Effect of Co-transfection of Anti-myostatin shRNA Constructs in Caprine Fetal Fibroblast Cells

Knockdown of myostatin gene (MSTN), transforming growth factor-β superfamily, and a negative regulator of the skeletal muscle growth, by RNA interference (RNAi), has been reported to increase muscle mass in mammals. The current study was aimed to cotransfect two anti-MSTN short hairpin RNA (shRNA) constructs in caprine fetal fibroblast cells for transient silencing of MSTN gene. In the present investigation, approximately 89% MSTN silencing was achieved in transiently transfected caprine fetal fibroblast cells by cotransfection of two best out of four anti-MSTN shRNA constructs. Simultaneously, we also monitored the induction of IFN responsive genes (IFN), pro-apoptotic gene (caspase3) and anti-apoptotic gene (MCL-1) due to cotransfection of different anti-MSTN shRNA constructs. We observed induction of 0.66-19.12, 1.04-4.14, 0.50-3.43, and 0.42-1.98 for folds IFN-β, OAS1, caspase3, and MCL-1 genes, respectively (p < 0.05). This RNAi based cotransfection method could provide an alternative strategy of gene knockout and develop stable caprine fetal fibroblast cells. Furthermore, these stable cells can be used as a cell donor for the development of transgenic cloned embryos by somatic cell nuclear transfer (SCNT) technique.     

MicroRNA-Mediated Myostatin Silencing in Caprine Fetal Fibroblasts

Myostatin functions as a negative regulator of skeletal muscle growth by suppressing proliferation and differentiation of myoblasts. Dysfunction of the myostatin gene, either due to natural mutation or genetic manipulations such as knockout or knockdown, has been reported to increase muscle mass in mammalian species. RNA interference (RNAi) mediated by microRNAs (miRNAs) is a promising method for gene knockdown studies. In the present study, transient and stable silencing of the myostatin gene in caprine fetal fibroblasts (CFF) was evaluated using the two most effective constructs selected from four different miRNA expression constructs screened in 293FT cells. Using these two miRNA constructs, we achieved up to 84% silencing of myostatin mRNA in transiently transfected CFF cells and up to 31% silencing in stably transfected CFF cells. Moreover, off-target effects due to induction of interferon (IFN) response genes, such as interferon beta (IFN-β) and 2′-5′-oligoadenylate synthetase 2 (OAS2), were markedly fewer in stably transfected CFF cells than in transiently transfected cells. Stable expression of anti-myostatin miRNA with minimal induction of interferon shows great promise for increasing muscle mass in transgenic goats.     

Stable suppression of myostatin gene expression in goat fetal fibroblast cells by lentiviral vector‐mediated RNAi

Myostatin (MSTN) is a secreted growth factor that negatively regulates skeletal muscle mass, and therefore, strategies to block myostatin‐signaling pathway have been extensively pursued to increase the muscle mass in livestock. Here, we report a lentiviral vector‐based delivery of shRNA to disrupt myostatin expression into goat fetal fibroblasts (GFFs) that were commonly used as karyoplast donors in somatic‐cell nuclear transfer (SCNT) studies. Sh‐RNA positive cells were screened by puromycin selection. Using real‐time polymerase chain reaction (PCR), we demonstrated efficient knockdown of endogenous myostatin mRNA with 64% down‐regulation in sh2 shRNA‐treated GFF cells compared to GFF cells treated by control lentivirus without shRNA. Moreover, we have also demonstrated both the induction of interferon response and the expression of genes regulating myogenesis in GFF cells. The results indicate that myostatin‐targeting siRNA produced endogenously could efficiently down‐regulate myostatin expression. Therefore, targeted knockdown of the MSTN gene using lentivirus‐mediated shRNA transgenics would facilitate customized cell engineering, allowing potential use in the establishment of stable cell lines to produce genetically engineered animals. © 2014 American Institute of Chemical Engineers Biotechnol. Prog., 31:452–459, 2015     

Evaluation of Interferon Response Induced by Anti-Myostatin shRNA Constructs in Goat (Capra hircus) Fetal Fibroblasts by Quantitative Real TIME-Polymerase Chain Reaction

RNAi is an evolutionary conserved, highly efficient, and cost effective technique of gene silencing. It holds considerable promise and success has been achieved both in vitro and in vivo experiments. However, it is not devoid of undesirable side effects as dsRNA can trigger the immune response and can also cause non-specific off-target gene silencing. In the present study, silencing of myostatin gene, a negative regulator of myogenesis, was evaluated in caprine fetal fibroblasts using three different shRNA constructs. Out of these three constructs, two constructs sh1 and sh2 showed, 72% and 50% reduction (p?相似文献   

Evaluation of Interferon Response Induced by Anti-Myostatin shRNA Constructs in Goat (Capra hircus) Fetal Fibroblasts by Quantitative Real TIME-Polymerase Chain Reaction

RNAi is an evolutionary conserved, highly efficient, and cost effective technique of gene silencing. It holds considerable promise and success has been achieved both in vitro and in vivo experiments. However, it is not devoid of undesirable side effects as dsRNA can trigger the immune response and can also cause non-specific off-target gene silencing. In the present study, silencing of myostatin gene, a negative regulator of myogenesis, was evaluated in caprine fetal fibroblasts using three different shRNA constructs. Out of these three constructs, two constructs sh1 and sh2 showed, 72% and 50% reduction (p < 0.05) of myostatin mRNA, respectively. Efficient suppression (42–86%) of MSTN gene (p < 0.05) was achieved even by reducing the concentration of shRNA constructs. The induction of classical interferon stimulated gene (Oligoandenylate Synthetase-1, OAS-1) was studied to analyze the immune response against shRNAs. Notably, a reduction in the potency of shRNAs to induce interferon response was observed at lower concentration for OAS1 gene. The results obtained in the study would be helpful in the abrogation of the bystander effects of RNAi for long term stable expression of anti-MSTN expression constructs in the muscle.     

The critical role of myostatin in differentiation of sheep myoblasts

Myostatin [MSTN, also known as growth differentiation factor 8 (GDF8)], is an inhibitor of skeletal muscle growth. Blockade of MSTN function has been reported to result in increased muscle mass in mice. However, its role in myoblast differentiation in farm animals has not been determined. In the present study, we sought to determine the role of MSTN in the differentiation of primary sheep myoblasts. We found that ectopic overexpression of MSTN resulted in lower fusion index in sheep myoblasts, which indicated the repression of myoblast differentiation. This phenotypic change was reversed by shRNA knockdown of the ectopically expressed MSTN in the cells. In contrast, shRNA knockdown of the endogenous MSTN resulted in induction of myogenic differentiation. Additional studies revealed that the induction of differentiation by knocking down the ectopically or endogenously expressed MSTN was accompanied by up-regulation of MyoD and myogenin, and down-regulation of Smad3. Our results demonstrate that MSTN plays critical role in myoblast differentiation in sheep, analogous to that in mice. This study also suggests that shRNA knockdown of MSTN could be a potentially promising approach to improve sheep muscle growth, so as to increase meat productivity.     

Myostatin knockdown and its effect on myogenic gene expression program in stably transfected goat myoblasts

Myostatin, a negative regulator of skeletal muscle mass, is a proven candidate to modulate skeletal muscle mass through targeted gene knockdown approach. Here, we report myostatin (MSTN) knockdown in goat myoblasts stably expressing small hairpin RNA (shRNAs) against MSTN gene through lentivirus vector-mediated integration. We observed 72% (p?=?0.003) and 54% (p?=?0.022) downregulation of MSTN expression with sh2 shRNA compared to empty vector control and untransduced myoblasts, respectively. The knockdown of MSTN expression was accompanied with concomitant downregulation of myogenic regulatory factor MYOD (77%, p?=?0.001), MYOG (94%, p?=?0.000), and MYF5 (36%, p?=?0.000), cell cycle regulator p21 (62%, p?=?0.000), MSTN receptor ACVR2B (23%, p?=?0.061), MSTN antagonist follistatin (81%, p?=?0.000), and downstream signaling mediators SMAD2 (20%, p?=?0.060) and SMAD3 (49%, p?=?0.006). However, the expression of MYF6 was upregulated by 14% compared to control lentivirus-transduced myoblasts (p?=?0.354) and 79% compared to untransduced myoblasts (p?=?0.018) in sh2 shRNA-transduced goat myoblasts cells. Although, MSTN knockdown led to sustained cell proliferation of myoblasts, the myoblasts fusion was suppressed in both MSTN knocked down and control lentivirus-transduced myoblasts. The expression of interferon response gene OAS1 was significantly upregulated in control lentivirus (10.86-fold; p?=?0.000)- and sh2 (1.71-fold; p?=?0.002)-integrated myoblasts compared to untransduced myoblasts. Our study demonstrates stable knockdown of MSTN in goat myoblasts cells and its potential for use in generation of transgenic goat by somatic cell nuclear transfer.     

Knockdown of endogenous myostatin promotes sheep myoblast proliferation

Myostatin (MSTN), is a known negative regulator of myogenesis. Silencing of the function of MSTN could result in increasing muscle mass in mice. To determine the function of endogenous MSTN expression on proliferation of sheep myoblasts, a short-hairpin RNA-targeting sheep MSTN was constructed into lentiviral vector to silence endogenous MSTN expression. We demonstrated that silencing of endogenous MSTN gene with up to approximately 73.3% reduction by short hairpin RNA (shRNA) resulted in significant increase (overall 28.3%) of proliferation of primary ovine myoblasts. The upregulation of proliferation was accompanied by the decrease expression of MyoD (?37.6%, p?=?0.025), myogenin (?33.1%, p?=?0.049), p21 (?49.3%, p?=?0.046), and Smad3 (?50.0%, p?=?0.007). Silencing of myostatin using shRNA may provide a feasible approach to improve meat productivity in farm animals.     

Conditional RNAi in mice

RNA interference (RNAi)-mediated gene knockdown has developed into a routine method to assess gene function in cultured mammalian cells in a fast and easy manner. For the use of RNAi in mice, short hairpin (sh) RNAs expressed stably from the genome are a fast alternative to conventional knockout approaches. We developed a strategy for complete or conditional gene knockdown in mice, where the Cre/loxP system is used to activate RNAi in a time and tissue dependent manner. Alternatively doxycycline controlled shRNA expression vectors can be used for conditional gene silencing. Single copy RNAi constructs are placed into the Rosa26 locus of ES cells by recombinase mediated cassette exchange and transmitted through the germline of chimeric mice. The shRNA transgenic offspring can be either directly used for phenotypic analysis or are further crossed to a Cre transgenic strain to activate conditional shRNA vectors. The site specific insertion of single copy shRNA vectors allows the expedite and reproducible production of knockdown mice and provides an easy and fast approach to assess gene function in vivo.     

Assessment of goat activin receptor type IIB knockdown by short hairpin RNAs in vitro

Abstract

Background: Targeted knockdown of ACVR2B, a receptor for TGF beta superfamily, has been seen as a potential candidate to enhance the muscle mass through RNAi approach. Methods: We have evaluated the potential short hairpin RNAs targeting goat ACVR2B in human HEK293T cells and goat myoblasts cells by transient transfection and measured their knockdown efficiency and possible undesired interferon response by quantitative real-time PCR. Results: We observed a significant silencing (64–81%) of ACVR2B in 293T cells with all seven shRNAs (sh1 to sh7) constructs and 16–46% silencing with maximum of 46% by sh6 (p?=?0.0318) against endogenous ACVR2B whereas up to 66% (p?=?0.0002) silencing by sh6 against exogenously expressed ACVR2B in goat myoblasts cells. Transient knockdown of ACVR2B in goat myoblasts cells by shRNAs did not show significant correlation with the expression of MyoD (r?=?0.547; p?=?0.102), myogenin (r?=?0.517; p?=?0.126) and Myf5 (r?=?0.262; p?=?0.465). As reported earlier, transfection of plasmid DNA induced potent interferon response in 293T and goat myoblasts cells. Conclusions: The present study demonstrates the targeted knockdown of ACVR2B by shRNAs in HEK293T and goat myoblasts cells in vitro. The transient knockdown of ACVR2B by shRNAs in goat myoblasts did not alter the myogenic gene expression program. However, shRNAs showing significant knockdown efficiency in our study may further be tested for long term and stable knockdown to assess their potential to use for enhancing muscle mass in vivo. As reported earlier, expression of shRNAs through plasmid expression vectors induces potent interferon response raising the concern of safety of its application in vivo.     

Production of transgenic calves expressing an shRNA targeting myostatin

Myostatin (MSTN) is a well-known negative regulator of muscle growth. Animals that possess mutations within this gene display an enhanced muscling phenotype, a desirable agricultural trait. Increased neonatal morbidity is common, however, resulting from complications arising from the birth of offspring with increased fetal muscle mass. The objective of the current research was to generate an attenuated MSTN-null phenotype in a large-animal model using RNA interference to enhance muscle development without the detrimental consequences of an inactivating mutation. To this end, we identified a series of short interfering RNAs that demonstrated effective suppression of MSTN mRNA and protein levels. To produce transgenic offspring capable of stable MSTN suppression in vivo, a recombinant lentiviral vector expressing a short hairpin RNA (shRNA) targeting MSTN for silencing was introduced into bovine fetal fibroblasts. These cells were used as nucleus donors for somatic cell nuclear transfer (SCNT). Twenty blastocysts were transferred into seven recipient cows resulting in five pregnancies. One transgenic calf developed to term, but died following delivery by Caesarean-section. As an alternative strategy, microinjection of recombinant lentiviral particles into the perivitelline space of in vitro-produced bovine zygotes was utilized to produce 40 transgenic blastocysts that were transferred into 14 recipient cows, resulting in 7 pregnancies. Five transgenic calves were produced, of which three expressed the transgene. This is the first report of transgenic livestock produced by direct injection of a recombinant lentivirus, and expressing transgenes encoding shRNAs targeting an endogenous gene (myostatin) for silencing.     

Sleeping Beauty-mediated knockdown of sheep myostatin by RNA interference

Myostatin is a negative regulator of skeletal muscle growth. Myostatin dysfunction therefore offers a strategy for promoting animal muscle growth in livestock production. Knockdown of myostatin was achieved by combining RNA interference and the Sleeping Beauty (SB) transposon system in sheep cells. Four targeting sites of sheep myostatin were designed and measured for myostatin silencing in sheep fetal fibroblasts by real-time PCR. The sh3 construct induced significant decrease of myostatin gene expression by 90% (P < 0.05). Myostatin silencing induced by SB-mediated sh3 was further tested in stably transfected cells. SB transposition increased the integration frequency of genes into sheep genomes and mediated a more efficient myostatin knockdown than random integration of sh3. We suggest that SB-mediated shRNA provides a novel potential tool for gene knockdown in the donor cells of animal cloning.     

Myostatin short interfering hairpin RNA gene transfer increases skeletal muscle mass

BACKGROUND: Myostatin negatively regulates skeletal muscle growth. Myostatin knockout mice exhibit muscle hypertrophy and decreased interstitial fibrosis. We investigated whether a plasmid expressing a short hairpin interfering RNA (shRNA) against myostatin and transduced using electroporation would increase local skeletal muscle mass. METHODS: Short interfering RNAs (siRNAs) targeting myostatin were co-transfected with a myostatin-expressing plasmid into HEK293 cells and identified for myostatin silencing by Western blot. Corresponding shRNAs were cloned into plasmid shRNA expression vectors. Myostatin or a randomer negative control shRNA plasmid was injected and electroporated into the tibialis anterior or its contralateral muscle, respectively, of nine rats that were sacrificed after 2 weeks. Six other rats received a beta-galactosidase reporter plasmid and were sacrificed at 1, 2, and 4 weeks. Uptake of plasmid was examined by beta-galactosidase expression, whereas myostatin expression was determined by real-time polymerase chain reaction (PCR) and Western blotting. Muscle fiber size was determined by histochemistry. Satellite cell proliferation was determined by PAX7 immunohistochemistry. Myosin heavy chain type II (MHCII) expression was determined by Western blot. RESULTS: beta-Galactosidase reporter plasmid was expressed at 1 and 2 weeks but diminished by 4 weeks in tibialis anterior skeletal muscle. Myostatin shRNA reduced myostatin mRNA and protein expression by 27 and 48%, respectively. Tibialis anterior weight, fiber size, and MHCII increased by 10, 34, and 38%, respectively. Satellite cell number was increased by over 2-fold. CONCLUSIONS: This is the first demonstration that myostatin shRNA gene transfer is a potential strategy to increase muscle mass.     

Pol II-expressed shRNA knocks down Sod2 gene expression and causes phenotypes of the gene knockout in mice

RNA interference (RNAi) has been used increasingly for reverse genetics in invertebrates and mammalian cells, and has the potential to become an alternative to gene knockout technology in mammals. Thus far, only RNA polymerase III (Pol III)-expressed short hairpin RNA (shRNA) has been used to make shRNA-expressing transgenic mice. However, widespread knockdown and induction of phenotypes of gene knockout in postnatal mice have not been demonstrated. Previous studies have shown that Pol II synthesizes micro RNAs (miRNAs)-the endogenous shRNAs that carry out gene silencing function. To achieve efficient gene knockdown in mammals and to generate phenotypes of gene knockout, we designed a construct in which a Pol II (ubiquitin C) promoter drove the expression of an shRNA with a structure that mimics human miRNA miR-30a. Two transgenic lines showed widespread and sustained shRNA expression, and efficient knockdown of the target gene Sod2. These mice were viable but with phenotypes of SOD2 deficiency. Bigenic heterozygous mice generated by crossing these two lines showed nearly undetectable target gene expression and phenotypes consistent with the target gene knockout, including slow growth, fatty liver, dilated cardiomyopathy, and premature death. This approach opens the door of RNAi to a wide array of well-established Pol II transgenic strategies and offers a technically simpler, cheaper, and quicker alternative to gene knockout by homologous recombination for reverse genetics in mice and other mammalian species.     

猪Nanog基因四环素诱导干扰载体的构建和鉴定

Nanog基因是在早期胚胎和干细胞等多能性细胞中特异表达的重要基因,但有关猪Nanog基因功能的相关研究甚少。四环素诱导干扰载体是一种可通过四环素等药物条件性诱导干扰目的基因的载体,尤其适用于在发育过程中起着关键作用的基因沉默。常规的四环素干扰系统为二元载体,与一元载体相比获得针对特定基因干扰的稳定细胞系所需周期更长。首先通过构建pGenesil 1.0-shRNA重组干扰载体,瞬时转染稳定过表达猪Nanog基因的猪胎儿成纤维细胞后通过Realtime-PCR筛选出干扰效率可达80%以上的干扰片段。之后将筛选得到的干扰片段插入到改造的一元四环素诱导干扰载体TREsilencer,对稳定表达猪Nanog基因的猪胎儿成纤维细胞进行了瞬时转染。实验分别通过光密度检测以及Realtime-PCR检测了不同浓度doxycycline的诱导效率和干扰效率。结果表明,所构建的四环素诱导干扰载体TREsilencer-shRNA5随着四环素浓度的增加,诱导Nanog基因的干扰效率增加,在处理浓度为1μg/ml时干扰效率可达70%以上,为后续得到可诱导的稳定干扰猪Nanog基因的细胞系和进一步研究猪Nanog基因功能奠定了基础。     

Knockdown of Myostatin Expression by RNAi Enhances Muscle Growth in Transgenic Sheep

Myostatin (MSTN) has been shown to be a negative regulator of skeletal muscle development and growth. MSTN dysfunction therefore offers a strategy for promoting animal growth performance in livestock production. In this study, we investigated the possibility of using RNAi-based technology to generate transgenic sheep with a double-muscle phenotype. A shRNA expression cassette targeting sheep MSTN was used to generate stable shRNA-expressing fibroblast clones. Transgenic sheep were further produced by somatic cell nuclear transfer (SCNT) technology. Five lambs developed to term and three live lambs were obtained. Integration of shRNA expression cassette in three live lambs was confirmed by PCR. RNase protection assay showed that the shRNAs targeting MSTN were expressed in muscle tissues of three transgenic sheep. MSTN expression was significantly inhibited in muscle tissues of transgenic sheep when compared with control sheep. Moreover, transgenic sheep showed a tendency to faster increase in body weight than control sheep. Histological analysis showed that myofiber diameter of transgenic sheep M17 were bigger than that of control sheep. Our findings demonstrate a promising approach to promoting muscle growth in livestock production.