusion[J]. Developmental Cell, 2018, 46(6): 767-780.
    [51] Mendieta-Serrano M A, Dhar S, Ng B H, et al. Slow muscles guide fast myocyte fusion to ensure robust myotome formation despite the high spatiotemporal stochasticity of fusion events[J]. Developmental Cell, 2022, 57(17): 2095-2110.
    [52] Shi J, Bi P, Pei J, et al. Requirement of the fusogenic micropeptide myomixer for muscle formation in zebrafish[J]. Proceedings of the National Academy of Sciences, 2017, 114(45): 11950-11955.
    [53] Shi J, Cai M, Si Y, et al. Knockout of myomaker results in defective myoblast fusion, reduced muscle growth and increased adipocyte infiltration in zebrafish skeletal muscle[J]. Human Molecular Genetics, 2018, 27(20): 3542-3554.
    [54] Wu P, Yong P, Zhang Z, et al. Loss of myomixer results in defective myoblast fusion, impaired muscle growth, and severe myopathy in zebrafish[J]. Marine Biotechnology, 2022, 24(5): 1023-1038.
    [55] Landemaine A, Ramirez-Martinez A, Monestier O, et al. Trout myomaker contains 14 minisatellites and two sequence extensions but retains fusogenic function[J]. Journal of Biological Chemistry, 2019, 294(16): 6364-6374.
    [56] Perello-Amoros M, Rallière C, Gutiérrez J, et al. Myomixer is expressed during embryonic and post-larval hyperplasia, muscle regeneration and differentiation of myoblats in rainbow trout (Oncorhynchus mykiss)[J]. Gene, 2021, 790: 145688.
    [57] Huang Y, Wu S, Zhang J, et al. Methylation status and expression patterns of myomaker gene play important roles in postnatal development in the Japanese flounder (Paralichthys olivaceus)[J]. General and Comparative Endocrinology, 2019, 280: 104-114.
    [58] Perelló-Amorós M, Otero-Tarrazón A, Jorge-Pedraza V, et al. Myomaker and Myomixer characterization in gilthead sea bream under different myogenesis conditions[J]. International Journal of Molecular Sciences, 2022, 23(23): 14639.
    [59] Zhu K C, Liu B S, Guo H Y, et al. Functional analysis of two MyoDs revealed their role in the activation of myomixer expression in yellowfin seabream (Acanthopagrus latus)(Hottuyn, 1782)[J]. International Journal of Biological Macromolecules, 2020, 156: 1081-1090.
    [60] Zhu K, He P, Liu B, et al. Identification of myomaker in yellowfin seabream (Acanthopagrus latus)(Hottuyn, 1782) and its transcriptional regulation by two MyoDs[J]. Pakistan Journal of Zoology, 2021, 53(1): 227.
    [61] Zhang H, Wen J, Bigot A, et al. Human myotube formation is determined by MyoD-Myomixer/Myomaker axis[J]. Science Advances, 2020, 6(51): eabc4062.
    [62] Zhang H, Shang R, Kim K, et al. Evolution of a chordate-specific mechanism for myoblast fusion[J]. Science Advances, 2022, 8(35): eadd2696.
    [63] Srinivas B P, Woo J, Leong W Y, et al. A conserved molecular pathway mediates myoblast fusion in insects and vertebrates[J]. Nature Genetics, 2007, 39(6): 781-786.
    [64] Kim J H, Jin P, Duan R, et al. Mechanisms of myoblast fusion during muscle development[J]. Current Opinion in Genetics & Development, 2015, 32: 162-170.
    [65] Luo Z, Shi J, Pandey P, et al. The cellular architecture and molecular determinants of the zebrafish fusogenic synapse[J]. Developmental Cell, 2022, 57(13): 1582-1597.
    [66] Powell G T, Wright G J. Jamb and jamc are essential for vertebrate myocyte fusion[J]. PLoS Biology, 2011, 9(12): e1001216.
    [67] Si Y, Wen H, Du S. Genetic mutations in jamb, jamc, and myomaker revealed different roles on myoblast fusion and muscle growth[J]. Marine Biotechnology, 2019, 21: 111-123.
    [68] Massarwa R, Carmon S, Shilo B Z, et al. WIP/WASp-based actin-polymerization machinery is essential for myoblast fusion in Drosophila[J]. Developmental Cell, 2007, 12(4): 557-569.
    [69] Richardson B E, Beckett K, Nowak S J, et al. SCAR/WAVE and Arp2/3 are crucial for cytoskeletal remodeling at the site of myoblast fusion[J]. Development, 2007, 134(24): 4357-4367.
    [70] Sohn R L, Huang P, Kawahara G, et al. A role for nephrin, a renal protein, in vertebrate skeletal muscle cell fusion[J]. Proceedings of the National Academy of Sciences, 2009, 106(23): 9274-9279.
    [71] Moore C A, Parkin C A, Bidet Y, et al. A role for the Myoblast city homologues Dock1 and Dock5 and the adaptor proteins Crk and Crk-like in zebrafish myoblast fusion[J]. Development, 2007, 134(17): 3145-3153.
    [72] Baas D, Caussanel-Boude S, Guiraud A, et al. CKIP-1 regulates mammalian and zebrafish myoblast fusion[J]. Journal of Cell Science, 2012, 125(16): 3790-3800.
    [73] 石军, 褚武英, 张建社. 肌肉特异表达 microRNA 的功能研究[J]. 水生生物学报, 2015, 39(6): 1224-1230.
    Shi J, Chu W Y, Zhang J S. The functional studies of muscle-specific microRNAs[J]. Acta Hydrobiologica Sinica, 2015, 39(6): 1224-1230 (in Chinese).
    [74] Koganti P, Yao J, Cleveland B M. Molecular mechanisms regulating muscle plasticity in fish[J]. Animals, 2020, 11(1): 61.
    [75] O'Rourke J R, Georges S A, Seay H R, et al. Essential role for Dicer during skeletal muscle development[J]. Developmental Biology, 2007, 311(2): 359-368.
    [76] Chen J F, Mandel E M, Thomson J M, et al. The role of microRNA-1 and microRNA-133 in skeletal muscle proliferation and differentiation[J]. Nature Genetics, 2006, 38(2): 228-233.
    [77] Chen J F, Tao Y, Li J, et al. microRNA-1 and microRNA-206 regulate skeletal muscle satellite cell proliferation and differentiation by repressing Pax7[J]. Journal of Cell Biology, 2010, 190(5): 867-879.
    [78] Rosenberg M I, Georges S A, Asawachaicharn A, et al. MyoD inhibits Fstl1 and Utrn expression by inducing transcription of miR-206[J]. Journal of Cell Biology, 2006, 175(1): 77-85.
    [79] Mishima Y, Abreu-Goodger C, Staton A A, et al. Zebrafish miR-1 and miR-133 shape muscle gene expression and regulate sarcomeric actin organization[J]. Genes & Development, 2009, 23(5): 619-632.
    [80] Koganti P P, Wang J, Cleveland B, et al. Estradiol regulates expression of miRNAs associated with myogenesis in rainbow trout[J]. Molecular and Cellular Endocrinology, 2017, 443: 1-14.
    [81] Fu Y, Shi Z, Wu M, et al. Identification and differential expression of microRNAs during metamorphosis of the Japanese flounder (Paralichthys olivaceus)[J]. PloS One, 2011, 6(7): e22957.
    [82] Chu W Y, Liu L S, Li Y L, et al. Systematic identification and differential expression profiling of microRNAs from white and red muscles of Siniperca chuatsi[J]. Current Molecular Medicine, 2013, 13(8): 1397-1407.
    [83] Huang C W, Li Y H, Hu S Y, et al. Differential expression patterns of growth-related microRNAs in the skeletal muscle of Nile tilapia (Oreochromis niloticus)[J]. Journal of Animal Science, 2012, 90(12): 4266-4279.
    [84] Xia J H, He X P, Bai Z Y, et al. Identification and characterization of 63 MicroRNAs in the Asian seabass Lates calcarifer[J]. PLoS One, 2011, 6(3): e17537.
    [85] Yan X, Ding L, Li Y, et al. Identification and profiling of microRNAs from skeletal muscle of the common carp[J]. PloS One, 2012, 7(1): e30925.
    [86] Yan B, Guo J T, Zhu C, et al. miR-203b: a novel regulator of MyoD expression in tilapia skeletal muscle[J]. Journal of Experimental Biology, 2013, 216(3): 447-451.
    [87] Chen L, Wu P, Guo X H, et al. miR-143: a novel regulator of MyoD expression in fast and slow muscles of Siniperca chuatsi[J]. Current Molecular Medicine, 2014, 14(3): 370-375.
    [88] Yan B, Zhu C D, Guo J T, et al. miR-206 regulates the growth of the teleost tilapia (Oreochromis niloticus) through the modulation of IGF-1 gene expression[J]. Journal of Experimental Biology, 2013, 216(7): 1265-1269.
    [89] Flynt A S, Li N, Thatcher E J, et al. Zebrafish miR-214 modulates Hedgehog signaling to specify muscle cell fate[J]. Nature Genetics, 2007, 39(2): 259-263.
    [90] Nachtigall P G, Dias M C, Carvalho R F, et al. MicroRNA-499 expression distinctively correlates to target genes sox6 and rod1 profiles to resolve the skeletal muscle phenotype in Nile tilapia[J]. PLoS One, 2015, 10(3): e0119804.
    [91] Duran B O S, Dal-Pai-Silva M, Garcia de la Serrana D. Rainbow trout slow myoblast cell culture as a model to study slow skeletal muscle, and the characterization of mir-133 and mir-499 families as a case study[J]. Journal of Experimental Biology, 2020, 223(2): jeb216390.
    [92] Lin C Y, Chen J S, Loo M R, et al. MicroRNA-3906 regulates fast muscle differentiation through modulating the target gene homer-1b in zebrafish embryos[J]. PLoS One, 2013, 8(7): e70187.
    [93] Chu W Y, Zhang F L, Song R, et al. Proteomic and microRNA transcriptome analysis revealed the microRNA-SmyD1 network regulation in skeletal muscle fibers performance of Chinese perch[J]. Scientific Reports, 2017, 7(1): 16498.
    [94] Yang S, Liu Z, Yan Z, et al. Improvement of skeletal muscle growth by GH/IGF growth-axis contributes to growth performance in commercial fleshy sturgeon[J]. Aquaculture, 2021, 543: 736929.
    [95] Fuentes E N, Valdés J A, Molina A, et al. Regulation of skeletal muscle growth in fish by the growth hormone-insulin-like growth factor system[J]. General and Comparative Endocrinology, 2013, 192: 136-148.
    [96] Vélez E J, Lutfi E, Azizi S, et al. Understanding fish muscle growth regulation to optimize aquaculture production[J]. Aquaculture, 2017, 467: 28-40.
    [97] Reindl K M, Sheridan M A. Peripheral regulation of the growth hormone-insulin-like growth factor system in fish and other vertebrates[J]. Comparative Biochemistry and Physiology Part A: Molecular & Integrative Physiology, 2012, 163(3-4): 231-245.
    [98] Rius-Francino M, Acerete L, Jiménez-Amilburu V, et al. Differential effects on proliferation of GH and IGFs in sea bream (Sparus aurata) cultured myocytes[J]. General and Comparative Endocrinology, 2011, 172(1): 44-49.
    [99] Levesque H M, Shears M A, Fletcher G L, et al. Myogenesis and muscle metabolism in juvenile Atlantic salmon (Salmo salar) made transgenic for growth hormone[J]. Journal of Experimental Biology, 2008, 211(1): 128-137.
    [100] Devlin R H, Biagi C A, Yesaki T Y, et al. Growth of domesticated transgenic fish[J]. Nature, 2001, 409(6822): 781-782.
    [101] Figueiredo M A, Lanes C F C, Almeida D V, et al. Improving the production of transgenic fish germlines: in vivo evaluation of mosaicism in zebrafish (Danio rerio) using a green fluorescent protein (GFP) and growth hormone cDNA transgene co-injection strategy[J]. Genetics and Molecular Biology, 2007, 30: 31-36.
    [102] Wang Y, Hu W, Wu G, et al. Genetic analysis of “all-fish” growth hormone gene trans ferred carp (Cyprinus carpio L. ) and its F1 generation[J]. Chinese Science Bulletin, 2001, 46: a1-a4.
    [103] Li D, Lou Q, Zhai G, et al. Hyperplasia and cellularity changes in IGF-1-overexpressing skeletal muscle of crucian carp[J]. Endocrinology, 2014, 155(6): 2199-2212.
    [104] Jiménez-Amilburu V, Salmerón C, Codina M, et al. Insulin-like growth factors effects on the expression of myogenic regulatory factors in gilthead sea bream muscle cells[J]. General and Comparative Endocrinology, 2013, 188: 151-158.
    [105] Bower N I, Johnston I A. Transcriptional regulation of the IGF signaling pathway by amino acids and insulin-like growth factors during myogenesis in Atlantic salmon[J]. PLoS One, 2010, 5(6): e11100.
    [106] Ledford H. Salmon is first transgenic animal to win U.S. approval for food[J]. Nature, 2015, 19: 2015.
    [107] Cui Z, Liu Y, Wang W, et al. Genome editing reveals dmrt1 as an essential male sex-determining gene in Chinese tongue sole (Cynoglossus semilaevis)[J]. Scientific reports, 2017, 7(1): 42213.
    [108] Dong Q, Nie C H, Wu Y M, et al. Generation of blunt snout bream without intermuscular bones by runx2b gene mutation[J]. Aquaculture, 2023, 567: 739263.
    [109] McPherron A C, Lawler A M, Lee S J. Regulation of skeletal muscle mass in mice by a new TGF-β superfamily member[J]. Nature, 1997, 387(6628): 83-90.
    [110] Grobet L, Royo Martin L J, Poncelet D, et al. A deletion in the bovine myostatin gene causes the double-muscled phenotype in cattle[J]. Nature Genetics, 1997, 17(1): 71-74.
    [111] Mosher D S, Quignon P, Bustamante C D, et al. A mutation in the myostatin gene increases muscle mass and enhances racing performance in heterozygote dogs[J]. PLoS Genetics, 2007, 3(5): e79.
    [112] Li R, Zeng W, Ma M, et al. Precise editing of myostatin signal peptide by CRISPR/Cas9 increases the muscle mass of Liang Guang Small Spotted pigs[J]. Transgenic Research, 2020, 29: 149-163.
    [113] Pie M R, Alvares L E. Evolution of myostatin in vertebrates: is there evidence for positive selection?[J]. Molecular Phylogenetics and Evolution, 2006, 41(3): 730-734.
    [114] Wu Y, Wu T, Yang L, et al. Generation of fast growth Nile tilapia (Oreochromis niloticus) by myostatin gene mutation[J]. Aquaculture, 2023, 562: 738762.
    [115] Gao Y, Dai Z, Shi C, et al. Depletion of myostatin b promotes somatic growth and lipid metabolism in zebrafish[J]. Frontiers in Endocrinology, 2016, 7: 88.
    [116] Wang C, Chen Y L, Bian W P, et al. Deletion of mstna and mstnb impairs the immune system and affects growth performance in zebrafish[J]. Fish & Shellfish Immunology, 2018, 72: 572-580.
    [117] Chiang Y A, Kinoshita M, Maekawa S, et al. TALENs-mediated gene disruption of myostatin produces a larger phenotype of medaka with an apparently compromised immune system[J]. Fish & Shellfish Immunology, 2016, 48: 212-220.
    [118] Yeh Y C, Kinoshita M, Ng T H, et al. Using CRISPR/Cas9-mediated gene editing to further explore growth and trade-off effects in myostatin-mutated F4 medaka (Oryzias latipes)[J]. Scientific Reports, 2017, 7(1): 11435.
    [119] Kishimoto K, Washio Y, Yoshiura Y, et al. Production of a breed of red sea bream Pagrus major with an increase of skeletal muscle mass and reduced body length by genome editing with CRISPR/Cas9[J]. Aquaculture, 2018, 495: 415-427.
    [120] Ohama M, Washio Y, Kishimoto K, et al. Growth performance of myostatin knockout red sea bream Pagrus major juveniles produced by genome editing with CRISPR/Cas9[J]. Aquaculture, 2020, 529: 735672.
    [121] Zhang X, Wang F, Dong Z, et al. A new strain of yellow catfish carrying genome edited myostatin alleles exhibits double muscling phenotype with hyperplasia[J]. Aquaculture, 2020, 523: 735187.
    [122] Sun Y, Zheng G D, Nissa M, et al. Disruption of mstna and mstnb gene through CRISPR/Cas9 leads to elevated muscle mass in blunt snout bream (Megalobrama amblycephala)[J]. Aquaculture, 2020, 528: 735597.
    [123] Kim J, Cho J Y, Kim J W, et al. CRISPR/Cas9-mediated myostatin disruption enhances muscle mass in the olive flounder Paralichthys olivaceus[J]. Aquaculture, 2019, 512: 734336.
    [124] Tao B, Tan J, Chen L, et al. CRISPR/Cas9 system-based myostatin-targeted disruption promotes somatic growth and adipogenesis in loach, Misgurnus anguillicaudatus[J]. Aquaculture, 2021, 544: 737097.
    [125] Zhong Z, Niu P, Wang M, et al. Targeted disruption of sp7 and myostatin with CRISPR-Cas9 results in severe bone defects and more muscular cells in common carp[J]. Scientific Reports, 2016, 6(1): 22953.
    [126] Shahi N, Mallik S K, Sarma D. Muscle growth in targeted knockout common carp (Cyprinus carpio) mstn gene with low off-target effects[J]. Aquaculture, 2022, 547: 737423.
    [127] Khalil K, Elayat M, Khalifa E, et al. Generation of myostatin gene-edited channel catfish (Ictalurus punctatus) via zygote injection of CRISPR/Cas9 system[J]. Scientific Reports, 2017, 7(1): 7301.
    [128] Zhang X, Wang F, Ou M, et al. Effects of Myostatin b knockout on offspring body length and skeleton in yellow catfish (Pelteobagrus fulvidraco)[J]. Biology, 2023, 12(10): 1331.
    [129] Sun Y, Yu X, Tong J. Polymorphisms in myostatin gene and associations with growth traits in the common carp (Cyprinus carpio L. )[J]. International Journal of Molecular Sciences, 2012, 13(11): 14956-61.
    [130] Wang Y, Wang X, Meng X, et al. Identification of two SNPs in myostatin (MSTN) gene of Takifugu rubripes and their association with growth traits[J]. Molecular and Cellular Probes, 2014, 28(4): 200-3.
    [131] Li M J, Liu W S, Luo W, et al. Polymorphisms and their association with growth traits in the growth hormone gene of yellow catfish, Pelteobagrus fulvidraco[J]. Aquaculture, 2017, 469: 117-23.
    [132] Jaser S K, Dias M A, Lago A D, et al. Single nucleotide polymorphisms in the growth hormone gene of Oreochromis niloticus and their association with growth performance[J]. Aquaculture Research, 2017, 48(12): 5835-45.
    [133] Sun C F, Sun H L, Dong J J, et al. Correlation analysis of mandarin fish (Siniperca chuatsi) growth hormone gene polymorphisms and growth traits[J]. Journal of Genetics, 2019, 98: 1-10.
    [134] Tsai H Y, Hamilton A, Guy D R, et al. Single nucleotide polymorphisms in the insulin-like growth factor 1 (IGF 1) gene are associated with growth‐related traits in farmed Atlantic salmon[J]. Animal Genetics, 2014, 45(5): 709-15.
    [135] Özcan Gökçek E, Işık R. Associations between genetic variants of the insulin-like growth factor I (IGF-I) gene and growth traits in European sea bass (Dicentrarchus labrax, L. )[J]. Fish Physiology and Biochemistry, 2020, 46(3): 1131-8.
    [136] Hao Y, Jia X, Yuan L, et al. Genome-wide association study reveals growth-related SNPs and candidate genes in grass carp (Ctenopharyngodon idella)[J]. Aquaculture, 2023, 577: 739979.
    [137] Zhou Y, Fu H C, Wang Y Y, et al. Genome-wide association study reveals growth-related SNPs and candidate genes in mandarin fish (Siniperca chuatsi)[J]. Aquaculture, 2022, 550: 737879.
    [138] Zhu F, Sun H, Jiang L, et al. Genome-wide association study for growth-related traits in golden pompano (Trachinotus ovatus)[J]. Aquaculture, 2023, 572: 739549.
    [139] Yu Y, Wan S M, Zhang S M, et al. Identification of SNPs and candidate genes associated with growth using GWAS and transcriptome analysis in Coilia nasus[J]. Aquaculture, 2024, 586: 740777.
    [140] Salem M, Al-Tobasei R, Ali A, et al. Genome-wide association analysis with a 50K transcribed gene SNP-chip identifies QTL affecting muscle yield in rainbow trout[J]. Frontiers in Genetics, 2018, 9: 402818.
    [141] Zhou Z, Han K, Wu Y, et al. Genome-wide association study of growth and body-shape-related traits in large yellow croaker (Larimichthys crocea) using ddRAD sequencing[J]. Marine Biotechnology, 2019, 21: 655-70.
    [142] Omeka W K, Liyanage D S, Lee S, et al. Genome-wide association study (GWAS) of growth traits in olive flounder (Paralichthys olivaceus)[J]. Aquaculture, 2022, 555: 738257.
    [143] Wu L, Yang Y, Li B, et al. First genome-wide association analysis for growth traits in the largest coral reef-dwelling bony fishes, the Giant grouper (Epinephelus lanceolatus)[J]. Marine Biotechnology, 2019, 21: 707-17.
    [144] Yu E, Fu B, Wang G, et al. Proteomic and metabolomic basis for improved textural quality in crisp grass carp (Ctenopharyngodon idellus C. et V) fed with a natural dietary pro-oxidant[J]. Food Chemistry, 2020, 325: 126906.
    [145] He X, Shu H, Xu T, et al. Effects of broad bean diet on the growth performance, muscle characteristics, antioxidant capacity, and intestinal health of Nile tilapia (Oreochromis niloticus)[J]. Animals, 2023, 13(23): 3705.
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HE Yuhui, LI Xiang, SHI Jun. Advances of fish muscle growth[J]. Journal of Fisheries of China,2024,48(9):099601

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  • Received:January 24,2024
  • Revised:May 17,2024
  • Online: September 05,2024
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