Your search keyword '"skeletal muscle development"' showing total 257 results

1. Supplemental Clostridium butyricum modulates skeletal muscle development and meat quality by shaping the gut microbiota of lambs

Author

Dou, Lu, Liu, Chang, Chen, Xiaoyu, Yang, Zhihao, Hu, Guanhua, Zhang, Min, Sun, Lina, Su, Lin, Zhao, Lihua, and Jin, Ye

Published

2023

2. Differential gene expression in neonatal calf muscle tissues from Hanwoo cows overfed during mid to late pregnancy period

Author

Borhan Shokrollahi, Myungsun Park, Youl-Chang Baek, Shil Jin, Gi-Suk Jang, Sung-Jin Moon, Kyung-Hwan Um, Sun-Sik Jang, and Hyun-Jeong Lee

Subjects

Maternal nutrition, Skeletal muscle development, Metabolic programming, Transcriptomic analysis, Beef cattle metabolism, Medicine, Science

Abstract

Abstract Maternal nutrition significantly influences fetal development and postnatal outcomes. This study investigates the impact of maternal overfeeding during mid to late pregnancy on gene expression in the round and sirloin muscles of Hanwoo neonatal calves. Eight cows were assigned to either a control group receiving standard nutrition (100%) or a treated group receiving overnutrition (150%). After birth, tissue samples from the round and sirloin muscles of neonatal calves were collected and subjected to RNA sequencing to assess differentially expressed genes (DEGs). RNA sequencing identified 43 DEGs in round muscle and 15 in sirloin muscle, involving genes related to myogenesis, adipogenesis, and energy regulation. Key genes, including PPARGC1A, THBS1, CD44, JUND, CNN1, ENAH, and RUNX1, were predominantly downregulated. Gene ontology (GO) enrichment analyses revealed terms associated with muscle development, such as “biological regulation,” “cellular process,” and “response to stimulus.” Protein-protein interaction networks highlighted complex interactions among DEGs. Random Forest analysis identified ARC, SLC1A5, and GNPTAB as influential genes for distinguishing between control and treated groups. Overall, maternal overnutrition during mid-to-late pregnancy results in the downregulation of genes involved in muscle development and energy metabolism in neonatal Hanwoo calves. These findings provide insights into the molecular effects of maternal nutrition on muscle development.

Published

2024

3. Multiomics analysis reveals signatures of selection and loci associated with complex traits in pigs.

Author

Liu, Lei, Yi, Guoqiang, Yao, Yilong, Liu, Yuwen, Li, Jiang, Yang, Yalan, Liu, Mei, Fang, Lingzhao, Mo, Delin, Zhang, Longchao, Liu, Yonggang, Niu, Yongchao, Wang, Liyuan, Qu, Xiaolu, Pan, Zhangyuan, Wang, Lei, Chen, Muya, Fan, Xinhao, Chen, Yun, and Zhang, Yongsheng

Subjects

*GENETIC variation, *REGULATOR genes, *MUSCLE growth, *SKELETAL muscle, *GENETIC regulation

Abstract

The genetic basis of complex traits and phenotypic differentiation remains unclear in pigs. Using nine genomes—seven of which were newly generated, high‐quality de novo assembled genomes—and 1081 resequencing genomes, we built a pan‐genome and identified 134.24 Mb nonredundant nonreference sequences, 1099 novel protein‐coding genes, 187,927 structural variations (SVs) and 30,143,962 single‐nucleotide polymorphisms (SNPs). Analysis of selective domestication revealed BRCA1 associated with enhanced adipocyte growth and fat deposition, and ABCA3 linked to an alleviated immune response and reduced lung injury. Integrating 162 transcriptomes and 162 methylomes of skeletal muscle across 27 developmental stages revealed the regulatory mechanism of phenotypic differentiation between Eastern and Western breeds. Artificial selection reshaped local DNA methylation status and imparted regulatory effects on the progression patterns of heterochronic genes such as GHSR and BDH1, particularly during embryonic development. Altogether, our work provides valuable resources for understanding molecular mechanisms behind phenotypic variations and enhancing the genetic improvement programs in pigs. Highlights: Combining nine high‐quality genomes and 1081 whole‐genome resequencing data, a relatively complete pan‐genome and genetic variation data set of pigs was constructed, laying the foundation for analyzing the complex traits of pigs.Abundant signals and genes of selective sweeps related to pig fat deposition, muscle growth, and immune traits were discovered, providing key genetic markers for future breeding programs.Integration of transcriptome and methylome data across 27 skeletal muscle development stages revealed the epigenetic and heterochronic gene regulatory mechanisms of skeletal muscle growth differences between Eastern and Western pig breeds.Artificial selection has a significant impact on DNA methylation and heterochronic gene regulation, which is closely related to the differences in skeletal muscle growth and meat quality between Eastern and Western pig breeds. [ABSTRACT FROM AUTHOR]

Published

2024

4. Establishment of CSE1L Knockout C2C12 Cells by CRISPR-Cas9 System.

Author

LI Zixin, BAI Hongfei, XIE Yong, LI Xun, and BAI Lijing

Subjects

GREEN fluorescent protein, GENE knockout, GENE expression, CELL cycle, KNOCKOUT mice

Abstract

To study the role of chromosomeseegregation 1-like (CSE1L) protein in skeletal muscle development in mice, CSE1L gene knockout C2C12 cell line was constructed by CRISPR-Cas9 gene editing technology. 3 pairs of single RNAs (sgRNAs) targeting the third exon of mouse CSE1L CDS sequence were designed, then sgRNA plasmid (linked to green fluorescent protein, GFP) and Cas9 plasmid (linked to red fluorescent protein, RFP) were constructed. The sgRNA and Cas9 were co-transfected into C2C12 cell line, then the cleavage efficiency of different sgRNA was screened. After co-transfection, the C2C12 cell lines were sorted by flow cytometry to obtain the cells coexpressing GFP and RFP, and then identified by DNA sequencing. The molecular characteristics of CSE1L were identified by real-time quantitative PCR (RT-qPCR) and Western blot. Finally, CCK-8, cell cycle and apoptosis test were used to examine the activity and apoptosis of CSE1L knock out cell line. The results showed that CSE1L gene mRNA and protein expression level were significantly decreased (P<0.01), which indicated that CSE1L gene was successfully knocked out. CSE1L gene deletion resulted in C2C12 cell line elongated, cell viability was significantly down-regulated at 72 h, cell cycle arrest and apoptosis increased. This study demonstrated the CSE1L gene knockout cell line was successfully constructed, and the function related to growth and development of mouse skeletal muscle cells was studied, which provided a cell line model for exploring the function of CSE1L gene study and laid a foundation for generating subsequent gene editing knockout mice. [ABSTRACT FROM AUTHOR]

Published

2024

5. Ythdf2 facilitates precursor miR-378/miR-378-5p maturation to support myogenic differentiation.

Author

Deng, Kaiping, Su, Yalong, Liu, Zhipeng, Hu, Silu, Ren, Caifang, Wei, Wurilege, Fan, Yixuan, Zhang, Yanli, and Wang, Feng

Subjects

*GENE expression, *MUSCLE growth, *SKELETAL muscle, *MYOGENESIS, *MESSENGER RNA

Abstract

Ythdf2 is known to mediate mRNA degradation in an m6A-dependent manner, and it has been shown to play a role in skeletal muscle differentiation. Recently, Ythdf2 was also found to bind to m6A-modified precursor miRNAs and regulate their maturation. However, it remains unknown whether this mechanism is related to the regulation of myogenesis by Ythdf2. Here, we observed that Ythdf2 knockdown significantly suppressed myotube formation and impacted miRNAs expression during myogenic differentiation. Through integrated analysis of miRNA and mRNA sequencing data, miR-378 and miR-378-5p were identified as important targets of Ythdf2 in myogenesis. Mechanically, Ythdf2 was found to interact with core components of the pre-miRNA processor complex, namely DICER1 and TARBP2, thereby facilitating the maturation of pre-miR-378/miR-378-5p in an m6A-dependent manner and resulting in an increase in the expression levels of mature miR-378 and miR-378-5p. Moreover, the downregulation of either miR-378 or miR-378-5p significantly inhibited myotube formation, while the forced expression of miR-378 or miR-378-5p could partially rescued Ythdf2 knockdown-induced suppression of myogenic differentiation by activating the mTOR pathway. Collectively, our results for the first time suggest that Ythdf2 regulates myogenic differentiation via mediating pre-miR-378/miR-378-5p maturation, which might provide new insights into the molecular mechanisms underlying m6A modification in the regulation of myogenesis. [ABSTRACT FROM AUTHOR]

Published

2024

6. Differential gene expression in neonatal calf muscle tissues from Hanwoo cows overfed during mid to late pregnancy period.

Author

Shokrollahi, Borhan, Park, Myungsun, Baek, Youl-Chang, Jin, Shil, Jang, Gi-Suk, Moon, Sung-Jin, Um, Kyung-Hwan, Jang, Sun-Sik, and Lee, Hyun-Jeong

Subjects

METABOLIC reprogramming, GENE expression, MUSCLE growth, MATERNAL nutrition, CALF muscles

Abstract

Maternal nutrition significantly influences fetal development and postnatal outcomes. This study investigates the impact of maternal overfeeding during mid to late pregnancy on gene expression in the round and sirloin muscles of Hanwoo neonatal calves. Eight cows were assigned to either a control group receiving standard nutrition (100%) or a treated group receiving overnutrition (150%). After birth, tissue samples from the round and sirloin muscles of neonatal calves were collected and subjected to RNA sequencing to assess differentially expressed genes (DEGs). RNA sequencing identified 43 DEGs in round muscle and 15 in sirloin muscle, involving genes related to myogenesis, adipogenesis, and energy regulation. Key genes, including PPARGC1A, THBS1, CD44, JUND, CNN1, ENAH, and RUNX1, were predominantly downregulated. Gene ontology (GO) enrichment analyses revealed terms associated with muscle development, such as "biological regulation," "cellular process," and "response to stimulus." Protein-protein interaction networks highlighted complex interactions among DEGs. Random Forest analysis identified ARC, SLC1A5, and GNPTAB as influential genes for distinguishing between control and treated groups. Overall, maternal overnutrition during mid-to-late pregnancy results in the downregulation of genes involved in muscle development and energy metabolism in neonatal Hanwoo calves. These findings provide insights into the molecular effects of maternal nutrition on muscle development. [ABSTRACT FROM AUTHOR]

Published

2024

7. Regulatory role of N6-Methyladenosine on skeletal muscle development in Hu sheep.

Author

Junfang Jiang, Liangyong Guo, Xin Huang, Kaizhi Zheng, Sangang He, and Huili Shan

Subjects

RNA modification & restriction, MUSCLE growth, BIOLOGICAL transport, SKELETAL muscle, CYTOSKELETON

Abstract

N6-Methyladenosine (m6A) RNA modification plays an essential role in many biological processes. To investigate the regulatory role of m6A on the skeletal muscle development in Hu sheep, this study took newborn Hu sheep (b_B Group) and six-month-old Hu sheep (s_B Group) as the objects. MeRIP-seq and RNA-Seq analysis techniques were used to detect differentially methylated genes (DMGs) and differentially expressed genes (DEGs) in the longissimus dorsi muscle of Hu sheep at different months of age. Then, conjoint analysis was further employed to screen for key genes involved in skeletal muscle development that are modified by m6A and expressed by mRNA. According to the results of the MeRIP-seq analysis, there were 285 m6A differentially methylated peaks (DMPs) in total between b_B Group and s_B Group, with 192 significant upregulated peaks and 93 significant downregulated peaks. GO and KEGG analysis revealed that DMGs are mainly enriched in actin-binding, cellular transport, and metabolic pathways. According to the results of the RNA-seq analysis, there were 4,349 DEGs in total between b_B Group and s_B Group, with 2010 upregulated genes and 2,339 downregulated genes. DEGs are found to be mainly enriched in the regulation of actin cytoskeleton tissue, AMPK and FoxO signaling pathways, etc. The conjoint analysis demonstrated that 283 genes were both modified by m6A and expressed by mRNA. Among them, three genes relevant to muscle growth (RGMB, MAPK8IP3, and RSPO3) were selected as candidates for quantitative validation, and the results were in line with the sequencing results. The results mentioned above all suggest that m6A plays a certain role in the skeletal muscle development in Hu sheep. [ABSTRACT FROM AUTHOR]

Published

2024

8. The emergence of the stem cell niche

Author

Hicks, Michael R and Pyle, April D

Subjects

Biochemistry and Cell Biology, Biological Sciences, Stem Cell Research, Stem Cell Research - Induced Pluripotent Stem Cell - Human, Stem Cell Research - Embryonic - Non-Human, Regenerative Medicine, Stem Cell Research - Nonembryonic - Non-Human, Stem Cell Research - Nonembryonic - Human, Stem Cell Research - Induced Pluripotent Stem Cell, Stem Cell Research - Embryonic - Human, 1.1 Normal biological development and functioning, Underpinning research, Musculoskeletal, Humans, Cell Differentiation, Stem Cell Niche, Muscle, Skeletal, Satellite Cells, Skeletal Muscle, Pluripotent Stem Cells, niche emergence, niche rejuvenation and therapeutics, progenitor to stem cell maturation, skeletal muscle development, Medical and Health Sciences, Developmental Biology, Biochemistry and cell biology

Abstract

Stem cell niches are composed of dynamic microenvironments that support stem cells over a lifetime. The emerging niche is distinct from the adult because its main role is to support the progenitors that build organ systems in development. Emerging niches mature through distinct stages to form the adult niche and enable proper stem cell support. As a model of emerging niches, this review highlights how differences in the skeletal muscle microenvironment influence emerging versus satellite cell (SC) niche formation in skeletal muscle, which is among the most regenerative tissue systems. We contrast how stem cell niches regulate intrinsic properties between progenitor and stem cells throughout development to adulthood. We describe new applications for generating emerging niches from human pluripotent stem cells (hPSCs) using developmental principles and highlight potential applications for regeneration and therapeutics.

Published

2023

9. Building Haplotype‐Resolved 3D Genome Maps of Chicken Skeletal Muscle.

Author

Li, Jing, Lin, Yu, Li, Diyan, He, Mengnan, Kui, Hua, Bai, Jingyi, Chen, Ziyu, Gou, Yuwei, Zhang, Jiaman, Wang, Tao, Tang, Qianzi, Kong, Fanli, Jin, Long, and Li, Mingzhou

Subjects

*SKELETAL muscle, *CHICKENS, *GENE mapping, *GENOMIC imprinting, *MUSCLE growth, *CHICKEN breeds

Abstract

Haplotype‐resolved 3D chromatin architecture related to allelic differences in avian skeletal muscle development has not been addressed so far, although chicken husbandry for meat consumption has been prevalent feature of cultures on every continent for more than thousands of years. Here, high‐resolution Hi‐C diploid maps (1.2‐kb maximum resolution) are generated for skeletal muscle tissues in chicken across three developmental stages (embryonic day 15 to day 30 post‐hatching). The sequence features governing spatial arrangement of chromosomes and characterize homolog pairing in the nucleus, are identified. Multi‐scale characterization of chromatin reorganization between stages from myogenesis in the fetus to myofiber hypertrophy after hatching show concordant changes in transcriptional regulation by relevant signaling pathways. Further interrogation of parent‐of‐origin‐specific chromatin conformation supported that genomic imprinting is absent in birds. This study also reveals promoter‐enhancer interaction (PEI) differences between broiler and layer haplotypes in skeletal muscle development‐related genes are related to genetic variation between breeds, however, only a minority of breed‐specific variations likely contribute to phenotypic divergence in skeletal muscle potentially via allelic PEI rewiring. Beyond defining the haplotype‐specific 3D chromatin architecture in chicken, this study provides a rich resource for investigating allelic regulatory divergence among chicken breeds. [ABSTRACT FROM AUTHOR]

Published

2024

10. Neonatal resveratrol administration promotes skeletal muscle growth and insulin sensitivity in intrauterine growth‐retarded suckling piglets associated with activation of FGF21–AMPKα pathway.

Author

Bai, Guangyi, Chen, Jinyong, Liu, Yue, Chen, Jun, Yan, Honglin, You, Jinming, and Zou, Tiande

Subjects

*INSULIN receptors, *INSULIN sensitivity, *INSULIN, *SKELETAL muscle, *MUSCLE growth, *PIGLETS, *FETAL growth retardation

Abstract

BACKGROUND: Skeletal muscle is a major insulin‐sensitive tissue with a pivotal role in modulating glucose homeostasis. This study aimed to investigate the effect of resveratrol (RES) intervention during the suckling period on skeletal muscle growth and insulin sensitivity of neonates with intrauterine growth retardation (IUGR) in a pig model. RESULTS: Twelve pairs of normal birth weight (NBW) and IUGR neonatal male piglets were selected. The NBW and IUGR piglets were fed basal formula milk diet or identical diet supplemented with 0.1% RES from 7 to 21 days of age. Myofiber growth and differentiation, inflammation and insulin sensitivity in skeletal muscle were assessed. Early RES intervention promoted myofiber growth and maturity in IUGR piglets by ameliorating the myogenesis process and increasing thyroid hormone level. Administering RES also reduced triglyceride concentration in skeletal muscle of IUGR piglets, along with decreased inflammatory response, increased plasma fibroblast growth factor 21 (FGF21) concentration and improved insulin signaling. Meanwhile, the improvement of insulin sensitivity by RES may be partly regulated by activation of the FGF21/AMP‐activated protein kinase α/sirtuin 1/peroxisome proliferator activated receptor‐γ coactivator‐1α pathway. CONCLUSION: Our results suggest that RES has beneficial effects in promoting myofiber growth and maturity and increasing skeletal muscle insulin sensitivity in IUGR piglets, which open a novel field of application of RES in IUGR infants for improving postnatal metabolic adaptation. © 2023 Society of Chemical Industry. [ABSTRACT FROM AUTHOR]

Published

2024

11. Effects of thyroid hormone on monochromatic light combinations mediate skeletal muscle fiber pattern in broilers

Author

Yameng Liu, Zixu Wang, Jing Cao, Yulan Dong, Ting Gao, and Yaoxing Chen

Subjects

thyroid hormone, monochromatic light, muscle fiber type conversion, skeletal muscle development, chicken, Animal culture, SF1-1100

Abstract

ABSTRACT: It has been shown that monochromatic green light and blue light promote skeletal muscle development in early (P0-P26) and later growth stages (P27-P42), respectively. This study further investigated the effects of monochromatic light combinations on myogenesis and myofiber types transformation in broilers. Here, a total of 252 chicks were exposed to monochromatic light [red (R), green (G), blue (B), or white light (W)], and monochromatic light combination [green and blue light combination (GB), blue and green light combination (BG), red and blue combination (RB)] until P42. Compared with other groups, GB significantly increased body weight, and muscle organ index, both proportions of larger-size myofibers and oxidative myofibers in the pectoralis major (PM) and gastrocnemius muscle (GAS). Meanwhile, GB up-regulated the abundance of oxidative genes MYH7B and MYH1B, transcription factors PAX7 and Myf5, antioxidant proteins Nrf2, HO-1, and GPX4, and the activities of antioxidant enzymes CAT, GPx, and T-AOC, but down-regulated the abundance of glycolytic related genes MYH 1A, MyoD, MyoG, Mstn, Keap1, TNFa, and MDA levels. Consistent with the change of myofiber pattern, GB significantly reduced serum thyroid hormone (TH) levels, up-regulated skeletal muscle deiodinase DIO3 expression and down-regulated deiodinase DIO2 expression, which may directly lead to the reduction of intramuscular TH levels to affect myofiber types transformation. In contrast, the proportion of fast glycolytic muscle fibers increased in the RR with increasing TH levels. After thyroidectomy, the above parameters were inversed and resulted in no significant difference of each color light treatment group. These data suggested that GB significantly increased the proportion of oxidative muscle fibers and antioxidant capacity in skeletal muscle of broilers, which was regulated by TH-DIO2/DIO3 signaling pathway.

Published

2024

12. SRSF2 is a key player in orchestrating the directional migration and differentiation of MyoD progenitors during skeletal muscle development

Author

Rula Sha, Ruochen Guo, Huimin Duan, Qian Peng, Ningyang Yuan, Zhenzhen Wang, Zhigang Li, Zhiqin Xie, Xue You, and Ying Feng

Subjects

SRSF2, scRNA-seq, skeletal muscle development, gene regulation, alternative splicing, Medicine, Science, Biology (General), QH301-705.5

Abstract

SRSF2 plays a dual role, functioning both as a transcriptional regulator and a key player in alternative splicing. The absence of Srsf2 in MyoD + progenitors resulted in perinatal mortality in mice, accompanied by severe skeletal muscle defects. SRSF2 deficiency disrupts the directional migration of MyoD progenitors, causing them to disperse into both muscle and non-muscle regions. Single-cell RNA-sequencing analysis revealed significant alterations in Srsf2-deficient myoblasts, including a reduction in extracellular matrix components, diminished expression of genes involved in ameboid-type cell migration and cytoskeleton organization, mitosis irregularities, and premature differentiation. Notably, one of the targets regulated by Srsf2 is the serine/threonine kinase Aurka. Knockdown of Aurka led to reduced cell proliferation, disrupted cytoskeleton, and impaired differentiation, reflecting the effects seen with Srsf2 knockdown. Crucially, the introduction of exogenous Aurka in Srsf2-knockdown cells markedly alleviated the differentiation defects caused by Srsf2 knockdown. Furthermore, our research unveiled the role of Srsf2 in controlling alternative splicing within genes associated with human skeletal muscle diseases, such as BIN1, DMPK, FHL1, and LDB3. Specifically, the precise knockdown of the Bin1 exon17-containing variant, which is excluded following Srsf2 depletion, profoundly disrupted C2C12 cell differentiation. In summary, our study offers valuable insights into the role of SRSF2 in governing MyoD progenitors to specific muscle regions, thereby controlling their differentiation through the regulation of targeted genes and alternative splicing during skeletal muscle development.

Published

2024

13. MYH1G-AS is a chromatin-associated lncRNA that regulates skeletal muscle development in chicken

Author

Bolin Cai, Manting Ma, Rongshuai Yuan, Zhen Zhou, Jing Zhang, Shaofen Kong, Duo Lin, Ling Lian, Juan Li, Xiquan Zhang, and Qinghua Nie

Subjects

Chromatin accessibility, LncRNA MYH1G-AS, m6A methylation, Skeletal muscle development, Cytology, QH573-671

Abstract

Abstract Background Skeletal muscle development is pivotal for animal growth and health. Recently, long noncoding RNAs (lncRNAs) were found to interact with chromatin through diverse roles. However, little is known about how lncRNAs act as chromatin-associated RNAs to regulate skeletal muscle development. Here, we aim to investigate the regulation of chromatin-associated RNA (MYH1G-AS) during skeletal muscle development. Methods We provided comprehensive insight into the RNA profile and chromatin accessibility of different myofibers, combining RNA sequencing (RNA-seq) with an assay for transposase-accessible chromatin with high-throughput sequencing (ATAC-seq). The dual-luciferase reporter assay and chromatin immunoprecipitation (ChIP) assay were used to analyze the transcriptional regulation mechanism of MYH1G-AS. ALKBH5-mediated MYH1G-AS N 6-methyladenosine (m6A) demethylation was assessed by a single-base elongation and ligation-based qPCR amplification method (SELECT) assay. Functions of MYH1G-AS were investigated through a primary myoblast and lentivirus/cholesterol-modified antisense oligonucleotide (ASO)-mediated animal model. To validate the interaction of MYH1G-AS with fibroblast growth factor 18 (FGF18) protein, RNA pull down and an RNA immunoprecipitation (RIP) assay were performed. Specifically, the interaction between FGF18 and SWI/SNF-related matrix-associated actin-dependent regulator of chromatin subfamily A member 5 (SMARCA5) protein was analyzed by coimmunoprecipitation (Co-IP) and a yeast two-hybrid assay. Results A total of 45 differentially expressed (DE) lncRNAs, with DE ATAC-seq peaks in their promoter region, were classified as open chromatin-associated lncRNAs. A skeletal muscle-specific lncRNA (MSTRG.15576.9; MYH1G-AS), which is one of the open chromatin-associated lncRNA, was identified. MYH1G-AS transcription is coordinately regulated by transcription factors (TF) SMAD3 and SP2. Moreover, SP2 represses ALKBH5 transcription to weaken ALKBH5-mediated m6A demethylation of MYH1G-AS, thus destroying MYH1G-AS RNA stability. MYH1G-AS accelerates myoblast proliferation but restrains myoblast differentiation. Moreover, MYH1G-AS drives a switch from slow-twitch to fast-twitch fibers and causes muscle atrophy. Mechanistically, MYH1G-AS inhibits FGF18 protein stabilization to reduce the interaction of FGF18 to SMARCA5, thus repressing chromatin accessibility of the SMAD4 promoter to activate the SMAD4-dependent pathway. Conclusions Our results reveal a new pattern of the regulation of lncRNA expression at diverse levels and help expound the regulation of m6A methylation on chromatin status. Graphical Abstract

Published

2024

14. MYH1G-AS is a chromatin-associated lncRNA that regulates skeletal muscle development in chicken.

Author

Cai, Bolin, Ma, Manting, Yuan, Rongshuai, Zhou, Zhen, Zhang, Jing, Kong, Shaofen, Lin, Duo, Lian, Ling, Li, Juan, Zhang, Xiquan, and Nie, Qinghua

Abstract

Background: Skeletal muscle development is pivotal for animal growth and health. Recently, long noncoding RNAs (lncRNAs) were found to interact with chromatin through diverse roles. However, little is known about how lncRNAs act as chromatin-associated RNAs to regulate skeletal muscle development. Here, we aim to investigate the regulation of chromatin-associated RNA (MYH1G-AS) during skeletal muscle development. Methods: We provided comprehensive insight into the RNA profile and chromatin accessibility of different myofibers, combining RNA sequencing (RNA-seq) with an assay for transposase-accessible chromatin with high-throughput sequencing (ATAC-seq). The dual-luciferase reporter assay and chromatin immunoprecipitation (ChIP) assay were used to analyze the transcriptional regulation mechanism of MYH1G-AS. ALKBH5-mediated MYH1G-AS N6-methyladenosine (m6A) demethylation was assessed by a single-base elongation and ligation-based qPCR amplification method (SELECT) assay. Functions of MYH1G-AS were investigated through a primary myoblast and lentivirus/cholesterol-modified antisense oligonucleotide (ASO)-mediated animal model. To validate the interaction of MYH1G-AS with fibroblast growth factor 18 (FGF18) protein, RNA pull down and an RNA immunoprecipitation (RIP) assay were performed. Specifically, the interaction between FGF18 and SWI/SNF-related matrix-associated actin-dependent regulator of chromatin subfamily A member 5 (SMARCA5) protein was analyzed by coimmunoprecipitation (Co-IP) and a yeast two-hybrid assay. Results: A total of 45 differentially expressed (DE) lncRNAs, with DE ATAC-seq peaks in their promoter region, were classified as open chromatin-associated lncRNAs. A skeletal muscle-specific lncRNA (MSTRG.15576.9; MYH1G-AS), which is one of the open chromatin-associated lncRNA, was identified. MYH1G-AS transcription is coordinately regulated by transcription factors (TF) SMAD3 and SP2. Moreover, SP2 represses ALKBH5 transcription to weaken ALKBH5-mediated m6A demethylation of MYH1G-AS, thus destroying MYH1G-AS RNA stability. MYH1G-AS accelerates myoblast proliferation but restrains myoblast differentiation. Moreover, MYH1G-AS drives a switch from slow-twitch to fast-twitch fibers and causes muscle atrophy. Mechanistically, MYH1G-AS inhibits FGF18 protein stabilization to reduce the interaction of FGF18 to SMARCA5, thus repressing chromatin accessibility of the SMAD4 promoter to activate the SMAD4-dependent pathway. Conclusions: Our results reveal a new pattern of the regulation of lncRNA expression at diverse levels and help expound the regulation of m6A methylation on chromatin status. [ABSTRACT FROM AUTHOR]

Published

2024

15. The Integration of Genome-Wide DNA Methylation and Transcriptomics Identifies the Potential Genes That Regulate the Development of Skeletal Muscles in Ducks.

Author

Lu, Yinglin, Zhou, Jing, Li, Fan, Cao, Heng, Zhang, Xingyu, Yu, Debing, He, Zongliang, Ji, Hongjie, Lv, Kunpeng, Wu, Guansuo, and Yu, Minli

Subjects

*SKELETAL muscle, *DNA methylation, *MUSCLE growth, *DUCKS, *WHOLE genome sequencing, *CYTOSKELETAL proteins, *EPIGENOMICS

Abstract

DNA methylation is a pivotal epigenetic regulatory mechanism in the development of skeletal muscles. Nonetheless, the regulators responsible for DNA methylation in the development of embryonic duck skeletal muscles remain unknown. In the present study, whole genome bisulfite sequencing (WGBS) and transcriptome sequencing were conducted on the skeletal muscles of embryonic day 21 (E21) and day 28 (E28) ducks. The DNA methylation pattern was found to fall mainly within the cytosine-guanine (CG) context, with high methylation levels in the intron, exon, and promoter regions. Overall, 7902 differentially methylated regions (DMRs) were identified, which corresponded to 3174 differentially methylated genes (DMGs). By using integrative analysis of both WGBS with transcriptomics, we identified 1072 genes that are DMGs that are negatively associated with differentially expressed genes (DEGs). The gene ontology (GO) analysis revealed significant enrichment in phosphorylation, kinase activity, phosphotransferase activity, alcohol-based receptors, and binding to cytoskeletal proteins. The Kyoto Encyclopedia of Genes and Genomes (KEGGs) analysis showed significant enrichment in MAPK signaling, Wnt signaling, apelin signaling, insulin signaling, and FoxO signaling. The screening of enriched genes showed that hyper-methylation inhibited the expression of Idh3a, Got1, Bcl2, Mylk2, Klf2, Erbin, and Klhl38, and hypo-methylation stimulated the expression of Col22a1, Dnmt3b, Fn1, E2f1, Rprm, and Wfikkn1. Further predictions showed that the CpG islands in the promoters of Klhl38, Klf2, Erbin, Mylk2, and Got1 may play a crucial role in regulating the development of skeletal muscles. This study provides new insights into the epigenetic regulation of the development of duck skeletal muscles. [ABSTRACT FROM AUTHOR]

Published

2023

16. Comparative Genomics Identifies the Evolutionarily Conserved Gene TPM3 as a Target of eca-miR-1 Involved in the Skeletal Muscle Development of Donkeys.

Author

Yang, Ge, Sun, Minhao, Wang, Zhaofei, Hu, Qiaoyan, Guo, Jiajun, Yu, Jie, Lei, Chuzhao, and Dang, Ruihua

Subjects

*MUSCLE growth, *SKELETAL muscle, *DONKEYS, *GENE targeting, *GENE families, *COMPARATIVE genomics, *MICRORNA genetics

Abstract

Species within the genus Equus are valued for their draft ability. Skeletal muscle forms the foundation of the draft ability of Equus species; however, skeletal muscle development-related conserved genes and their target miRNAs are rarely reported for Equus. In this study, a comparative genomics analysis was performed among five species (horse, donkey, zebra, cattle, and goat), and the results showed that a total of 15,262 (47.43%) genes formed the core gene set of the five species. Only nine chromosomes (Chr01, Chr02, Chr03, Chr06, Chr10, Chr18, Chr22, Chr27, Chr29, and Chr30) exhibited a good collinearity relationship among Equus species. The micro-synteny analysis results showed that TPM3 was evolutionarily conserved in chromosome 1 in Equus. Furthermore, donkeys were used as the model species for Equus to investigate the genetic role of TPM3 in muscle development. Interestingly, the results of comparative transcriptomics showed that the TPM3 gene was differentially expressed in donkey skeletal muscle S1 (2 months old) and S2 (24 months old), as verified via RT-PCR. Dual-luciferase test analysis showed that the TPM3 gene was targeted by differentially expressed miRNA (eca-miR-1). Furthermore, a total of 17 TPM3 gene family members were identified in the whole genome of donkey, and a heatmap analysis showed that EaTPM3-5 was a key member of the TPM3 gene family, which is involved in skeletal muscle development. In conclusion, the TPM3 gene was conserved in Equus, and EaTPM3-5 was targeted by eca-miR-1, which is involved in skeletal muscle development in donkeys. [ABSTRACT FROM AUTHOR]

Published

2023

17. Integrated analysis of circRNA, lncRNA, miRNA and mRNA to reveal the ceRNA regulatory network of postnatal skeletal muscle development in Ningxiang pig

Author

Zonggang Yu, Xueli Xu, Nini Ai, Kaiming Wang, Peiwen Zhang, Xintong Li, Sui LiuFu, Xiaolin Liu, Jun Jiang, Jingjing Gu, Ning Gao, and Haiming Ma

Subjects

ceRNA network, circRNA, lncRNA, Ningxiang pig, skeletal muscle development, whole transcriptome, Biology (General), QH301-705.5

Abstract

Introduction: The development of skeletal muscle is regulated by regulatory factors of genes and non-coding RNAs (ncRNAs).Methods: The objective of this study was to understand the transformation of muscle fiber type in the longissimus dorsi muscle of male Ningxiang pigs at four different growth stages (30, 90, 150, and 210 days after birth, n = 3) by histological analysis and whole transcriptome sequencing. Additionally, the study investigated the expression patterns of various RNAs involved in muscle fiber transformation and constructed a regulatory network for competing endogenous RNA (ceRNA) that includes circular RNA (circRNA)/long non-coding RNA (lncRNA)-microRNA (miRNA)-messenger RNA (mRNA).Results: Histomorphology analysis showed that the diameter of muscle fiber reached its maximum at 150 days after birth. The slow muscle fiber transformation showed a pattern of initial decrease followed by an increase. 29,963 circRNAs, 2,683 lncRNAs, 986 miRNAs and 22,411 mRNAs with expression level ≥0 were identified by whole transcriptome sequencing. Furthermore, 642 differentially expressed circRNAs (DEc), 505 differentially expressed lncRNAs (DEl), 316 differentially expressed miRNAs (DEmi) and 6,090 differentially expressed mRNAs (DEm) were identified by differential expression analysis. Functions of differentially expressed mRNA were identified by gene ontology (GO) and Kyoto Encyclopedia of Genes and Genomes (KEGG). GO enrichment analysis indicates that 40 known genes and 6 new genes are associated with skeletal muscle development. Additionally, KEGG analysis shows that these genes regulate skeletal muscle development via MAPK, FoxO, Hedgehog, PI3K-Akt, Notch, VEGF and other signaling pathways. Through protein-protein interaction (PPI) and transcription factor prediction (TFP), the action mode of skeletal muscle-related genes was explored. PPI analysis showed that there were stable interactions among 19 proteins, meanwhile, TFP analysis predicted 22 transcription factors such as HMG20B, MYF6, MYOD1 and MYOG, and 12 of the 19 interacting proteins were transcription factors. The regulatory network of ceRNA related to skeletal muscle development was constructed based on the correlation of various RNA expression levels and the targeted binding characteristics with miRNA. The regulatory network included 31 DEms, 59 miRNAs, 667 circRNAs and 224 lncRNAs.conclusion: Overall, the study revealed the role of ceRNA regulatory network in the transformation of skeletal muscle fiber types in Ningxiang pigs, which contributes to the understanding of ceRNA regulatory network in Ningxiang pigs during the skeletal muscle development period.

Published

2023

18. Genome-Wide Analysis of MAMSTR Transcription Factor-Binding Sites via ChIP-Seq in Porcine Skeletal Muscle Fibroblasts.

Author

Li, Chenlei, Zhang, Zhe, Wei, Yilin, Qi, Kunlong, Dou, Yaqing, Song, Chenglei, Liu, Yingke, Li, Xinjian, Li, Xiuling, Wang, Kejun, Qiao, Ruimin, Yang, Feng, and Han, Xuelei

Subjects

*SKELETAL muscle, *MUSCLE growth, *ADIPOGENESIS, *ANIMAL genetics, *FIBROBLASTS, *IMMUNOPRECIPITATION, *GENETIC transcription regulation

Abstract

Simple Summary: Skeletal muscle is the most abundant tissue in animals, accounting for 45–60% of the body weight of meat animals, and the growth and development of skeletal muscle has the most direct impact on lean meat percentage and muscle quality. Therefore, exploring the molecular regulation mechanism of skeletal muscle growth and development is an important basis for improving pig meat production performance, and it has also been a research focus in animal genetics in recent years. In this study, ChIP-seq and other methods were used to explore the transcriptional regulation mechanism of new transcription factor MAMSTR in pig skeletal muscle development, The results of this study can further reveal the regulatory mechanism of pig skeletal muscle growth and development, identify new genes related to pig skeletal muscle growth and development, and provide a better reference for pig-farming practices and breeding of high-quality meat pig breeds. Myocyte enhancer factor-2-activating motif and SAP domain-containing transcriptional regulator (MAMSTR) regulates its downstream through binding in its promoter regions. However, its molecular mechanism, particularly the DNA-binding sites, and coregulatory genes are quite unexplored. Therefore, to identify the genome-wide binding sites of the MAMSTR transcription factors and their coregulatory genes, chromatin immunoprecipitation sequencing was carried out. The results showed that MAMSTR was associated with 1506 peaks, which were annotated as 962 different genes. Most of these genes were involved in transcriptional regulation, metabolic pathways, and cell development and differentiation, such as AMPK signaling pathway, TGF-beta signaling pathway, transcription coactivator activity, transcription coactivator binding, adipocytokine signaling pathway, fat digestion and absorption, skeletal muscle fiber development, and skeletal muscle cell differentiation. Lastly, the expression levels and transcriptional activities of PID1, VTI1B, PRKAG1, ACSS2, and SLC28A3 were screened and verified via functional markers and analysis. Overall, this study has increased our understanding of the regulatory mechanism of MAMSTR during skeletal muscle fibroblast development and provided a reference for analyzing muscle development mechanisms. [ABSTRACT FROM AUTHOR]

Published

2023

19. Effects of Equol Supplementation on Growth Performance, Redox Status, Intestinal Health and Skeletal Muscle Development of Weanling Piglets with Intrauterine Growth Retardation.

Author

Zhang, Yong, Ren, Jingchang, Chen, Li, Yan, Honglin, Zou, Tiande, Zhang, Hongfu, and Liu, Jingbo

Subjects

*FETAL growth retardation, *MUSCLE growth, *PIGLETS, *SKELETAL muscle, *INTESTINES, *BACTERIAL metabolism, *IMMUNOGLOBULIN G, *DIETARY supplements

Abstract

Simple Summary: Intrauterine growth retardation (IUGR) hurts the postnatal growth and development of weanling piglets. Equol (Eq), a primary bioactive metabolite of daidzein, derives from intestinal bacterial metabolism and exerts numerous biological benefits. Nevertheless, no evidence is available to discover whether dietary Eq treatment exerts positive influences on the growth performance, redox status, intestinal health and skeletal muscle development of piglets with IUGR. Therefore, the aim of this study was to evaluate the influences of Eq supplementation on growth performance, redox status, intestinal health and skeletal muscle development. Here, twenty IUGR piglets and ten normal-birth-weight (NBW) female weanling piglets were used in this study and the results showed that Eq treatment enhanced antioxidant capacity and intestinal health, and facilitated skeletal muscle development, thus promoting the growth performance of IUGR piglets. Our findings provide significant implications for improving the growth performance of IUGR piglets and highlighting feasible applications in pig production. Animals with intrauterine growth retardation (IUGR) usually undergo injured postnatal growth and development during the early period after birth. Equol (Eq), an isoflavan produced by gut bacteria in response to daidzein intake, has various health benefits. Therefore, the objective of this study was to evaluate whether Eq supplementation can influence the growth performance, redox status, intestinal health and skeletal muscle development of weanling piglets with IUGR. A total of 10 normal-birth-weight (NBW) newborn female piglets and 20 newborn female piglets with IUGR were selected. After weaning at the age of 21 d, 10 NBW piglets and 10 IUGR piglets were allocated to the NBW group and IUGR group, respectively, and offered a basal diet. The other 10 IUGR piglets were allocated to the IUGR + Eq group and offered a basal diet with 50 mg of Eq per kg of diet. The whole trial lasted for 21 d. At the end of the feeding trial, all piglets were sacrificed for the collection of serum, intestinal tissues and skeletal muscles. Supplementation with Eq increased the average daily gain (ADG), average daily feed intake (ADFI), duodenal villus height to crypt depth ratio (V/C), jejunal villus height and V/C, but reduced the duodenal crypt depth in neonatal piglets with IUGR. Meanwhile, Eq supplementation elevated the activities of superoxide dismutase (SOD) and catalase (CAT) in the serum and duodenum and the activity of SOD in the jejunum, but lowered malondialdehyde (MDA) content in the serum, jejunum and ileum of piglets with IUGR. In addition, supplementation with Eq reduced diamine oxidase (DAO) activity and the levels of D-lactate and endotoxin in serum, and the tumor necrosis factor-α (TNF-α) level in jejunum and ileum, whereas the concentration of serum immunoglobulin G (IgG) and the mRNA levels of intestinal barrier-related markers in jejunum and ileum of IUGR piglets were increased. Furthermore, supplementation with Eq elevated the percentage of fast-fibers and was accompanied with higher mRNA expression of myosin heavy chain IIb (MyHC IIb) and lower mRNA levels in MyHC I in the longissimus thoracis (LT) muscle of IUGR piglets. In summary, Eq supplementation can promote antioxidant capacity, maintain intestinal health and facilitate skeletal muscle development, thus resulting in the higher growth performance of IUGR piglets. [ABSTRACT FROM AUTHOR]

Published

2023

20. Tceal7 Regulates Skeletal Muscle Development through Its Interaction with Cdk1.

Author

Xiong, Zhenzhen, Wang, Mengni, Wu, Jianhua, and Shi, Xiaozhong

Subjects

*MUSCLE growth, *SKELETAL muscle, *AMINO acid sequence, *TRANSGENIC mice, *PROTEIN-protein interactions

Abstract

We have previously reported Tceal7 as a muscle-specific gene that represses myoblast proliferation and promotes myogenic differentiation. The regulatory mechanism of Tceal7 gene expression has been well clarified recently. However, the underlying mechanism of Tceal7 function in skeletal muscle development remains to be elucidated. In the present study, we have generated an MCK 6.5 kb-HA-Tceal7 transgenic model. The transgenic mice are born normally, while they have displayed defects in the growth of body weight and skeletal muscle myofiber during postnatal development. Although four RxL motifs have been identified in the Tceal7 protein sequence, we have not detected any direct protein-protein interaction between Tceal7 and Cyclin A2, Cyclin B1, Cylin D1, or Cyclin E1. Further analysis has revealed the interaction between Tceal7 and Cdk1 instead of Cdk2, Cdk4, or Cdk6. Transgenic overexpression of Tceal7 reduces phosphorylation of 4E-BP1 Ser65, p70S6K1 Thr389, and Cdk substrates in skeletal muscle. In summary, these studies have revealed a novel mechanism of Tceal7 in skeletal muscle development. [ABSTRACT FROM AUTHOR]

Published

2023

21. Global Long Noncoding RNA Expression Profiling of MSTN and FGF5 Double-Knockout Sheep Reveals the Key Gatekeepers of Skeletal Muscle Development.

Author

Chen, Mingming, Lian, Di, Li, Yan, Zhao, Yue, Xu, Xueling, Liu, Zhimei, Zhang, Jinlong, Zhang, Xiaosheng, Wu, Sujun, Qi, Shiyu, Deng, Shoulong, Yu, Kun, and Lian, Zhengxing

Subjects

*LINCRNA, *GENE expression, *MUSCLE growth, *SKELETAL muscle, *FIBROBLAST growth factors, *SHEEP, *RYANODINE receptors, *MERINO sheep

Abstract

Improving livestock and poultry growth rates and increasing meat production are urgently needed worldwide. Previously, we produced a myostatin (MSTN) and fibroblast growth factor 5 (FGF5) double-knockout (MF−/−) sheep by CRISPR Cas9 system to improve meat production, and also wool production. Both MF−/− sheep and the F1 generation (MF+/−) sheep showed an obvious "double-muscle" phenotype. In this study, we identified the expression profiles of long noncoding RNAs (lncRNAs) in wild-type and MF+/− sheep, then screened out the key candidate lncRNAs that can regulate myogenic differentiation and skeletal muscle development. These key candidate lncRNAs can serve as critical gatekeepers for muscle contraction, calcium ion transport and skeletal muscle cell differentiation, apoptosis, autophagy, and skeletal muscle inflammation, further revealing that lncRNAs play crucial roles in regulating muscle phenotype in MF+/− sheep. In conclusion, our newly identified lncRNAs may emerge as novel molecules for muscle development or muscle disease and provide a new reference for MSTN-mediated regulation of skeletal muscle development. [ABSTRACT FROM AUTHOR]

Published

2023

22. Hyperpigmentation Inhibits Early Skeletal Muscle Development in Tengchong Snow Chicken Breed.

Author

Shi, Hongmei, Fu, Jing, He, Yang, Li, Zijian, Kang, Jiajia, Hu, Changjie, Zi, Xiannian, Liu, Yong, Zhao, Jinbo, Dou, Tengfei, Jia, Junjing, Duan, Yong, Wang, Kun, and Ge, Changrong

Subjects

*MUSCLE growth, *CHICKEN breeds, *POULTRY breeding, *SKELETAL muscle, *BREAST, *LEG muscles, *MELANOGENESIS

Abstract

Tengchong snow, which has white feathers and black meat, is one of the most important black-bone chicken breeds and a genetic treasure of black food in China. Although the black meat traits are dominant, there are some chickens with white meat traits born in the process of folk selection and breeding. The purpose of this study was to compare the differences in skeletal muscle development between Tengchong snow black meat chickens (BS) and white meat chickens (WS), as well as whether excessive melanin deposition has an effect on skeletal muscle development. The BS and WS groups were selected to determine their muscle development difference at stages of 1, 7, 14, 21, and 42 days, using histological stain methods to analyze the development and composing type of breast and leg muscle fibers, as well as the count of melanin in BS muscle fibers. Finally, we were validated key candidate genes associated with muscle development and melanin synthesis. The results showed that BS breast muscle development was inhibited at 7, 14, and 21 days, while the leg muscle was inhibited at 7, 14, 21, and 42 days, compared to WS. Melanin deposition was present in a temporal migration pattern and was greater in the leg muscles than in the breast muscles, and it focused around blood vessels, as well as the epithelium, perimysium, endomysium, and connective tissue. Additionally, melanin produced an inhibitory effect similar to MSTN during skeletal muscle fiber development, and the inhibition was strongest at the stage of melanin entry between muscle fibers, but the precise mechanisms need to be confirmed. This study revealed that melanin has an inhibitory effect on the early development of skeletal muscle, which will provide new insights into the role of melanin in the black-boned chicken and theoretical references for the future conservation and utilization of black-boned chicken. [ABSTRACT FROM AUTHOR]

Published

2022

23. Comprehensive analysis of lncRNAs involved in skeletal muscle development in ZBED6-knockout Bama pigs

Author

Dandan Wang, Yabin Pu, Yefang Li, Dengke Pan, Shengnan Wang, Wenjie Tian, Yuehui Ma, and Lin Jiang

Subjects

ZBED6 KO pig, lncRNAs, RNA-Seq, Skeletal muscle development, Biotechnology, TP248.13-248.65, Genetics, QH426-470

Abstract

Abstract Background The mutation of insulin-like growth factor 2 (IGF2 mutation) that a single-nucleotide substitution (G→A) in the third intron of IGF2 abrogates the interaction with zinc finger BED-type containing 6 (ZBED6) and leads to increased muscle mass in pigs. IGF2 mutation knock-in (IGF2 KI) and ZBED6 knockout (ZBED6 KO) lead to changes in IGF2 expression and increase muscle mass in mice and pigs. Long noncoding RNAs (lncRNAs) may participate in numerous biological processes, including skeletal muscle development. However, the role of the ZBED6-lncRNA axis in skeletal muscle development is poorly characterized. Results In this study, we assembled transcriptomes using RNA-seq data published in previous studies by our group and identified 11,408 known lncRNAs and 2269 potential lncRNAs in seven tissues, heart, longissimus dorsi, gastrocnemius muscle, liver, spleen, lung and kidney, of ZBED6 KO (lean mass model) and WT Bama pigs. ZBED6 affected the expression of 1570 lncRNAs (differentially expressed lncRNAs [DE-lncRNAs]; log2-fold change ≥ 1, nominal p-value ≤ 0.05) in the seven examined tissues. The expressed lncRNAs (FPKM > 0.1) exhibited tissue-specific patterns in WT pigs. Specifically, 3410 lncRNAs were expressed exclusively in only one tissue. Potential functions of lncRNAs were indirectly predicted by searching their target cis- and trans-regulated protein-coding genes. LncRNAs with tissue-specific expression influence numerous genes related to tissue functions. Weighted gene coexpression network analysis (WGCNA) of 1570 DE-lncRNAs between WT and ZBED6 KO pigs was used to define the following six lncRNA modules specific to different tissues: skeletal muscle, heart, lung, spleen, kidney and liver modules. Furthermore, by conjoint analysis of longissimus dorsi data (tissue-specific expression, muscle module and DE-lncRNAs) and ChIP-PCR revealed NONSUSG002145.1 (adjusted p-values = 0.044), which is coexpressed with the IGF2 gene and binding with ZBED6, may play important roles in ZBED6 KO pig skeletal muscle development. Conclusions These findings indicate that the identified lncRNAs may play essential roles in tissue function and regulate the mechanism of ZBED6 action in skeletal muscle development in pigs. To our knowledge, this is the first study describing lncRNAs in ZBED6 KO pigs. These results may open new research directions leading to a better understanding of the global functions of ZBED6 and of lncRNA functions in skeletal muscle development in pigs.

Published

2021

24. PPARGC1A Is a Moderator of Skeletal Muscle Development Regulated by miR-193b-3p.

Author

Ma, Manting, Cai, Bolin, Kong, Shaofen, Zhou, Zhen, Zhang, Jing, Zhang, Xiquan, and Nie, Qinghua

Subjects

*PGC-1 protein, *MUSCLE growth, *SKELETAL muscle, *FATTY acid oxidation

Abstract

Meat production performance is one of the most important factors in determining the economic value of poultry. Myofiber is the basic unit of skeletal muscle, and its physical and chemical properties determine the meat quality of livestock and poultry to a certain extent. Peroxisome proliferator-activated receptor gamma coactivator 1-alpha (PPARGC1A) as a transcriptional coactivator has been found to be widely involved in a series of biological processes. However, PPARGC1A is still poorly understood in chickens. In this manuscript, we reported that PPARGC1A was highly expressed in slow-twitch myofibers. PPARGC1A facilitated mitochondrial biogenesis and regulated skeletal muscle metabolism by mediating the flux of glycolysis and the TCA cycle. Gain- and loss-of-function analyses revealed that PPARGC1A promoted intramuscular fatty acid oxidation, drove the transformation of fast-twitch to slow-twitch myofibers, and increased chicken skeletal muscle mass. Mechanistically, the expression level of PPARGC1A is regulated by miR-193b-3p. Our findings help to understand the genetic regulation of skeletal muscle development and provide a molecular basis for further research on the antagonism of skeletal muscle development and fat deposition in chickens. [ABSTRACT FROM AUTHOR]

Published

2022

25. Trans-Species Fecal Transplant Revealed the Role of the Gut Microbiome as a Contributor to Energy Metabolism and Development of Skeletal Muscle.

Author

Cai, Liyuan, Li, Min, Zhou, Shuyi, Zhu, Xiaoyan, Zhang, Xianghua, and Xu, Qingbiao

Subjects

SKELETAL muscle, GUT microbiome, FECAL microbiota transplantation, ENERGY development, MUSCLE growth, ENERGY metabolism, FECES

Abstract

The aim of this study was to investigate the influence of the exogenous gut microbiome at early life stages on the development of mice skeletal muscle in adulthood. First, the characteristics of skeletal muscle and the gut microbiota composition of the gut microbiota donors—Erhualian (EH) pigs (a native Chinese breed)—were studied. EH pigs had significantly higher fiber densities and thinner fiber diameters than Duroc × Landrace × Yorkshire crossed (DLY) pigs (p < 0.05). The expression levels of genes related to oxidized muscle fibers, mitochondrial function, and glucose metabolism in the skeletal muscle of EH pigs were significantly higher than those in DLY pigs (p < 0.05). Moreover, the abundances of 8 gut microbial phyla and 35 genera correlated with the skeletal muscle fiber diameters and densities exhibited significant differences (p < 0.05) between EH and DLY pigs. Subsequently, newborn mice were treated with saline (CG) and fecal microbiota suspensions collected from EH pigs (AG), respectively, for 15 days, starting from the day of birth. In adulthood (60 days), the relative abundances of Parabacteroides, Sutterella, and Dehalobacterium were significantly higher in the feces of the AG mice than those of the CG mice. The microbes contribute to improved functions related to lipid and carbohydrate metabolism. The weight, density, and gene expression related to the oxidized muscle fibers, mitochondrial function, and glucose metabolism of the AG group were significantly higher than those of the CG group (p < 0.05), whereas the fiber diameters in the skeletal muscle of the AG mice were significantly lower (p < 0.05) than those of the CG mice. These results suggested that intervention with exogenous microbiota at early stages of life can affect the fiber size and energy metabolism of their skeletal muscle. [ABSTRACT FROM AUTHOR]

Published

2022

26. Regulatory role of RNA N6-methyladenosine modifications during skeletal muscle development

Author

Baojun Yu, Jiamin Liu, Juan Zhang, Tong Mu, Xiaofang Feng, Ruoshuang Ma, and Yaling Gu

Subjects

N6-methyladenosine (m6A) modification, myogenesis, skeletal muscle development, transcriptional regulation, epigenetic, Biology (General), QH301-705.5

Abstract

Functional cells in embryonic myogenesis and postnatal muscle development undergo multiple stages of proliferation and differentiation, which are strict procedural regulation processes. N6-methyladenosine (m6A) is the most abundant RNA modification that regulates gene expression in specific cell types in eukaryotes and regulates various biological activities, such as RNA processing and metabolism. Recent studies have shown that m6A modification-mediated transcriptional and post-transcriptional regulation plays an essential role in myogenesis. This review outlines embryonic and postnatal myogenic differentiation and summarizes the important roles played by functional cells in each developmental period. Furthermore, the key roles of m6A modifications and their regulators in myogenesis were highlighted, and the synergistic regulation of m6A modifications with myogenic transcription factors was emphasized to characterize the cascade of transcriptional and post-transcriptional regulation during myogenesis. This review also discusses the crosstalk between m6A modifications and non-coding RNAs, proposing a novel mechanism for post-transcriptional regulation during skeletal muscle development. In summary, the transcriptional and post-transcriptional regulatory mechanisms mediated by m6A and their regulators may help develop new strategies to maintain muscle homeostasis, which are expected to become targets for animal muscle-specific trait breeding and treatment of muscle metabolic diseases.

Published

2022

27. Comprehensive Transcriptome Analysis Reveals the Role of lncRNA in Fatty Acid Metabolism in the Longissimus Thoracis Muscle of Tibetan Sheep at Different Ages

Author

Gaoliang Bao, Shaobin Li, Fangfang Zhao, Jiqing Wang, Xiu Liu, Jiang Hu, Bingang Shi, Yuliang Wen, Li Zhao, and Yuzhu Luo

Subjects

lncRNA, skeletal muscle development, fatty acid metabolism, Tibetan sheep, regulation of nutrient metabolism, Nutrition. Foods and food supply, TX341-641

Abstract

Long noncoding RNA (lncRNA) plays an important regulatory role in mammalian adipogenesis and lipid metabolism. However, their function in the longissimus thoracis (LT) muscle of fatty acid metabolism of Tibetan sheep remains undefined. In this study, fatty acid and fat content in LT muscle of Tibetan sheep were determined, and RNA sequencing was performed to reveal the temporal regularity of lncRNA expression and the effect of lncRNA-miRNA-mRNA ceRNA regulatory network on lipid metabolism of LT muscle in Tibetan sheep at four growth stages (4-month-old, 4 m; 1.5-year-old, 1.5 y; 3.5-year-old, 3.5 y; 6-year-old, 6 y). The results indicated that the intramuscular fat (IMF) content was highest at 1.5 y. Moreover, the monounsaturated fatty acid (MUFA) content in 1.5 y of Tibetan sheep is significantly higher than those of the other groups (P < 0.05), and it was also rich in a variety of polyunsaturated fatty acids (PUFA). A total of 360 differentially expressed lncRNAs (DE lncRNAs) were identified from contiguous period transcriptome comparative groups of 4 m vs. 1.5 y, 1.5 y vs. 3.5 y, 3.5 y vs. 6 y, and 4 m vs. 6 y, respectively. Kyoto encyclopedia of genes and genomes (KEGG) enrichment analysis found that the target genes in lncRNA trans-mRNA were significantly related to the protein digestion, absorption, and fatty acid biosynthesis pathways (P < 0.05), which demonstrated that DE lncRNA trans-regulated the target genes, and further regulated the growth and development of the LT muscle and intramuscular fatty acid metabolism in Tibetan sheep. We further analyzed the role of the lncRNA-miRNA-mRNA regulatory network in the lipid metabolism of Tibetan sheep. Additionally, GPD2, LIPE (lipase E hormone-sensitive enzyme), TFDP2, CPT1A, ACACB, ADIPOQ, and other mRNA related to fatty acid and lipid metabolism and the corresponding lncRNA-miRNA regulatory pairs were identified. The enrichment analysis of mRNA in the regulatory network found that the AMPK signaling pathway was the most significantly enriched (P = 0.0000112361). Comprehensive transcriptome analysis found that the LIPE, ADIPOQ, ACACB, and CPT1A that were regulated by lncRNA might change the formation of energy metabolism in Tibetan sheep muscle through the AMPK signaling pathway, and oxidized muscle fibers are transformed into glycolytic muscle fibers, reduced IMF content, and the fatty acid profile also changed.

Published

2022

28. Regulation of Myostatin on the Growth and Development of Skeletal Muscle

Author

Ming-Ming Chen, Yi-Ping Zhao, Yue Zhao, Shou-Long Deng, and Kun Yu

Subjects

myostatin, skeletal muscle development, myogenesis, protein synthesis, degradation, Biology (General), QH301-705.5

Abstract

Myostatin (MSTN), a member of the transforming growth factor-β superfamily, can negatively regulate the growth and development of skeletal muscle by autocrine or paracrine signaling. Mutation of the myostatin gene under artificial or natural conditions can lead to a significant increase in muscle quality and produce a double-muscle phenotype. Here, we review the similarities and differences between myostatin and other members of the transforming growth factor-β superfamily and the mechanisms of myostatin self-regulation. In addition, we focus extensively on the regulation of myostatin functions involved in myogenic differentiation, myofiber type conversion, and skeletal muscle protein synthesis and degradation. Also, we summarize the induction of reactive oxygen species generation and oxidative stress by myostatin in skeletal muscle. This review of recent insights into the function of myostatin will provide reference information for future studies of myostatin-regulated skeletal muscle formation and may have relevance to agricultural fields of study.

Published

2021

29. Characterization of Long Non-coding RNAs Modified by m6A RNA Methylation in Skeletal Myogenesis

Author

Shu-Juan Xie, Shuang Tao, Li-Ting Diao, Pan-Long Li, Wei-Cai Chen, Zhi-Gang Zhou, Yan-Xia Hu, Ya-Rui Hou, Hang Lei, Wan-Yi Xu, Wen-Jie Chen, Yan-Wen Peng, Qi Zhang, and Zhen-Dong Xiao

Subjects

m6A, lncRNAs, Brip1os, METTL3, skeletal muscle development, Biology (General), QH301-705.5

Abstract

Proper development of mammalian skeletal muscle relies on precise gene expression regulation. Our previous studies revealed that muscle development is regulated by both mRNA and long non-coding RNAs (lncRNAs). Accumulating evidence has demonstrated that N6-methyladenosine (m6A) plays important roles in various biological processes, making it essential to profile m6A modification on a transcriptome-wide scale in developing muscle. Patterns of m6A methylation in lncRNAs in developing muscle have not been uncovered. Here, we reveal differentially expressed lncRNAs and report temporal m6A methylation patterns in lncRNAs expressed in mouse myoblasts and myotubes by RNA-seq and methylated RNA immunoprecipitation (MeRIP) sequencing. Many lncRNAs exhibit temporal differential expression, and m6A-lncRNAs harbor the consensus m6A motif “DRACH” along lncRNA transcripts. Interestingly, we found that m6A methylation levels of lncRNAs are positively correlated with the transcript abundance of lncRNAs. Overexpression or knockdown of m6A methyltransferase METTL3 alters the expression levels of these lncRNAs. Furthermore, we highlight that the function of m6A genic lncRNAs might correlate to their nearby mRNAs. Our work reveals a fundamental expression reference of m6A-mediated epitranscriptomic modifications in lncRNAs that are temporally expressed in developing muscle.

Published

2021

30. circHIPK3 regulates proliferation and differentiation of myoblast through the miR‐7/TCF12 pathway.

Author

Gao, Mengjin, Li, Xue, Yang, Zuojun, Zhao, Shuo, Ling, Xingxing, Li, Jingjing, Xing, Kai, Qi, Xiaolong, Wang, Xiangguo, Xiao, Longfei, Ni, Hemin, Guo, Yong, and Sheng, Xihui

Subjects

*MYOBLASTS, *INHIBITION of cellular proliferation, *MUSCLE growth, *CIRCULAR RNA, *SKELETAL muscle, *NON-coding RNA

Abstract

Skeletal muscle development is a complex biological process involving multiple key genes, signaling pathways and noncoding RNAs, including microRNAs and circular RNAs (circRNAs). However, the regulatory relationship among them is so complicated that it has not yet been fully elucidated. In this study, we found that miR‐7 inhibited C2C12 cell proliferation and differentiation by targeting transcription factor 12 (TCF12). circHIPK3 acted as a competing endogenous RNA, and its overexpression effectively reversed the regulation of miR‐7 on C2C12 cell proliferation and differentiation by increasing TCF12 expression. Taken together, our findings provide evidence that circHIPK3 regulates skeletal muscle development through the miR‐7/TCF12 pathway. This study provides a scientific basis for further research on skeletal muscle development at the circRNA level. [ABSTRACT FROM AUTHOR]

Published

2021

31. Transcriptomic regulatory analysis of skeletal muscle development in landrace pigs.

Author

Yu, Mubin, Feng, Yanqin, Yan, Jiamao, Zhang, Xiaoyuan, Tian, Zhe, Wang, Tao, Wang, Junjie, and Shen, Wei

Subjects

*SKELETAL muscle, *MUSCLE growth, *REGULATOR genes, *TRANSCRIPTOMES, *GENE expression

Abstract

• This study constructed a transcriptome expression map of skeletal muscle development in Landrace pigs from embryonic stage to adulthood. • The development process of skeletal muscle is divided into four developmental stages, each stage has its own unique developmental characteristics and regulatory genes. • The transformation of skeletal muscle fiber types and the dramatic changes in gene transcription levels during the skeletal muscle volume expansion stage. • A total of 11 candidate genes potentially regulate the transformation of skeletal muscle fiber types and the process of skeletal muscle volume expansion. • This study deepens the understanding of the development process of skeletal muscle and is beneficial to the improvement of meat production traits. The development of pig skeletal muscle is a complex dynamic regulation process, which mainly includes the formation of primary and secondary muscle fibers, the remodeling of muscle fibers, and the maturation of skeletal muscle; However, the regulatory mechanism of the entire developmental process remains unclear. This study analyzed the whole-transcriptome data of skeletal muscles at 27 developmental nodes (E33-D180) in Landrace pigs, and their key regulatory factors in the development process were identified using the bioinformatics method. Firstly, we constructed a transcriptome expression map of skeletal muscle development from embryo to adulthood in Landrace pig. Subsequently, due to drastic change in gene expression, the perinatal periods including E105, D0 and D9, were focused, and the genes related to the process of muscle fiber remodeling and volume expansion were revealed. Then, though conjoint analysis with miRNA and lncRNA transcripts, a ceRNA network were identified, which consist of 11 key regulatory genes (such as CHAC1 , RTN4IP1 and SESN1), 7 miRNAs and 43 lncRNAs, and they potentially play an important role in the process of muscle fiber differentiation, muscle fiber remodeling and volume expansion, intramuscular fat deposition, and other skeletal muscle developmental events. In summary, we reveal candidate genes and underlying molecular regulatory networks associated with perinatal skeletal muscle fiber type remodeling and expansion. These data provide new insights into the molecular regulation of mammalian skeletal muscle development and diversity. [ABSTRACT FROM AUTHOR]

Published

2024

32. Comprehensive analysis of lncRNAs involved in skeletal muscle development in ZBED6-knockout Bama pigs.

Author

Wang, Dandan, Pu, Yabin, Li, Yefang, Pan, Dengke, Wang, Shengnan, Tian, Wenjie, Ma, Yuehui, and Jiang, Lin

Subjects

SKELETAL muscle, MUSCLE growth, SOMATOMEDIN A, LINCRNA, SWINE, MUSCLE mass

Abstract

Background: The mutation of insulin-like growth factor 2 (IGF2 mutation) that a single-nucleotide substitution (G→A) in the third intron of IGF2 abrogates the interaction with zinc finger BED-type containing 6 (ZBED6) and leads to increased muscle mass in pigs. IGF2 mutation knock-in (IGF2 KI) and ZBED6 knockout (ZBED6 KO) lead to changes in IGF2 expression and increase muscle mass in mice and pigs. Long noncoding RNAs (lncRNAs) may participate in numerous biological processes, including skeletal muscle development. However, the role of the ZBED6-lncRNA axis in skeletal muscle development is poorly characterized. Results: In this study, we assembled transcriptomes using RNA-seq data published in previous studies by our group and identified 11,408 known lncRNAs and 2269 potential lncRNAs in seven tissues, heart, longissimus dorsi, gastrocnemius muscle, liver, spleen, lung and kidney, of ZBED6 KO (lean mass model) and WT Bama pigs. ZBED6 affected the expression of 1570 lncRNAs (differentially expressed lncRNAs [DE-lncRNAs]; log2-fold change ≥ 1, nominal p-value ≤ 0.05) in the seven examined tissues. The expressed lncRNAs (FPKM > 0.1) exhibited tissue-specific patterns in WT pigs. Specifically, 3410 lncRNAs were expressed exclusively in only one tissue. Potential functions of lncRNAs were indirectly predicted by searching their target cis- and trans-regulated protein-coding genes. LncRNAs with tissue-specific expression influence numerous genes related to tissue functions. Weighted gene coexpression network analysis (WGCNA) of 1570 DE-lncRNAs between WT and ZBED6 KO pigs was used to define the following six lncRNA modules specific to different tissues: skeletal muscle, heart, lung, spleen, kidney and liver modules. Furthermore, by conjoint analysis of longissimus dorsi data (tissue-specific expression, muscle module and DE-lncRNAs) and ChIP-PCR revealed NONSUSG002145.1 (adjusted p-values = 0.044), which is coexpressed with the IGF2 gene and binding with ZBED6, may play important roles in ZBED6 KO pig skeletal muscle development. Conclusions: These findings indicate that the identified lncRNAs may play essential roles in tissue function and regulate the mechanism of ZBED6 action in skeletal muscle development in pigs. To our knowledge, this is the first study describing lncRNAs in ZBED6 KO pigs. These results may open new research directions leading to a better understanding of the global functions of ZBED6 and of lncRNA functions in skeletal muscle development in pigs. [ABSTRACT FROM AUTHOR]

Published

2021

33. Trans-Species Fecal Transplant Revealed the Role of the Gut Microbiome as a Contributor to Energy Metabolism and Development of Skeletal Muscle

Author

Liyuan Cai, Min Li, Shuyi Zhou, Xiaoyan Zhu, Xianghua Zhang, and Qingbiao Xu

Subjects

pigs, mice, gut microbiome, fecal microbiota transplantation, skeletal muscle development, Microbiology, QR1-502

Abstract

The aim of this study was to investigate the influence of the exogenous gut microbiome at early life stages on the development of mice skeletal muscle in adulthood. First, the characteristics of skeletal muscle and the gut microbiota composition of the gut microbiota donors—Erhualian (EH) pigs (a native Chinese breed)—were studied. EH pigs had significantly higher fiber densities and thinner fiber diameters than Duroc × Landrace × Yorkshire crossed (DLY) pigs (p < 0.05). The expression levels of genes related to oxidized muscle fibers, mitochondrial function, and glucose metabolism in the skeletal muscle of EH pigs were significantly higher than those in DLY pigs (p < 0.05). Moreover, the abundances of 8 gut microbial phyla and 35 genera correlated with the skeletal muscle fiber diameters and densities exhibited significant differences (p < 0.05) between EH and DLY pigs. Subsequently, newborn mice were treated with saline (CG) and fecal microbiota suspensions collected from EH pigs (AG), respectively, for 15 days, starting from the day of birth. In adulthood (60 days), the relative abundances of Parabacteroides, Sutterella, and Dehalobacterium were significantly higher in the feces of the AG mice than those of the CG mice. The microbes contribute to improved functions related to lipid and carbohydrate metabolism. The weight, density, and gene expression related to the oxidized muscle fibers, mitochondrial function, and glucose metabolism of the AG group were significantly higher than those of the CG group (p < 0.05), whereas the fiber diameters in the skeletal muscle of the AG mice were significantly lower (p < 0.05) than those of the CG mice. These results suggested that intervention with exogenous microbiota at early stages of life can affect the fiber size and energy metabolism of their skeletal muscle.

Published

2022

34. Reorganization of chromatin architecture during prenatal development of porcine skeletal muscle.

Author

Yuan, Renqiang, Zhang, Jiaman, Wang, Yujie, Zhu, Xingxing, Hu, Silu, Zeng, Jianhua, Liang, Feng, Tang, Qianzi, Chen, Yaosheng, Chen, Luxi, Zhu, Wei, Li, Mingzhou, and Mo, Delin

Abstract

Myofibres (primary and secondary myofibre) are the basic structure of muscle and the determinant of muscle mass. To explore the skeletal muscle developmental processes from primary myofibres to secondary myofibres in pigs, we conducted an integrative three-dimensional structure of genome and transcriptomic characterization of longissimus dorsi muscle of pig from primary myofibre formation stage [embryonic Day 35 (E35)] to secondary myofibre formation stage (E80). In the hierarchical genomic structure, we found that 11.43% of genome switched compartment A/B status, 14.53% of topologically associating domains are changed intradomain interactions (D -scores) and 2,730 genes with differential promoter–enhancer interactions and (or) enhancer activity from E35 to E80. The alterations of genome architecture were found to correlate with expression of genes that play significant roles in neuromuscular junction, embryonic morphogenesis, skeletal muscle development or metabolism, typically, NEFL , MuSK , SLN , Mef2D and GCK. Significantly, Sox6 and MATN2 play important roles in the process of primary to secondary myofibres formation and increase the regulatory potential score and genes expression in it. In brief, we reveal the genomic reorganization from E35 to E80 and construct genome-wide high-resolution interaction maps that provide a resource for studying long-range control of gene expression from E35 to E80. [ABSTRACT FROM AUTHOR]

Published

2021

35. HOXA5 Participates in Brown Adipose Tissue and Epaxial Skeletal Muscle Patterning and in Brown Adipocyte Differentiation

Author

Miriam A. Holzman, Abigail Ryckman, Tova M. Finkelstein, Kim Landry-Truchon, Kyra A. Schindler, Jenna M. Bergmann, Lucie Jeannotte, and Jennifer H. Mansfield

Subjects

Hoxa5, brown adipose tissue, adipose development, skeletal muscle development, differentiation, Biology (General), QH301-705.5

Abstract

Brown adipose tissue (BAT) plays critical thermogenic, metabolic and endocrine roles in mammals, and aberrant BAT function is associated with metabolic disorders including obesity and diabetes. The major BAT depots are clustered at the neck and forelimb levels, and arise largely within the dermomyotome of somites, from a common progenitor with skeletal muscle. However, many aspects of BAT embryonic development are not well understood. Hoxa5 patterns other tissues at the cervical and brachial levels, including skeletal, neural and respiratory structures. Here, we show that Hoxa5 also positively regulates BAT development, while negatively regulating formation of epaxial skeletal muscle. HOXA5 protein is expressed in embryonic preadipocytes and adipocytes as early as embryonic day 12.5. Hoxa5 null mutant embryos and rare, surviving adults show subtly reduced iBAT and sBAT formation, as well as aberrant marker expression, lower adipocyte density and altered lipid droplet morphology. Conversely, the epaxial muscles that arise from a common dermomyotome progenitor are expanded in Hoxa5 mutants. Conditional deletion of Hoxa5 with Myf5/Cre can reproduce both BAT and epaxial muscle phenotypes, indicating that HOXA5 is necessary within Myf5-positive cells for proper BAT and epaxial muscle development. However, recombinase-based lineage tracing shows that Hoxa5 does not act cell-autonomously to repress skeletal muscle fate. Interestingly, Hoxa5-dependent regulation of adipose-associated transcripts is conserved in lung and diaphragm, suggesting a shared molecular role for Hoxa5 in multiple tissues. Together, these findings establish a role for Hoxa5 in embryonic BAT development.

Published

2021

36. Dietary guanidinoacetic acid improves the growth performance and skeletal muscle development of finishing pigs through changing myogenic gene expression and myofibre characteristics.

Author

Lu, Yafei, Zou, Tiande, Wang, Zirui, Yang, Jin, Li, Lanhai, Guo, Xiaobo, He, Qin, Chen, Liling, and You, Jinming

Subjects

*MUSCLE growth, *SKELETAL muscle, *SWINE growth, *GENE expression, *SWINE, *ACETIC acid, *SHEARING force

Abstract

This study aimed to evaluate the effects of dietary guanidine acetic acid (GAA) supplementation on growth performance, carcass traits and the expression of muscle growth‐related genes in finishing pigs. A total of 128 (81.03 ± 1.09 kg body weight) crossbred pigs (Duroc × Landrace ×Yorkshire) were blocked by body weight and allotted to 16 pens (eight pigs per pen), and pens were randomly assigned within blocks to one of five dietary treatments, with a basal diet (control group) or a basal diet supplemented with 0.03%, 0.06% and 0.09% GAA respectively. During the 60‐day trial, GAA increased the average dairy gain (ADG) and average daily feed intake (ADFI) (p <.05). The back fat thickness of pigs fed 0.06% GAA was lower than other groups (p <.05). Pigs fed 0.06% GAA had improved lean meat percentage, loin muscle area, shear force and cross‐sectional area of muscle fibre in comparison with control group (p <.05). The drop loss and the muscle fibre density in pigs fed 0.06% GAA were lower than control (p <.05). In addition, dietary GAA enhanced the expression of myosin heavy chain gene (MYH4), myogenic determination (Myod) and myogenic factor 5 (Myf5) in longissimus dorsi and carnitine palmitoyltransferase‐1(CPT‐1) in liver (p <.05). Meanwhile, GAA decreased the expression of Myostatin in longissimus dorsi and fatty acid synthase (FAS) in liver (p <.05). In conclusion, our results showed that appropriate dietary GAA supplementation (0.06%) promotes skeletal muscle development through changing myogenic gene expression and myofibre characteristics. [ABSTRACT FROM AUTHOR]

Published

2020

37. Elevated incubation temperature improves later‐life swimming endurance in juvenile Chinook salmon, Oncorhynchus tshawytscha.

Author

Lim, Dan Dohyung, Milligan, C. Louise, and Morbey, Yolanda E.

Subjects

*CHINOOK salmon, *HIGH temperatures, *BODY size, *EGG incubation, *MUSCLE growth, *SKELETAL muscle

Abstract

The effect of incubation and rearing temperature on muscle development and swimming endurance under a high‐intensity swimming test was investigated in juvenile Chinook salmon (Oncorhynchus tshawytscha) in a hatchery experiment. After controlling for the effects of fork length (LF) and parental identity, times to fatigue of fish were higher when fish were incubated or reared at warmer temperatures. Significant differences among combinations of pre‐ and post‐emergence temperatures conformed to 15–15°C > 15–9°C > 9–9°C > 7–9°C > 7–7°C in 2011 when swimming tests were conducted at 300 accumulated temperature units post‐emergence and 15–9°C > (7–9°C = 7–7°C) in 2012 when swimming tests were conducted at an LF of c. 40 mm. The combination of pre‐ and post‐emergence temperatures also affected the number and size of muscle fibres, with differences among temperature treatments in mean fibre cross‐sectional area persisting after controlling for LF and parental effects. Nonetheless, neither fibre number nor fibre size accounted for significant variation in swimming endurance. Thus, thermal carryover effects on swimming endurance were not mediated by thermal imprinting of muscle structure. This is the first study to test how temperature, body size and muscle structure interact to affect swimming endurance during early development in salmon. [ABSTRACT FROM AUTHOR]

Published

2020

38. Systematic analyses reveal RNA editing events involved in skeletal muscle development of goat (Capra hircus).

Author

Yang, Liu, Li, Li, Kyei, Bismark, Guo, Jiazhong, Zhan, Siyuan, Zhao, Wei, Song, Yumo, Zhong, Tao, Wang, Linjie, Xu, Lingyang, and Zhang, Hongping

Subjects

*RNA editing, *MUSCLE growth, *GOATS, *RNA analysis, *PUERPERIUM

Abstract

RNA editing is a posttranscriptional molecular process involved with specific nucleic modification, which can enhance the diversity of gene products. Adenosine-to-inosine (A-to-I, I is read as guanosine by both splicing and translation machinery) is the main type of RNA editing in mammals, which manifested as AG (adenosine-to-guanosine) in sequence data. Here, we aimed to explore patterns of RNA editing using RNA sequencing data from skeletal muscle at four developmental stages (three fetal periods and one postnatal period) in goat. We found the occurrences of RNA editing events raised at fetal periods and declined at the postnatal period. Also, we observed distinct editing levels of AG editing across stages, and significant difference was found between postnatal period and fetal periods. AG editing patterns in newborn goats are similar to those of 45-day embryo compared with embryo at 105 days and embryo at 60 days. In this study, we found a total of 1415 significantly differential edited AG sites among four groups. Moreover, 420 sites were obviously clustered into six time-series profiles, and one profile had significant association between editing level and gene expression. Our findings provided some novel insights into understanding the molecular mechanism of muscle development in mammals. [ABSTRACT FROM AUTHOR]

Published

2020

39. miR-208b modulating skeletal muscle development and energy homoeostasis through targeting distinct targets.

Author

Fu, Liangliang, Wang, Heng, Liao, Yinlong, Zhou, Peng, Xu, Yueyuan, Zhao, Yunxia, Xie, Shengsong, Zhao, Shuhong, and Li, Xinyun

Abstract

Embryonic and neonatal skeletal muscles grow via the proliferation and fusion of myogenic cells, whereas adult skeletal muscle adapts largely by remodelling pre-existing myofibers and optimizing metabolic balance. It has been reported that miRNAs played key roles during skeletal muscle development through targeting different genes at post-transcriptional level. In this study, we show that a single miRNA (miR-208b) can modulate both the myogenesis and homoeostasis of skeletal muscle by distinct targets. As results, miR-208b accelerates the proliferation and inhibits the differentiation of myogenic cells by targeting the E-protein family member transcription factor 12 (TCF12). Also, miR-208b can stimulate fast-to-slow fibre conversion and oxidative metabolism programme through targeting folliculin interacting protein 1 (FNIP1) but not TCF12 gene. Further, miR-208b could active the AMPK/PGC-1a signalling and mitochondrial biogenesis through targeting FNIP1. Thus, miR-208b could mediate skeletal muscle development and homoeostasis through specifically targeting of TCF12 and FNIP1. [ABSTRACT FROM AUTHOR]

Published

2020

40. Identification and functional analysis of circpdlim5a generated from pdlim5a gene splicing in the skeletal muscle of Japanese flounder (Paralichthys olivaceus).

Author

Wang, Hao, Liu, Min, Tang, Hengtai, Zhang, Zhirui, Wen, Haishen, and He, Feng

Subjects

*GENETIC engineering, *SKELETAL muscle, *PARALICHTHYS, *FUNCTIONAL analysis, *MUSCLE growth, *EPICATECHIN

Abstract

• Screening candidate circpdlim5a from the Japanese flounder transcriptome. • Circpdlim5a has a stable structure and high RNase R tolerance. • Distributed in nucleus and cytoplasm and highly expressed in nucleus. • Circpdlim5a inhibits the expression of proliferation and differentiation genes. Circular RNAs (circRNAs) are non-coding RNAs with endogenous regulatory functions, including regulating skeletal muscle development. However, its role in the development of skeletal muscle in Japanese flounder (Paralichthys olivaceus) is not clear. Therefore we screened a candidate circpdlim5a, which is derived from the gene pdlim5a , from the skeletal muscle transcriptome of Japanese flounder. We characterized circpdlim5a, which was more stable compared to the linear RNA pdlim5a. Distributional characterization of circpdlim5a showed that circpdlim5a was predominantly distributed in the nucleus and was highly expressed in the skeletal muscle of adult Japanese flounder (24 months). When we further studied the circpdlim5a function, we found that it inhibited the expression of proliferation and differentiation genes according to the over-expression experiment of circpdlim5a in myoblasts. We concluded that circpdlim5a may inhibit the proliferation and differentiation of myoblasts and thereby inhibit skeletal muscle development in Japanese flounder. This experiment provides information for the study of circRNAs by identifying circpdlim5a and exploring its function, and offers clues for molecular breeding from an epigenetic perspective. [ABSTRACT FROM AUTHOR]

Published

2024

41. Effects of Restricted Feeding on Growth Performance, Intestinal Immunity, and Skeletal Muscle Development in New Zealand Rabbits

Author

Junyi Zhuang, Tong Zhou, Shaocheng Bai, Bohao Zhao, Xinsheng Wu, and Yang Chen

Subjects

restricted feeding, New Zealand rabbits, growth performance, intestinal immunity, skeletal muscle development, PI3K/Akt signaling pathway, Veterinary medicine, SF600-1100, Zoology, QL1-991

Abstract

This study aimed to explore the effects of different feeding restriction levels on the growth performance, intestinal immunity, and skeletal muscle development of meat rabbits. Additionally, we studied whether complete compensatory growth could be obtained post 2 weeks of restricted feeding, in order to seek a scientific mode of feeding restriction. Each of three groups was exposed to 3 weeks of feeding restriction and 2 weeks of compensatory growth. The 15% feeding restriction showed a negligible effect on the final body-weight of the rabbits (p > 0.05), but significantly reduced the feed-to-weight ratio (p < 0.05); reduced diarrhea and mortality; and increased digestive enzyme activity and antioxidant capacity. However, a 30% feeding-restriction level substantially reduced the growth rate of the rabbits (p < 0.05), impaired skeletal muscle development, and showed no compensatory growth after 2 weeks of nutritional recovery. Additionally, immunoglobulin and antioxidant enzyme synthesis were impaired due to reduced nutritional levels, and levels of pro-inflammatory factors were increased during the compensation period. The IGF1 mRNA expression decreased significantly (p < 0.05), whereas MSTN and FOXO1 expression increased noticeably (p < 0.05). Moreover, protein levels of p-Akt and p-p70 decreased significantly in the 15% feeding restriction group. Overall, the 15% feeding limit unaffected the weight and skeletal muscle development of rabbits, whereas the 30% feeding limit affected the growth and development of skeletal muscle in growing rabbits. The PI3K/Akt signaling pathway is plausibly a mediator of this process.

Published

2022

42. Nutritional and pharmacological manipulations of myogenesis in the rat : a study of protein expression

Author

Downie, Diane

Subjects

573, Skeletal muscle development

Abstract

Although much work has been carried out to identify the mechanisms by which muscle is formed, many of the regulatory pathways involved have yet to be fully elucidated. In creating perturbations during the embryonic period, either nutritionally (with a marginal vitamin A deficiency model) or pharmacologically (with the b2-adrenerguic agonist clenbuterol), a comparison with 'normal' muscle development may be attained. Differences in the temporal expression of specific regulatory proteins may then enhance the existing knowledge of their function in regulating muscle development. Prior to studying changes in muscle regulatory proteins due to perturbations, it was first necessary to illustrate their temporal pattern in "normal" muscle development. The results indicated that a complex regulatory system operates in myogenesis with a number of proteins appearing to be involved in the process of muscle development. A marginal vitamin A deficiency model was established in which maternal retinol levels were clearly reduced in treatment animals in comparison with controls. This resulted in offspring that showed clearly symptoms of marginal vitamin A deficiency. Changes in the abundance of five proteins were observed in response to marginal vitamin A deficiency. Overall, these changes suggested a potential reduction in secondary myogenesis, based on reduced levels of MHCfast, associated with secondary fibres, following birth. Analysis of RNA, DNA and protein values suggested that neonates from clenbuterol fed dams may have reduced hyperplasia and/or increased hypertrophy. Biochemical analysis revealed that proteins such as GATA-2, PKC and Shh, which have previously been associated with hypertrophy, were altered in response to clenbuterol. Further evidence in support of hypertrophy was indicated in an apparent increase in fibre size of neonates detected by MHC immunolocalisation. In conclusion, it has been demonstrated that both nutritional and pharmacological manipulations throughout are gestation capable of altering myogeneiss in utero by two different mechanisms.

Published

2002

43. The genetic regulation of skeletal muscle development: insights from chicken studies

Author

Wen LUO, Bahareldin A. ABDALLA, Qinghua NIE, Xiquan ZHANG

Subjects

chicken, epigenetic modification, miRNAs, skeletal muscle development, SNP, transcription factor, Agriculture (General), S1-972

Abstract

Skeletal muscle development is a complex multi-process trait regulated by various genetic factors. The chicken embryo is an ideal model system for studying skeletal muscle development. However, only a small proportion of the genetic factors affecting skeletal muscle development have been identified in chicken. The aim of this review is to summarize recent knowledge about the genetic factors involved in the regulation of skeletal muscle development in the chicken, such as gene polymorphisms, epigenetic modification, noncoding RNAs and transcription factors, which can influence skeletal muscle development at the genome, epigenome, transcriptome and proteome levels. Research on the regulation of skeletal muscle development in chicken is not yet comprehensive and most of the candidate genes and single nucleotide polymorphisms related to chicken muscle growth remain to be verified in experimental studies. In addition, the data derived from transcriptome sequencing and genome-wide association studies still require further investigation and analysis and comprehensive studies on the regulation of chicken skeletal muscle development will continue as a major research focus.

Published

2017

44. Mechanism and Functions of Identified miRNAs in Poultry Skeletal Muscle Development – A Review.

Author

Collins, Asiamah Amponsah, Zou, Kun, Li, Zhang, and Ying, Su

Subjects

*MUSCLE growth, *SKELETAL muscle, *MICRORNA, *POULTRY, *REGULATOR genes, *POULTRY growth, *MYOBLASTS

Abstract

Development of the skeletal muscle goes through several complex processes regulated by numerous genetic factors. Although much efforts have been made to understand the mechanisms involved in increased muscle yield, little work is done about the miRNAs and candidate genes that are involved in the skeletal muscle development in poultry. Comprehensive research of candidate genes and single nucleotide related to poultry muscle growth is yet to be experimentally unraveled. However, over a few periods, studies in miRNA have disclosed that they actively participate in muscle formation, differentiation, and determination in poultry. Specifically, miR-1, miR-133, and miR-206 influence tissue development, and they are highly expressed in the skeletal muscles. Candidate genes such as CEBPB, MUSTN1, MSTN, IGF1, FOXO3, mTOR, and NFKB1, have also been identified to express in the poultry skeletal muscles development. However, further researches, analysis, and comprehensive studies should be made on the various miRNAs and gene regulatory factors that influence the skeletal muscle development in poultry. The objective of this review is to summarize recent knowledge in miRNAs and their mode of action as well as transcription and candidate genes identified to regulate poultry skeletal muscle development. [ABSTRACT FROM AUTHOR]

Published

2019

45. Effect of maternal feed restriction in dairy goats at different stages of gestation on skeletal muscle development and energy metabolism of kids at the time of births.

Author

Costa, Thaís C., Moura, Felipe H., Souza, Ranyeri O., Lopes, Mariana M., Fontes, Marta M.S., Serão, Nick V.L., Sanglard, Leticia P., Du, Min, Gionbelli, Mateus P., and Duarte, Marcio S.

Subjects

*BIRTH size, *GOATS, *MUSCLE growth, *SKELETAL muscle, *ENERGY metabolism, *ENERGY development

Abstract

The aim was to determine effects of maternal feed restriction in dairy goats at gestational different stages on skeletal muscle development and energy metabolism in kids at birth. Six pregnant goats were fed 50% of total digestible nutrients (TDN) and crude protein (CP) (NRC, 2007) recommendations in the first half of gestation and then fed to 100% of the recommendations in the second half of gestation (treatment R-M). In the other group, eight pregnant goats were fed 100% of TDN and CP in the first half of gestation and 50% of a restricted diet the second half of gestation (treatment M-R). Birth weight, blood glucose concentration, muscle fiber number, and size of kids at birth were not affected by maternal feed restriction. The mRNA and protein abundance of myogenic, adipogenic and fibrogenic markers were not affected (P > 0.05) by maternal diet. With regard to values for variables in kid energy metabolism, mRNA abundance of the glycolic enzyme HKII was less (P = 0.03) in the M-R group. In conclusion, maternal feed restriction in the first or second half of gestation had no affect mRNA abundance on myogenic, adipogenic, and fibrogenic markers nor were there changes in skeletal muscle mesenchymal stem cell population of kids at the time of birth. There, however, may be detrimental effects on energy metabolism by reducing HKII gene expression in skeletal muscle of dairy goat kids at the time of birth. [ABSTRACT FROM AUTHOR]

Published

2019

46. Prenatal Skeletal Muscle Transcriptome Analysis Reveals Novel MicroRNA-mRNA Networks Associated with Intrauterine Growth Restriction in Pigs

Author

Asghar Ali, Eduard Murani, Frieder Hadlich, Xuan Liu, Klaus Wimmers, and Siriluck Ponsuksili

Subjects

IUGR, fetal growth, miRNAs, skeletal muscle development, miR-210, Cytology, QH573-671

Abstract

Intrauterine growth restriction (IUGR) occurs in 15–20% of pig neonates and poses huge economic losses to the pig industry. IUGR piglets have reduced skeletal muscle growth, which may persist after birth. Prenatal muscle growth is regulated by complex molecular pathways that are not well understood. MicroRNAs (miRNAs) have emerged as the main regulators of vital pathways and biological processes in the body. This study was designed to identify miRNA–mRNA networks regulating prenatal skeletal muscle development in pigs. We performed an integrative miRNA–mRNA transcriptomic analysis in longissimus dorsi muscle from IUGR fetuses and appropriate for gestational age (AGA) fetuses at 63 days post conception. Our data showed that 47 miRNAs and 3257 mRNAs were significantly upregulated, and six miRNAs and 477 mRNAs were significantly downregulated in IUGR compared to AGA fetuses. Moreover, 47 upregulated miRNAs were negatively correlated and can potentially target 326 downregulated genes, whereas six downregulated miRNAs were negatively correlated and can potentially target 1291 upregulated genes. These miRNA–mRNA networks showed enrichment in biological processes and pathways critical for fetal growth, development, and metabolism. The miRNA–mRNA networks identified in this study can potentially serve as indicators of prenatal fetal growth and development as well as postnatal carcass quality.

Published

2021

47. Skeletal Muscle Development in Postnatal Beef Cattle Resulting from Maternal Protein Restriction during Mid-Gestation

Author

Thais Correia Costa, Min Du, Karolina Batista Nascimento, Matheus Castilho Galvão, Javier Andrés Moreno Meneses, Erica Beatriz Schultz, Mateus Pies Gionbelli, and Marcio de Souza Duarte

Subjects

beef cattle, dietary protein restriction, maternal effects, mid-gestation, skeletal muscle development, Veterinary medicine, SF600-1100, Zoology, QL1-991

Abstract

We aimed to investigate the effects of maternal protein restriction during mid-gestation on the skeletal muscle composition of the offspring. In the restriction treatment (RES, n = 9), cows were fed a basal diet, while in the control (CON, n = 9) group cows received the same RES diet plus the protein supplement during mid-gestation (100–200d). Samples of Longissimus dorsi muscle were collected from the offspring at 30d and 450d postnatal. Muscle fiber number was found to be decreased as a result of maternal protein restriction and persisted throughout the offspring’s life (p < 0.01). The collagen content was enhanced (p < 0.05) due to maternal protein restriction at 30d. MHC2X mRNA expression tended to be higher (p = 0.08) in RES 30d offspring, however, no difference (p > 0.05) was found among treatments at 450d. Taken together, our results suggest that maternal protein restriction during mid-gestation has major and persistent effects by reducing muscle fiber formation and may slightly increase collagen accumulation in the skeletal muscle of the offspring. Although maternal protein restriction may alter the muscle fiber metabolism by favoring the establishment of a predominant glycolytic metabolism, the postnatal environment may be a determinant factor that establishes the different proportion of muscle fiber types.

Published

2021

48. The DNA Methylation Status of Wnt and Tgfβ Signals Is a Key Factor on Functional Regulation of Skeletal Muscle Satellite Cell Development

Author

Weiya Zhang, Saixian Zhang, Yueyuan Xu, Yunlong Ma, Dingxiao Zhang, Xinyun Li, and Shuhong Zhao

Subjects

MeDIP-Seq, DNA methylation, Wnt, Tgfβ, satellite cells, skeletal muscle development, Genetics, QH426-470

Abstract

DNA methylation is an important form of epigenetic regulation that can regulate the expression of genes and the development of tissues. Muscle satellite cells play an important role in skeletal muscle development and regeneration. Therefore, the DNA methylation status of genes in satellite cells is important in the regulation of the development of skeletal muscle. This study systematically investigated the changes of genome-wide DNA methylation in satellite cells during skeletal muscle development. According to the MeDIP-Seq data, 52,809–123,317 peaks were obtained for each sample, covering 0.70–1.79% of the genome. The number of reads and peaks was highest in the intron regions followed by the CDS regions. A total of 96,609 DMRs were identified between any two time points. Among them 6198 DMRs were annotated into the gene promoter regions, corresponding to 4726 DMGs. By combining the MeDIP-Seq and RNA-Seq data, a total of 202 overlap genes were obtained between DMGs and DEGs. GO and Pathway analysis revealed that the overlap genes were mainly involved in 128 biological processes and 23 pathways. Among the biological processes, terms related to regulation of cell proliferation and Wnt signaling pathway were significantly different. Gene–gene interaction analysis showed that Wnt5a, Wnt9a, and Tgfβ1 were the key nodes in the network. Furthermore, the expression level of Wnt5a, Wnt9a, and Tgfβ1 genes could be influenced by the methylation status of promoter region during skeletal muscle development. These results indicated that the Wnt and Tgfβ signaling pathways may play an important role in functional regulation of satellite cells, and the DNA methylation status of Wnt and Tgfβ signals is a key regulatory factor during skeletal muscle development. This study provided new insights into the effects of genome-wide methylation on the function of satellite cells.

Published

2019

49. The DNA Methylation Status of Wnt and Tgfβ Signals Is a Key Factor on Functional Regulation of Skeletal Muscle Satellite Cell Development.

Author

Zhang, Weiya, Zhang, Saixian, Xu, Yueyuan, Ma, Yunlong, Zhang, Dingxiao, Li, Xinyun, and Zhao, Shuhong

Subjects

SATELLITE cells, DNA methylation, SKELETAL muscle, WNT signal transduction, MUSCLE cells, EPIGENOMICS

Abstract

DNA methylation is an important form of epigenetic regulation that can regulate the expression of genes and the development of tissues. Muscle satellite cells play an important role in skeletal muscle development and regeneration. Therefore, the DNA methylation status of genes in satellite cells is important in the regulation of the development of skeletal muscle. This study systematically investigated the changes of genome-wide DNA methylation in satellite cells during skeletal muscle development. According to the MeDIP-Seq data, 52,809–123,317 peaks were obtained for each sample, covering 0.70–1.79% of the genome. The number of reads and peaks was highest in the intron regions followed by the CDS regions. A total of 96,609 DMRs were identified between any two time points. Among them 6198 DMRs were annotated into the gene promoter regions, corresponding to 4726 DMGs. By combining the MeDIP-Seq and RNA-Seq data, a total of 202 overlap genes were obtained between DMGs and DEGs. GO and Pathway analysis revealed that the overlap genes were mainly involved in 128 biological processes and 23 pathways. Among the biological processes, terms related to regulation of cell proliferation and Wnt signaling pathway were significantly different. Gene–gene interaction analysis showed that Wnt5a , Wnt9a , and Tgf β 1 were the key nodes in the network. Furthermore, the expression level of Wnt5a , Wnt9a , and Tgf β 1 genes could be influenced by the methylation status of promoter region during skeletal muscle development. These results indicated that the Wnt and Tgfβ signaling pathways may play an important role in functional regulation of satellite cells, and the DNA methylation status of Wnt and Tgfβ signals is a key regulatory factor during skeletal muscle development. This study provided new insights into the effects of genome-wide methylation on the function of satellite cells. [ABSTRACT FROM AUTHOR]

Published

2019

50. Effect of thermal manipulation during embryogenesis on the promoter methylation and expression of myogenesis-related genes in duck skeletal muscle.

Author

Wang, Yushi, Yan, Xiping, Liu, Hehe, Hu, Shenqiang, Hu, Jiwei, Li, Liang, and Wang, Jiwen

Subjects

*EMBRYOLOGY, *METHYLATION, *MYOGENESIS, *GENE expression, *MUSCLE growth

Abstract

Abstract Avian embryos are an ideal system to investigate the effect of incubation temperature on embryonic development, but the characteristics and mechanisms of temperature effects on poultry embryonic myogenesis are unclear. In this study, we investigated the effect of increasing the incubation temperature by 1 °C on the expression of nine myogenesis-related genes in ducks and then explored the correlation between the alteration of promoter methylation and the expression of two of the nine genes under thermal manipulation (TM). The qRT-PCR results showed that TM during embryonic days (ED) 1–10 promoted (P < 0.05) the expression of genes in breast muscle (PAX3 , PAX7 , MYOG , MCK , SIX1 , TNNC1) and leg muscle (MYOD , MYOG , MYF5 , MCK , AKIRIN2 , TNNC1). TM during ED10-20 promoted the expression of PAX3 , MYF5 and MCK and inhibited AKIRIN2 expression in breast muscle (P < 0.05); however, it inhibited the expression of PAX3 , PAX7 , MYOD , MYOG , MYF5 , SIX1 , AKIRIN2 and TNNC1 and promoted MCK expression in leg muscle (P < 0.05). TM during ED20-27 inhibited the expression of genes in breast muscle (PAX7) and leg muscle (MYOD , MYOG , MYF5 , TNNC1) and promoted MCK expression in breast and leg muscle (P < 0.05). Furthermore, with the Sequenom MassARRAY platform, it was observed that the average methylation level of AKIRIN2 (ED10) and TNNC1 (ED20) in leg muscle decreased (P < 0.05) after TM. Notably, we found significant (P < 0.05) inverse correlations between the methylation and mRNA levels of AKIRIN2 under TM during ED1-10 (r = − 0.969) and ED10-20 (r = − 0.805). Taken together, TM during ED1-10 was more favorable for improving duck myogenesis-related gene expression than TM during ED10-20 and ED20-27. TM during duck embryogenesis seemed to have a greater effect on the development of leg muscle than breast muscle and might alter AKIRIN2 expression by changing its promoter methylation status. These findings may be helpful to understand temperature effects on the muscle development of avian embryos and to explore the role of epigenetic regulation during this process. Highlights • Thermal manipulation during duck embryogenesis had greater effects on the development of leg muscle than breast muscle. • Thermal manipulation during the early embryonic stage was beneficial for duck myogenesis-related gene expression. • Thermal manipulation during embryogenesis might regulate duck AKIRIN2 expression by changing its promoter methylation. [ABSTRACT FROM AUTHOR]

Published

2019