猪骨骼肌卫星细胞分离培养、鉴定及其生物学特性

doi:10.3864/j.issn.0578-1752.2020.08.015

摘要/Abstract

摘要：

【目的】建立猪骨骼肌卫星细胞体外分离、纯化及鉴定的方法,并对其生物学特性进行探讨,为进一步研究猪肌肉生长发育提供良好的细胞模型。【方法】选取1日龄仔猪背最长肌为材料,无菌状态下将背最长肌剪碎为肉糜状。此后采用浓度为0.2%的Ⅰ型胶原酶消化90 min,再加入浓度为0.25%的胰蛋白酶37 ℃联合消化30 min。经终止消化、过滤、重悬后将分离得到的细胞置于37 ℃、5% CO₂细胞培养箱中培养。选用反复差速贴壁法对骨骼肌卫星细胞进行纯化,第一次纯化选择在细胞接种2 h后,将未贴壁细胞转移至新培养皿。上清液继续培养18 h后,对卫星细胞进行第二次差速贴壁纯化。当细胞密度达70%—80%时可对细胞进行传代或冻存处理。利用细胞免疫荧光技术检测P2代卫星细胞标志基因Pax7、MyoD的蛋白表达情况,并绘制卫星细胞生长曲线。分别添加不同诱导分化液使卫星细胞定向分化为肌细胞、脂肪细胞、成骨细胞,检测成肌分化标志基因MHC的免疫荧光,鉴定卫星细胞肌管形成情况;油红O染色及油红O定量鉴定卫星细胞诱导成脂分化效果;茜素红染色鉴定卫星细胞成骨分化能力,qRT-PCR检测成肌、成脂、成骨进程中关键基因的表达。【结果】通过两步酶消化和反复差速贴壁法分离纯化得到了纯度较高的卫星细胞,刚分离的细胞折光性强,贴壁后呈梭形或纺锤形,此后细胞延展并开始快速增殖。卫星细胞特异标志蛋白Pax7、MyoD细胞免疫荧光鉴定结果呈阳性,表明分离细胞为骨骼肌卫星细胞。骨骼肌卫星细胞增殖过程经潜伏期、生长期最终达到平台期,细胞生长曲线呈“S”型。当细胞生长至90%密度时,卫星细胞会出现自融合现象。对分离的骨骼肌卫星细胞成肌诱导分化后,可见邻近卫星细胞融合形成大量粗长肌管,多核肌管呈方向性排列,成肌标志蛋白MHC染色呈阳性。qRT-PCR结果显示标志基因MyoD、MyoG在成肌诱导分化过程中二者均呈先上升后下降趋势。经成脂诱导后细胞形态变为三角形,连续诱导发现脂滴出现并聚集成大脂滴,油红O染色可见大量红色葡萄样脂滴。油红O定量检测结果表明,成脂诱导过程中甘油三酯含量呈稳步上升趋势,各时间点均存在极显著差异（P<0.01）。qRT-PCR结果显示,PPARγ基因表达量在诱导中后期高表达;FABP4在诱导分化第6天达到最高,极显著高于其余时间点（P<0.01）;CEBP/β和HSL表达趋势一致,均呈先升高后降低趋势。诱导成骨分化后,发现细胞形态变为不规则状,诱导后期细胞复层生长形成骨钙结节,茜素红染色可见圆形不透明钙化结节,数量和密度较未诱导时期都明显增加,结果表明细胞出现成骨向分化。成骨标志基因BGLAP、RUNX2的表达量也随诱导进程呈稳步上升趋势,相比未诱导细胞差异极显著（P<0.01）。【结论】建立了基于联合酶消化和反复差速贴壁实现猪骨骼肌卫星细胞分离和纯化的方法,所得细胞增殖能力强且具有多向分化潜能,为猪骨骼肌卫星细胞作为种子细胞用于未来组织工程研究提供了技术平台。

关键词: 猪, 卫星细胞, 分离培养, 鉴定, 分化

Abstract:

【Objective】 The aim of this study was to establish a method for isolation, purification and identification of porcine skeletal muscle satellite cells in vitro, and to explore its biological characteristics, in order to provide a reliable cell model for further research of muscle growth and development in pigs. 【Method】 In this study, the longissimus dorsi muscle of 1 day old pig was selected and cut into meat emulsion in aseptic state. After that, it was digested with 0.2% type I collagenase for 90 min, and then digested with 0.25% trypsin for 30 min at 37 ℃. After termination of digestion, filtration and resuspension, the isolated cells were cultured in a 37 ℃ and 5% CO₂ cell incubator. The skeletal muscle satellite cells were purified by repeated differential adherence technique. The first purification selection was performed after cell culturing for 2 h, and non-adherent cells were transferred to a new culture dish. After the supernatant was further cultured for 18 h, the satellite cells were purified again. The cells were subcultured or frozen when the cell density reached 70% - 80%. Cell immunofluorescence technique was used to detect the protein expression of marker genes of Pax7 and MyoD of P2 satellite cell, and the growth curve was determined. The satellite cells were differentiated into myocytes, adipocytes and osteoblasts by adding different inducing differentiation fluids. The protein expression of myoblast differentiation marker gene MHC was detected by using cell immunofluorescence to identify myotube formation in satellite cells. Oil red O staining and triglyceride content were quantified to identify the adipogenic differentiation effect in satellite cells. Alizarin red staining was used to identify the osteogenic differentiation ability in satellite cells, which were detected the expression of key genes during myogenesis, adipogenesis and osteogenesis by qRT-PCR. 【Result】 The results showed that the satellite cells with higher purity were isolated and purified by two-step enzymatic digestion and repeated differential adherence technique. The cells that were originally isolated with highly refractive, and were fusiform or spindle-shaped after adherence, after which the cells extended and began to proliferate. The results of cell immunofluorescence identification of satellite cells specific marker proteins Pax7 and MyoD were positive, indicating that the isolated cells were skeletal muscle satellite cells. Skeletal muscle satellite cell proliferation underwent the incubation period, and the growth period and finally reached the plateau phase. The satellite cells were self-fusion when the cells grew to 90% density. After myogenic induction and differentiation of the satellite cells, a large number of myotubes were formed by the adjacent satellite cells. Multinucleated myotubes were regularly arranged and the myoblast marker protein MHC staining was positive. The qRT-PCR results showed that the marker genes of MyoD and MyoG both increased first and then decreased during the process of myoblast differentiation. After adipogenic induction, the cell morphology changed into triangle, and lipid droplets appeared and aggregated into large lipid droplets with continuous induction. Oil red O staining observed a large number of red grape-like lipid droplets. Oil red O staining quantitative results showed that the triglyceride content steadily increasing during the adipogensis. There were extremely significant differences among each time point (P<0.01). The qRT-PCR results showed that the expression level of PPARγ gene was high in the middle and the late stage of induction. The FABP4 gene reached the highest at the 6th day of induction and was significantly higher than that at other time points (P<0.01). A similar dynamic was observed with the relative expression level of CEBP/β and HSL in the differentiating cells. Their expression tended to increase first and then decrease. After inducing osteogenic differentiation, it was found that the cell morphology became irregular. Cells formed bone nodules after inducing, compared with the period without induction, the alizarin red staining showed that the number and density of round opaque calcified nodules were significantly increased. The results showed that the cells appeared osteogenic differentiation. The expression levels of osteogenic marker genes BGLAP and RUNX2 also showed a steady upward trend during the inducing procession, which was significantly different from that without inducing cells (P<0.01). 【Conclusion】 This study established a method for isolation and purification of pig skeletal muscle satellite cells based on combined enzyme digestion and differential adherent technique. The obtained cells had strong proliferation ability and multi-directional differentiation potential. The results provided a technical platform for pig skeletal muscle satellite cells as seed cells for future tissue engineering research.

Key words: pig, satellite cell, isolation culture, identification, differentiation

秦本源,杨阳,张燕伟,刘敏,张万锋,王海珍,吴怡琦,张雪莲,蔡春波,高鹏飞,郭晓红,李步高,曹果清. 猪骨骼肌卫星细胞分离培养、鉴定及其生物学特性[J]. 中国农业科学, 2020, 53(8): 1664-1676.

QIN BenYuan,YANG Yang,ZHANG YanWei,LIU Min,ZHANG WanFeng,WANG HaiZhen,WU YiQi,ZHANG XueLian,CAI ChunBo,GAO PengFei,GUO XiaoHong,LI BuGao,CAO GuoQing. Isolation, Culture, Identification and Biological Characteristics of Pig Skeletal Muscle Satellite Cells[J]. Scientia Agricultura Sinica, 2020, 53(8): 1664-1676.

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参考文献 48

[1]	SHAHINI A, VYDIAM K, CHOUDHURY D, RAJABIAN N, NGUYEN T, LEI P, ANDREADIS S T . Efficient and high yield isolation of myoblasts from skeletal muscle. Stem Cell Research, 2018,30:122-129.
[2]	CRAMERI R M, HENNING L, PETER M, JENSEN C H, HENRIK DAA S D, OLESEN J L, CHARLOTTE S, BøRGE T, MICHAEL K . Changes in satellite cells in human skeletal muscle after a single bout of high intensity exercise. Journal of Physiology, 2004,558(1):333-340.
[3]	GRIFFIN C A, APPONI L H, LONG K K, PAVLATH G K . Chemokine expression and control of muscle cell migration during myogenesis. Journal of Cell Science, 2010,123(18):3052-3060.
[4]	PERRUCHOT M H, ECOLAN P, SORENSEN I L, OKSBJERG N, LEFAUCHEUR L . In vitro characterization of proliferation and differentiation of pig satellite cells. Differentiation, 2012,84(4):322-329.
[5]	YIN H, PRICE F, RUDNICKI M A . Satellite cells and the muscle stem cell niche. Physiological Reviews, 2013,93(1):23-67.
[6]	MAURO A . Satellite cell of skeletal muscle fibers. Journal of Biophysical Biochemical Cytology, 1961,9(2):493-495.
[7]	ROBERT W, ANNESOPHIE B, VIOLA G, PETER Z . Dynamics of muscle fibre growth during postnatal mouse development. Bmc Developmental Biology, 2010,10:21.
[8]	FRY C S, LEE J D, MULA J, KIRBY T J, JACKSON J R, LIU F, YANG L, MENDIAS C L, DUPONTVERSTEEGDEN E E, MCCARTHY J J . Inducible depletion of satellite cells in adult, sedentary mice impairs muscle regenerative capacity without affecting sarcopenia. Nature Medicine, 2015,21(1):76-80.
[9]	RENAULT V, ROLLAND E, THORNELL L E, MOULY V, BUTLER-BROWNE G . Distribution of satellite cells in the human vastus lateralis muscle during aging. Experimental Gerontology, 2002,37(12):1513-1514.
[10]	DAY K, PATERSON B, YABLONKA-REUVENI Z . A distinct profile of myogenic regulatory factor detection within Pax7+ cells at S phase supports a unique role of Myf5 during posthatch chicken myogenesis. Developmental Dynamics An Official Publication of the American Association of Anatomists, 2009,238(4):1001-1009.
[11]	JULIA V M, JONES A E, PARKS R J, RUDNICKI M A . Pax7 is critical for the normal function of satellite cells in adult skeletal muscle. Proceedings of the National Academy of Sciences of the United States of America, 2013,110(41):16474-16479.
[12]	MORESI V, MARRONCELLI N, ADAMO S . New insights into the epigenetic control of satellite cells. World Journal of Stem Cells, 2015,7(6):945-955.
[13]	CORNELISON D D W, OLWIN B B, RUDNICKI M A, WOLD B J . MyoD-/-Satellite cells in single-fiber culture are differentiation defective and MRF4 deficient. Developmental Biology, 2000,224(2):122-137.
[14]	TAKEGAHARA Y, YAMANOUCHI K, NAKAMURA K, NAKANO S-i, NISHIHARA M . Myotube formation is affected by adipogenic lineage cells in a cell-to-cell contact-independent manner. Experimental Cell Research, 324(1):105-114.
[15]	YAMANOUCHI K, HOSOYAMA T, MURAKAMI Y, NAKANO S, NISHIHARA M . Satellite cell differentiation in goat skeletal muscle single fiber culture. Journal of Reproduction and Development, 2009,55(3):252-255.
[16]	MONTOYA-FLORES D, MORA O, TAMARIZ E, GONZ LEZ-D VALOS L, GONZ LEZ-GALLARDO A, ANTARAMIAN A, SHIMADA A, VARELA-ECHAVARR A A, ROMANO-MUNOZ J L . Ghrelin stimulates myogenic differentiation in a mouse muscle satellite cell line and in primary cultures of bovine myoblasts. Journal of Animal Physiology & Animal Nutrition, 2012,96(4):725-738.
[17]	DOUMIT M E, MERKEL R A . Conditions for isolation and culture of porcine myogenic satellite cells. Tissue & Cell, 1992,24(2):253-262.
[18]	JIE-MIN D, MU-XUE Y, ZHEN-YU S, CHU-YI G, SI-QI Z, XIAO-SHAN Q . Leucine promotes proliferation and differentiation of primary preterm rat satellite cells in part through mTORC1 signaling pathway. Nutrients, 2015,7(5):3387-3400.
[19]	MUSAR A . Isolation and culture of mouse satellite cells. Methods Molecular Biology, 2010,633(633):101-111.
[20]	JEEVA S, SIRISHA C, JYOTSNA D, DAA S d H, MAURILIO S . A Novel in vitro model for studying quiescence and activation of primary isolated human myoblasts. PLoS One, 2013,8(5):e64067.
[21]	MIERSCH C, STANGE K, R NTGEN M . Separation of functionally divergent muscle precursor cell populations from porcine juvenile muscles by discontinuous Percoll density gradient centrifugation. Bmc Cell Biology, 2018,19(1):2.
[22]	PALLAFACCHINA G, FRAN OIS S, REGNAULT B, CZARNY B, DIVE V, CUMANO A, MONTARRAS D, BUCKINGHAM M . An adult tissue-specific stem cell in its niche: A gene profiling analysis of in vivo quiescent and activated muscle satellite cells. Stem Cell Research, 2010,4(2):77-91.
[23]	MOTOHASHI N, ASAKURA Y, ASAKURA A . Isolation, culture, and transplantation of muscle satellite cells. Journal of Visualized Experiments Jove, 2014,86(86):e50846-e50846.
[24]	CASTIGLIONI A, HETTMER S, LYNES M, RAO T N, TCHESSALOVA D, SINHA I, LEE B, TSENG Y H, WAGERS A . Isolation of progenitors that exhibit myogenic/osteogenic bipotency in vitro by fluorescence-activated cell sorting from human fetal muscle. Stem Cell Reports, 2014,2(1):92-106.
[25]	薛科, 王林杰, 陈利, 王薏琳, 仲涛, 李利, 张红平 . 高糖诱导山羊骨骼肌卫星细胞成脂分化过程中相关基因表达的变化. 畜牧兽医学报, 2014,45(5):706-713.
	XUE K, WANG L J, CHEN L, WANG Y L, ZHONG T, LI L, ZHANG H P . Adipogenic-related gene expressions in goat skeletal muscle satellite cells treated with high concentration glucose. Acta Veterinaria et Zootechnica Sinica, 2014,45(5):706-713. (in Chinese)
[26]	DIDIER M, JENNIFER M, CHARLOTTE C, FR D RIC R, ST PHANE Z, ANA C, TERENCE P, MARGARET B . Direct isolation of satellite cells for skeletal muscle regeneration. Science, 2005,309(5743):2064-2067.
[27]	LI Y, YANG X, NI Y, DECUYPERE E, BUYSE J, EVERAERT N, GROSSMANN R, ZHAO R . Early-age feed restriction affects viability and gene expression of satellite cells isolated from the gastrocnemius muscle of broiler chicks. Journal of Animal Science and Biotechnology, 2012,3(1):33.
[28]	CHOI S H, CHUNG K Y, JOHNSON B J, GO G W, KIM K H, CHANG W, CHOI , SMITH S B . Co-culture of bovine muscle satellite cells with preadipocytes increases PPARγ and C/EBPβ gene expression in differentiated myoblasts and increases GPR43 gene expression in adipocytes. Journal of Nutritional Biochemistry, 2013,24(3):539-543.
[29]	WU H, REN Y, LI S, WANG W, YUAN J, GUO X, LIU D, CANG M . In vitro culture and induced differentiation of sheep skeletal muscle satellite cells. Cell Biology International, 2013,36(6):579-587.
[30]	RELAIX F, ZAMMIT P S . Satellite cells are essential for skeletal muscle regeneration: the cell on the edge returns centre stage. Development, 2012,139(16):2845-2856.
[31]	BRUN C E, YU X W, RUDNICKI M A . Single EDL myofiber isolation for analyses of quiescent and activated muscle stem cells. Cellular Quiescence, 2018,1686:149-159.
[32]	SEALE P, RUDNICKI M A . A new look at the origin, function, and “stem-cell” status of muscle satellite cells. Developmental Biology, 2000,218(2):115-124.
[33]	YANG J, LIU H, WANG K, LI L, YUAN H, LIU X, LIU Y, GUAN W . Isolation, culture and biological characteristics of multipotent porcine skeletal muscle satellite cells. Cell & Tissue Banking, 2017,18(4):1-13.
[34]	睢梦华, 郑琪, 吴昊, 丁建平, 刘勇, 李文雍, 储明星, 张子军, 凌英会 . 山羊胎儿肌肉干细胞的分离培养与成肌诱导分化. 中国农业科学, 2018,51(8):1590-1597.
	SUI M H, ZHENG Q, WU H, DING J P, LIU Y, LI W Y, CHU M X, ZHANG Z J, LING Y H . Isolation, Culture and Myogenic Differentiation of Muscle Stem Cells in Goat Fetal. Scientia Agricultura Sinica, 2018,51(8):1590-1597. (in Chinese)
[35]	BAQUERO-PEREZ B . A simplified but robust method for the isolation of avian and mammalian muscle satellite cells. Bmc Cell Biology, 2012,13(1):16.
[36]	MIERSCH C, STANGE K, R NTGEN M . Effects of trypsinization and of a combined trypsin, collagenase, and DNase digestion on liberation and in vitro function of satellite cells isolated from juvenile porcine muscles. In Vitro Cellular & Developmental Biology - Animal, 2018,54(6):406-412.
[37]	AGLEY C C, ROWLERSON A M, VELLOSO C P, LAZARUS N L, HARRIDGE S D . Isolation and quantitative immunocytochemical characterization of primary myogenic cells and fibroblasts from human skeletal muscle. Journal of Visualized Experiments, 2015,95:52049.
[38]	DICK S A, CHANG N C, DUMONT N A, BELL R A V, CHARIS P, YOICHI K, LITCHFIELD D W, RUDNICKI M A, MEGENEY L A . Caspase 3 cleavage of Pax7 inhibits self-renewal of satellite cells. Proceedings of the National Academy of Sciences of the United States of America, 2015,112(38):5246-5252.
[39]	FENG X, NAZ F, JUAN A H DELL'ORSO S SARTORELLI V . Identification of skeletal muscle satellite cells by immunofluorescence with Pax7 and laminin antibodies. Journal of Visualized Experiments, 2018,134:57212.
[40]	STARKEY J D, MASAKAZU Y, SHOKO Y, GOLDHAMER D J . Skeletal muscle satellite cells are committed to myogenesis and do not spontaneously adopt nonmyogenic fates. Journal of Histochemistry & Cytochemistry Official Journal of the Histochemistry Society, 2011,59(1):33-46.
[41]	李方华, 侯玲玲, 马月辉, 庞全海, 关伟军 . 北京油鸡骨骼肌卫星细胞的分离、培养、鉴定及成肌诱导分化的研究. 中国农业科学, 2010,43(22):4725-4731 .
	LI F H, HOU L L, MA Y H, PANG Q H, GUAN W J . Isolation, culture, identification and muscle differentiation of skeletal muscle satellite cells in Beijing Fatty Chicken. Scientia Agricultura Sinica, 2010,43(22):4725-4731 . (in Chinese)
[42]	ASAKURA A, RUDNICKI M A, KOMAKI M . Muscle satellite cells are multipotential stem cells that exhibit myogenic, osteogenic, and adipogenic differentiation. Differentiation , 68(4-5):245-253.
[43]	RUIZ-OJEDA F J, RUP REZ A I, GOMEZ-LLORENTE C, GIL A, AGUILERA C M . Cell models and their application for studying adipogenic differentiation in relation to obesity: a review. International Journal of Molecular Sciences, 2016,17(7):1040.
[44]	FISCHER C, SEKI T, LIM S, NAKAMURA M, ANDERSSON P, YANG Y, HONEK J, WANG Y, GAO Y, CHEN F, SAMANI N J, ZHANG J, MIYAKE M, OYADOMARI S, YASUE A, LI X, ZHANG Y, LIU Y, CAO Y . A miR-327-FGF10-FGFR2-mediated autocrine signaling mechanism controls white fat browning. Nature Communications, 2017,8(1):2079.
[45]	MANIATOPOULOS C, SODEK J, MELCHER A H . Bone formation in vitro by stromal cells obtained from bone marrow of young adult rats. Cell & Tissue Research, 1988,254(2):317-330.
[46]	LEE K-M, PARK K H, HWANG J S, LEE M, YOON D S, RYU H A, JUNG H S, PARK K W, KIM J, PARK S W, KIM S-H, CHUN Y-M, CHOI W J, LEE J W . Inhibition of STAT5A promotes osteogenesis by DLX5 regulation. Cell Death & Disease, 2018,9(11):1136.
[47]	YU R, WU H, ZHOU X, WEN J, JIN M, MING C, GUO X, WANG Q, LIU D, MA Y . Isolation, expansion, and differentiation of goat adipose-derived stem cells. Research in Veterinary Science, 2012,93(1):404-411.
[48]	REZA R, SEYED MAHDI N, PARVANEH K, ABDOL-MOHAMMAD K, SEYED HOSSEIN A, ELHAM M, MOHAMMAD M, MOHAMAD Z A . Juxtacrine and paracrine interactions of rat marrow-derived mesenchymal stem cells, muscle-derived satellite cells, and neonatal cardiomyocytes with endothelial cells in angiogenesis dynamics. Stem Cells & Development, 2012,22(6):855-865.

基因名称Gene name	引物序列（5′→3′）Primer sequence	产物长度Product length (bp)	序列号Accession No.
MyoD	F: GAGAGCACTACAGCGGTGAC R: CCTCGCTGTAATAGGTGCCG	132	NM_001002824.1
MyoG	F: CTCAGCTCCCTCAACCAGGA R: GGAGTGCAGATTGTGGGCAT	195	NM_001012406.1
FABP4	F:TGGTACAGGTGCAGAAGTGG R: TTCTGGTAGCCGTGACACCT	108	NM_001002817.1
CEBP/β	F:CTGGAGACGCAGCATAAGGT R:TGCTTGAACAAGTTCCGCAG	110	NM_001199889.1
PPARγ	F:CTATTCCATGCTGTCATGGGTG R: ACCATGGTCACCTCTTGTGA	107	NM_214379.1
HSL	F:CACTGACTGCTGACCCCAAG R:TCCTCACTGTCCTGTCCTTCAC	121	NM_214315.3
BGLAP	F: GCCACACTCTGCCTTGCTG R: CTCCTGGAAGCCGATGTGA	237	NM_001164004.1
RUNX2	F: GAGTGGACGAGGCAAGAGTT R:ACTTGGTGCAGAGTTCAGGG	256	XM_003482203.4
18S	F:CCCACGGAATCGAGAAAGAG R: TTGACGGAAGGGCACCA	122	NW_018085108.1