Overexpression of PRKAA1 Inhibits Lipid Deposition in Goat Intramuscular Precursor Adipocytes

doi:10.7668/hbnxb.20195380

Abstract

Abstract:

In order to clarify the role of PRKAA1 gene in lipid deposition in goat intramuscular precursor adipocytes,the complete CDS region of the goat PRKAA1 gene was successfully amplified and cloned using RT-PCR,followed by comprehensive bioinformatics analyses. Subsequently,PRKAA1 gene overexpression vectors were constructed utilizing a double enzyme digestion approach and transfected into intramuscular precursor adipocytes.Real-time Fluorescence Quantitative PCR(RT-qPCR)was used to measure the expression level of PRKAA1 gene in the dorsal longissimus dorsi muscle in juvenile and young adults,and the expression level of PRKAA1 gene and lipid metabolism-related genes in precursor adipocytes was also detected in the process of inducing the differentiation of adipocytes. The role of PRKAA1 gene in the formation of lipid droplets was observed and investigated using oil red O staining. The results showed that the total nucleotide sequence length of goat PRKAA1 gene was 2 520 bp. Among them,the 5' untranslated region(UTR)contained 3 bp,the coding region(CDS)was up to 1 680 bp,while the 3' untranslated region(UTR)was 837 bp,and the protein encoded by this gene consisted of 559 amino acid residues. Phylogenetic analysis of the goat PRKAA1 gene revealed that sheep was the most closely related species,followed by cow,pig,dolphin,human,mouse,and rat,whereas chicken was the most distantly related species. The PRKAA1 gene was expressed at a lower level in 9 month-age than 2 month-age in the longest dorsal muscle,and expression was present throughout the induction of differentiation of precursor adipocytes and was at its highest on day 6. In experiments overexpressing the PRKAA1 gene,the content of lipid droplets in precursor adipocytes in goat muscle was significantly reduced. In addition,the expression of genes related to lipid metabolism,such as SREBP1-c,FASN,ACC,AGPAT6,PLIN1,ATGL,and ACOX1 were significantly down-regulated,and the changes were statistically significant. However,the expression levels of several genes,DGAT1,DGAT2,LPL and HSL,did not show significant changes. These results suggest that overexpression of the PRKAA1 gene might affect lipid deposition through multiple metabolic pathways,specifically,it inhibits the ab initio synthesis of fatty acids,decreases the rate of fat synthesis,and increases the rate of fat degradation. These mechanisms work together to inhibit lipid deposition in goat intramuscular precursor adipocytes.

Key words: Goat, PRKAA1, Overexpression, Cloning, Lipid deposition

CLC Number:

S827.2

LI Haiyang, SHAO Peng, YANG Changheng, LIN Yaqiu, WANG Yong, DU Zhanyu, XIANG Hua, HUANG Lian, ZHU Jiangjiang. Overexpression of PRKAA1 Inhibits Lipid Deposition in Goat Intramuscular Precursor Adipocytes[J]. Acta Agriculturae Boreali-Sinica, 2025, 40(5): 208-215. doi: 10.7668/hbnxb.20195380.

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References 31

[1]	Gawat M, Boland M, Singh J, Kaur L. Goat meat:production and quality attributes[J]. Foods, 2023, 12(16):3130. doi:10.3390/foods12163130.
[2]	Tan Z D, Jiang H L. Molecular and cellular mechanisms of intramuscular fat development and growth in cattle[J]. International Journal of Molecular Sciences, 2024, 25(5):2520. doi:10.3390/ijms25052520.
[3]	李银, 韦洋洋, 蒋钦杨, 黄艳娜. 动物肌内脂肪沉积的影响因素及其分子机制[J]. 动物营养学报, 2024, 36(3):1502-1514. doi:10.12418/CJAN2024.133.
	Li Y, Wei Y Y, Jiang Q Y, Huang Y N, Affecting factors of intramuscular fat deposition in animals and their molecular mechanisms[J]. Chinese Journal of Animal Nutrition, 2024, 36(3):1502-1514.
[4]	Witters L A, Gao G, Kemp B E, Quistorff B. Hepatic 5'-AMP-activated protein kinase:zonal distribution and relationship to acetyl-CoA carboxylase activity in varying nutritional states[J]. Archives of Biochemistry and Biophysics, 1994, 308(2):413-419. doi:10.1006/abbi.1994.1058.
[5]	Winder W W, Hardie D G. Inactivation of acetyl-CoA carboxylase and activation of AMP-activated protein kinase in muscle during exercise[J]. American Journal of Physiology-Endocrinology and Metabolism, 1996, 270(2):E299-E304. doi:10.1152/ajpendo.1996.270.2.e299.
[6]	Reznick R M, Zong H H, Li J, Morino K, Moore I K, Yu H J, Liu Z X, Dong J Y, Mustard K J, Hawley S A, Befroy D, Pypaert M, Hardie D G, Young L H, Shulman G I. Aging-associated reductions in AMP-activated protein kinase activity and mitochondrial biogenesis[J]. Cell Metabolism, 2007, 5(2):151-156. doi:10.1016/j.cmet.2007.01.008.
[7]	Yavari A, Stocker C J, Ghaffari S, Wargent E T, Steeples V, Czibik G, Pinter K, Bellahcene M, Woods A, Martínez de Morentin P B, Cansell C, Lam B Y H, Chuster A, Petkevicius K, Nguyen-Tu M S, Martinez-Sanchez A, Pullen T J, Oliver P L, Stockenhuber A, Nguyen C, Lazdam M, O'Dowd J F, Harikumar P, Tóth M, Beall C, Kyriakou T, Parnis J, Sarma D, Katritsis G, Wortmann D D J, Harper A R, Brown L A, Willows R, Gandra S, Poncio V, de Oliveira Figueiredo M J, Qi N R, Peirson S N, McCrimmon R J, Gereben B, Tretter L, Fekete C, Redwood C, Yeo G S H, Heisler L K, Rutter G A, Smith M A, Withers D J, Carling D, Sternick E B, Arch J R S, Cawthorne M A, Watkins H, Ashrafian H. Chronic activation of γ2 AMPK induces obesity and reduces β cell function[J]. Cell Metabolism, 2016, 23(5):821-836. doi:10.1016/j.cmet.2016.04.003.
[8]	Trefts E, Shaw R J. AMPK:restoring metabolic homeostasis over space and time[J]. Molecular Cell, 2021, 81(18):3677-3690. doi:10.1016/j.molcel.2021.08.015.
[9]	Hsu C C, Peng D N, Cai Z, Lin H K. AMPK signaling and its targeting in cancer progression and treatment[J]. Seminars in Cancer Biology, 2022, 85:52-68. doi:10.1016/j.semcancer.2021.04.006.
[10]	吴巧群. miRNA对从江香猪PRKAA1基因调控的研究[D]. 贵阳: 贵州大学, 2021. doi:10.27047/d.cnki.ggudu.2021.002705.
	Wu Q Q. Regulation of PRKAA1 gene by miRNA in Congjiang xiang pigs[D]. Guizhou: Guizhou University,2021.
[11]	Wang S, Liang X, Yang Q, Fu X, Rogers C J, Zhu M, Rodgers B D, Jiang Q, Dodson M V, Du M. Resveratrol induces brown-like adipocyte formation in white fat through activation of AMP-activated protein kinase(AMPK)α1[J]. International Journal of Obesity, 2015, 39(6):967-976. doi:10.1038/ijo.2015.23.
[12]	Yang Q H, Ma Q, Xu J A, Liu Z P, Zou J Q, Shen J, Zhou Y Q, Da Q G, Mao X X, Lu S, Fulton D J, Weintraub N L, Bagi Z, Hong M, Huo Y Q. Prkaa1 metabolically regulates monocyte/macrophage recruitment and viability in diet-induced murine metabolic disorders[J]. Frontiers in Cell and Developmental Biology, 2021, 8:611354. doi:10.3389/fcell.2020.611354.
[13]	孙成娟. 猪肉质性状相关基因FoxO4、PRKAA1的克隆表达及功能研究[D]. 贵阳: 贵州大学, 2017.
	Sun C J. Cloning expression and function analysis of FoxO4 and PRKAA1 genes related to pork quality traits[D]. Guizhou: Guizhou University, 2017.
[14]	Yang J, Maika S N, Craddock L, King J A, Liu Z M. Chronic activation of AMP-activated protein kinase-alpha1 in liver leads to decreased adiposity in mice[J]. Biochemical and Biophysical Research Communications, 2008, 370(2):248-253. doi:10.1016/j.bbrc.2008.03.094.
[15]	Yang Q H, Ma Q, Xu J A, Liu Z P, Mao X X, Zhou Y Q, Cai Y F, Da Q G, Hong M, Weintraub N L, Fulton D J, Belin de Chantemèle E J, Huo Y Q. Endothelial AMPKα1/PRKAA1 exacerbates inflammation in HFD-fed mice[J]. British Journal of Pharmacology, 2022, 179(8):1661-1678. doi:10.1111/bph.15742.
[16]	许晴, 林森, 朱江江, 王永, 林亚秋. 山羊肌内前体脂肪细胞诱导分化过程中内参基因的表达稳定性分析[J]. 畜牧兽医学报, 2018, 49(5):907-918. doi:10.11843/j.issn.0366-6964.2018.05.005.
	Xu Q, Lin S, Zhu J J, Wang Y, Lin Y Q. The expression stability analysis of reference genes in the process of goat intramuscular preadipocytes differentiation in goat[J]. Chinese Journal of Animal and Veterinary Sciences, 2018, 49(5):907-918.
[17]	张天能, 韩帅斌, 周莉娟, 梅洋, 郭武君. 肉羊肌内脂肪沉积影响因素及研究进展[J]. 当代畜禽养殖业, 2023, 43(6):50-51. doi:10.14070/j.cnki.15-1150.2023.06.002.
	Zhang T N, Han S B, Zhou L J, Mei Y, Guo W J. Factors affecting intramuscular fat deposition in meat goats and research progress[J]. Modern Animal Husbandry, 2023, 43(6):50-51.
[18]	Kruk Z A, Bottema M J, Reyes-Veliz L, Forder R E A, Pitchford W S, Bottema C D K. Vitamin A and marbling attributes:intramuscular fat hyperplasia effects in cattle[J]. Meat Science, 2018, 137:139-146. doi:10.1016/j.meatsci.2017.11.024.
[19]	Zhang M, Li D H, Zhai Y H, Wang Z Z, Ma X F, Zhang D Y, Li G X, Han R L, Jiang R R, Li Z J, Kang X T, Sun G R. The landscape of DNA methylation associated with the transcriptomic network of intramuscular adipocytes generates insight into intramuscular fat deposition in chicken[J]. Frontiers in Cell and Developmental Biology, 2020, 8:206. doi:10.3389/fcell.2020.00206.
[20]	Klement E, Medzihradszky K F. Extracellular protein phosphorylation,the neglected side of the modification[J]. Molecular & Cellular Proteomics, 2017, 16(1):1-7. doi:10.1074/mcp.O116.064188.
[21]	Steinberg G R, Hardie D G. New insights into activation and function of the AMPK[J]. Nature Reviews Molecular Cell Biology, 2023, 24(4):255-272. doi:10.1038/s41580-022-00547-x.
[22]	Mossmann D, Park S, Hall M N. mTOR signalling and cellular metabolism are mutual determinants in cancer[J]. Nature Reviews Cancer, 2018, 18(12):744-757. doi:10.1038/s41568-018-0074-8.
[23]	Lin Y Q, Zhu J J, Wang Y, Li Q, Lin S. Identification of differentially expressed genes through RNA sequencing in goats(Capra hircus)at different postnatal stages[J]. PLoS One, 2017, 12(8):e0182602. doi:10.1371/journal.pone.0182602.
[24]	Ferré P, Phan F, Foufelle F. SREBP-1c and lipogenesis in the liver:an update[J]. Biochemical Journal, 2021, 478(20):3723-3739. doi:10.1042/bcj20210071.
[25]	Zhao Q S, Lin X Y, Wang G. Targeting SREBP-1-mediated lipogenesis as potential strategies for cancer[J]. Frontiers in Oncology, 2022, 12:952371. doi:10.3389/fonc.2022.952371.
[26]	Ma X Y, Duan A Q, Lu X R, Liang S S, Sun P H, Sohel M M H, Abdel-Shafy H, Amin A, Liang A X, Deng T X. Novel insight into the potential role of acylglycerophosphate acyltransferases family members on triacylglycerols synthesis in buffalo[J]. International Journal of Molecular Sciences, 2022, 23(12):6561. doi:10.3390/ijms23126561.
[27]	Olzmann J A, Carvalho P. Dynamics and functions of lipid droplets[J]. Nature Reviews Molecular Cell Biology, 2019, 20(3):137-155. doi:10.1038/s41580-018-0085-z.
[28]	Li S J, Raza S H A, Zhao C P, Cheng G, Zan L S. Overexpression of PLIN1 promotes lipid metabolism in bovine adipocytes[J]. Animals, 2020, 10(11):1944. doi:10.3390/ani10111944.
[29]	李君, 闫志浩, 贾万里, 许蒙蒙, 张景锋, 徐秋良, 韩浩园, 权凯. 奶山羊ATGL基因启动子鉴定与转录活性分析[J]. 华北农学报, 2022, 37(2):223-230. doi:10.7668/hbnxb.20192556.
	Li J, Yan Z H, Jia W L, Xu M M, Zhang J F, Xu Q L, Han H Y, Quan K. Identification and transcriptional activity analysis of ATGL gene promoter in dairy goat[J]. Acta Agriculturae Boreali-Sinica, 2022, 37(2):223-230.
[30]	Shang Z, Gao Y T, Xue Y, Zhang C C, Qiu J H, Qian Y H, Fang M, Zhang X, Sun X H, Kong X N, Gao Y Q. Shenge formula attenuates high-fat diet-induced obesity and fatty liver via inhibiting ACOX1[J]. Phytomedicine, 2024, 123:155183. doi:10.1016/j.phymed.2023.155183.
[31]	唐崟梅, 李琪, 李海洋, 林亚秋, 王永, 向华, 黄炼, 朱江江. 山羊FATP2基因的克隆及对前体脂肪细胞脂质沉积的影响[J]. 畜牧兽医学报, 2023, 54(9):3642-3652. doi:10.11843/j.issn.0366-6964.2023.09.006.
	Tang Y M, Li Q, Li H Y, Lin Y Q, Wang Y, Xiang H, Huang L, Zhu J J. Cloning of the goat FATP2 gene and its regulatory effect on lipid deposition in precursor adipocytes[J]. Acta Veterinaria et Zootechnica Sinica, 2023, 54(9):3642-3652.

基因 Gene	全称 Full name	引物序列(5'—3') Primer sequence(5'—3')	基因ID Gene ID
UXT	泛表达转录子	F:GCAAGTGGATTTGGGCTGTAAC R:ATGGAGTCCTTGGTGAGGTTGT	XM_005700842
PRKAA1	AMP活化蛋白激酶α1	F:AAAGGCAGCTGAGAACCTCC R:AAAGGCAGCTGAGAACCTCC	XM_018065502.1
ACC	乙酰辅酶A羧化酶	F: CTCCAACCTCAACCACTACGG R: GGGGAATCACAGAAGCAGCC	XM_018064174.1
SREBP1-c	甾醇调节元件结合蛋白1-c	F:AAGTGGTGGGCCTCTCTGA R:GCAGGGGTTTCTCGGACT	NM_001285755.1
DGAT1	二酰甘油酰基转移酶1	F: CCACTGGGACCTGAGGTGTC R: GCATCACCACACACCAATTCA	XM_018058728
DGAT2	二酰甘油酰基转移酶2	F:CATGTACACATTCTGCACCGATT R:TGACCTCCTGCCACCTTTCT	XM_018058853.1
AGPAT6	酰基甘油-3-磷酸酯酰基转移酶6	F:AAGCAAGTTGCCCATCCTCA R:AAACTGTGGCTCCAATTTCGA	JI861797.1
FASN	脂肪酸合成酶	F: GGGCTCCACCACCGTGTTCCA R: GCTCTGCTGGGCCTGCAGCTG	NM_001285629.1
PLIN1	围脂素1	F:CCCATTGCCAGCACTTCAGA R:CCCATTGCCAGCACTTCAGA	XM_018066567.1
LPL	脂蛋白脂肪酶	F:TCCTGGAGTGACGGAATCTGT R:GACAGCCAGTCCACCACGAT	NM_001285607.1
ATGL	脂肪甘油三酯水解酶	F:GGAGCTTATCCAGGCCAATG R:TGCGGGCAGATGTCACTCT	NM_001285739
HSL	激素敏感脂肪酶	F: TGCCCAAGACAGAGCCAATG R:GCGGAGGAGCCGAGTATCT	EU273879.1
ACOX1	酰基辅酶A氧化酶1	F:CGAGTTCATTCTCAACAGTCCT R:GCATCTTCAAGTAGCCATTATCC	XM_018063771

基因 Gene	全称 Full name	引物序列(5'—3') Primer sequence(5'—3')	基因ID Gene ID
UXT	泛表达转录子	F:GCAAGTGGATTTGGGCTGTAAC R:ATGGAGTCCTTGGTGAGGTTGT	XM_005700842
PRKAA1	AMP活化蛋白激酶α1	F:AAAGGCAGCTGAGAACCTCC R:AAAGGCAGCTGAGAACCTCC	XM_018065502.1
ACC	乙酰辅酶A羧化酶	F: CTCCAACCTCAACCACTACGG R: GGGGAATCACAGAAGCAGCC	XM_018064174.1
SREBP1-c	甾醇调节元件结合蛋白1-c	F:AAGTGGTGGGCCTCTCTGA R:GCAGGGGTTTCTCGGACT	NM_001285755.1
DGAT1	二酰甘油酰基转移酶1	F: CCACTGGGACCTGAGGTGTC R: GCATCACCACACACCAATTCA	XM_018058728
DGAT2	二酰甘油酰基转移酶2	F:CATGTACACATTCTGCACCGATT R:TGACCTCCTGCCACCTTTCT	XM_018058853.1
AGPAT6	酰基甘油-3-磷酸酯酰基转移酶6	F:AAGCAAGTTGCCCATCCTCA R:AAACTGTGGCTCCAATTTCGA	JI861797.1
FASN	脂肪酸合成酶	F: GGGCTCCACCACCGTGTTCCA R: GCTCTGCTGGGCCTGCAGCTG	NM_001285629.1
PLIN1	围脂素1	F:CCCATTGCCAGCACTTCAGA R:CCCATTGCCAGCACTTCAGA	XM_018066567.1
LPL	脂蛋白脂肪酶	F:TCCTGGAGTGACGGAATCTGT R:GACAGCCAGTCCACCACGAT	NM_001285607.1
ATGL	脂肪甘油三酯水解酶	F:GGAGCTTATCCAGGCCAATG R:TGCGGGCAGATGTCACTCT	NM_001285739
HSL	激素敏感脂肪酶	F: TGCCCAAGACAGAGCCAATG R:GCGGAGGAGCCGAGTATCT	EU273879.1
ACOX1	酰基辅酶A氧化酶1	F:CGAGTTCATTCTCAACAGTCCT R:GCATCTTCAAGTAGCCATTATCC	XM_018063771

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