The purpose of this study was to clone and characterize the ZFP36L1 (zinc finger protein 36-like 1) gene, clarify its expression characteristics, and elucidate its expression patterns in different tissues of goats. Samples of 15 tissues from Jianzhou big-eared goats, including heart, liver, spleen, lung and kidney were collected. Goat ZFP36L1 gene was amplified by reverse transcription-polymerase chain reaction (RT-PCR), then the gene and protein sequence were analyzed by online tools. Quantitative real-time polymerase chain reaction (qPCR) was used to detect the expression level of ZFP36L1 in intramuscular preadipocytes in different tissues and adipocytes of goat at different differentiation stages. The results showed that the length of ZFR36L1 gene was 1 224 bp, and the coding sequence (CDS) region was 1 017 bp, encoding 338 amino acids, which was a non-secretory unstable protein mainly located in nucleus and cytoplasm. Tissue expression profile showed that ZFP36L1 gene was expressed in all selected tissues. In visceral tissues, the small intestine showed the highest expression level (P < 0.01). In muscle tissue, the highest expression level was presented in longissimus dorsi muscle (P < 0.01), whereas the expression level in subcutaneous adipose tissue was significantly higher than that in other tissues (P < 0.01). The results of induced differentiation showed that the expression of this gene was up-regulated during adipogenic differentiation of intramuscular precursor adipocytes (P < 0.01). These data may help to clarify the biological function of the ZFP36L1 gene in goat.
Animals ; Goats/genetics* ; Amino Acid Sequence ; Liver ; Cloning, Molecular

C-fos is a transcription factor that plays an important role in cell proliferation, differentiation and tumor formation. The aim of this study was to clone the goat c-fos gene, clarify its biological characteristics, and further reveal its regulatory role in the differentiation of goat subcutaneous adipocytes. We cloned the c-fos gene from subcutaneous adipose tissue of Jianzhou big-eared goats by reverse transcription-polymerase chain reaction (RT-PCR) and analyzed its biological characteristics. Using real-time quantitative PCR (qPCR), we detected the expression of c-fos gene in the heart, liver, spleen, lung, kidney, subcutaneous fat, longissimus dorsi and subcutaneous adipocytes of goat upon induced differentiation for 0 h to 120 h. The goat overexpression vector pEGFP-c-fos was constructed and transfected into the subcutaneous preadipocytes for induced differentiation. The morphological changes of lipid droplet accumulation were observed by oil red O staining and bodipy staining. Furthermore, qPCR was used to test the relative mRNA level of the c-fos overexpression on adipogenic differentiation marker genes. The results showed that the cloned goat c-fos gene was 1 477 bp in length, in which the coding sequence was 1 143 bp, encoding a protein of 380 amino acids. Protein structure analysis showed that goat FOS protein has a basic leucine zipper structure, and subcellular localization prediction suggested that it was mainly distributed in the nucleus. The relative expression level of c-fos was higher in the subcutaneous adipose tissue of goats (P < 0.05), and the expression level of c-fos was significantly increased upon induced differentiation of subcutaneous preadipocyte for 48 h (P < 0.01). Overexpression of c-fos significantly inhibited the lipid droplets formation in goat subcutaneous adipocytes, significantly decreased the relative expression levels of the AP2 and C/EBPβ lipogenic marker genes (P < 0.01). Moreover, AP2 and C/EBPβ promoter are predicted to have multiple binding sites. In conclusion, the results indicated that c-fos gene was a negative regulatory factor of subcutaneous adipocyte differentiation in goats, and it might regulate the expression of AP2 and C/EBPβ gene expression.
Animals ; Goats/genetics* ; Cell Differentiation/genetics* ; Adipogenesis/genetics* ; Gene Expression Regulation ; Proteins/genetics* ; Cloning, Molecular

The aim of this study was to clone the goat RPL29 gene and analyze its effect on lipogenesis in intramuscular adipocytes. Using Jianzhou big-eared goats as the object, the goat RPL29 gene was cloned by reverse transcription-polymerase chain reaction (RT-PCR), the gene structure and expressed protein sequence were analyzed by bioinformatics, and the mRNA expression levels of RPL29 in various tissues and different differentiation stages of intramuscular adipocytes of goats were detected by quantitative real-time PCR (qRT-PCR). The RPL29 overexpression vector pEGFP-N1-RPL29 constructed by gene recombination was used to transfect into goat intramuscular preadipocytes and induce differentiation. Subsequently, the effect of overexpression of RPL29 on fat droplet accumulation was revealed morphologically by oil red O and Bodipy staining, and changes in the expression levels of genes related to lipid metabolism were detected by qRT-PCR. The results showed that the length of the goat RPL29 was 507 bp, including a coding sequence (CDS) region of 471 bp which encodes 156 amino acid residues. It is a positively charged and stable hydrophilic protein mainly distributed in the nucleus of cells. Tissue expression profiling showed that the expression level of this gene was much higher in subcutaneous adipose tissue and inter-abdominal adipose tissue of goats than in other tissues (P < 0.05). The temporal expression profile showed that the gene was expressed at the highest level at 84 h of differentiation in goat intramuscular adipocytes, which was highly significantly higher than that in the undifferentiated period (P < 0.01). Overexpression of RPL29 promoted lipid accumulation in intramuscular adipocytes, and the optical density values of oil red O staining were significantly increased (P < 0.05). In addition, overexpression of RPL29 was followed by a highly significant increase in ATGL and ACC gene expression (P < 0.01) and a significant increase in FASN gene expression (P < 0.05). In conclusion, the goat RPL29 may promote intra-muscular adipocyte deposition in goats by up-regulating FASN, ACC and ATGL.
Animals ; Lipogenesis/genetics* ; Adipogenesis/genetics* ; Goats/genetics* ; Adipocytes ; Cell Differentiation/genetics* ; Sequence Analysis ; Cloning, Molecular

Fluorescence PCR was applied to investigate the genetic diversities of 9 indigenous Chinese goat breeds and 1 exotic breed with 10 microsatellite DNA markers recommended by the Food and Agriculture Organization of the United Nations and the International Livestock Research Institute of Animal Genetics, which provide data for the preservation and utilization of indigenous goat breeds genetic resource. We found that the 7 breeds were high polymorphic while 3 breeds were moderate polymorphic. We also detected 119 alleles, and the effective allele number ranged from 1.4641 to 9.2911. The average heterozygosity of loci and breeds respectively varied from 0.2618 to 0.7672 and from 0.5196 to 0.7024. As well as SRCRSP23 site and Hexi cashmere goat had the highest average heterozygosity. Then we analyzed the phylogenetic trees (NJ and UPGMA), and found both of them were generally in accordance with their original breeding history and localities.
Alleles ; Animals ; Breeding ; DNA ; genetics ; Genetic Variation ; Goats ; classification ; genetics ; Heterozygote ; Microsatellite Repeats ; genetics ; Polymorphism, Genetic

This study aimed to explore the effect of miR-23b-3p on the differentiation of goat intramuscular preadipocytes, and to confirm whether miR-23b-3p plays its roles via targeting the PDE4B gene. Based on the pre-transcriptome sequencing data obtained previously, the miR-23b-3p, which was differentially expressed in goat intramuscular adipocytes before and after differentiation, was used as an entry point. real-time quantitative-polymerase chain reaction (qPCR) was used to detect the expression pattern of miR-23b-3p during the differentiation of goat intramuscular preadipocytes. The effects of miR-23b-3p on adipose differentiation and adipose differentiation marker genes were determined at the morphological and molecular levels. The downstream target genes of miR-23b-3p were determined using bioinformatics prediction as well as dual luciferase reporter assay to clarify the targeting relationship between miR-23b-3p and the predicted target genes. The results indicated that overexpression of miR-23b-3p reduced lipid droplet accumulation in goat intramuscular adipocytes, significantly down-regulated the expression levels of adipogenic marker genes AP2, C/EBPα, FASN, and LPL (P < 0.01). In addition, the expressions of C/EBPβ, DGAT2, GLUT4 and PPARγ were significantly downregulated (P < 0.05). After interfering with the expression of miR-23b-3p, lipid droplet accumulation was increased in goat intramuscular adipocytes. The expression levels of ACC, ATGL, AP2, DGAT2, GLUT4, FASN and SREBP1 were extremely significantly up-regulated (P < 0.01), and the expression levels of C/EBPβ, LPL and PPARγ were significantly up-regulated (P < 0.05). It was predicted that PDE4B might be a target gene of miR-23b-3p. The mRNA expression level of PDE4B was significantly decreased after overexpression of miR-23b-3p (P < 0.01), and the interference with miR-23b-3p significantly increased the mRNA level of PDE4B (P < 0.05). The dual luciferase reporter assay indicated that miR-23b-3p had a targeting relationship with PDE4B gene. MiR-23b-3p regulates the differentiation of goat intramuscular preadipocytes by targeting the PDE4B gene.
Animals ; MicroRNAs/metabolism* ; Goats/genetics* ; PPAR gamma/metabolism* ; Adipogenesis/genetics* ; Cell Differentiation/genetics* ; Luciferases ; RNA, Messenger

In this study, we cloned the complete sequence coding for aminoacids in protein (CDS) of goat ST13 gene, analyzed the bioinformation of it, and explored the expression pattern in different goat tissues and goat subcutaneous preadipocytes at different differentiation stages. To be specific, ST13 gene was cloned by reverse transcription PCR (RT-PCR), and the bioinformation was analyzed by online tools or software. The expression in various goat tissues and subcutaneous preadipocytes at different differentiation stages was detected by quantitative reverse transcription PCR (qRT-PCR). The results showed that the cloned goat ST13 gene was 1 380 bp, with CDS of 1 101 bp, encoding 366 amino acids. Protein prediction results showed that ST13 had 26 phosphorylation sites and that some sequences were highly hydrophilic and unstable. Moreover, ST13 was a non-transmembrane and non-secretory protein. Subcellular localization demonstrated that ST13 was mostly distributed in the nucleus (69.6%). Phylogeny analysis suggested that goat ST13 had the highest identity to sheep ST13. Tissue expression pattern showed that ST13 gene expressed in all of the collected 13 tissues of goat, including heart, liver, spleen, lung and kidney, especially in triceps brachii and subcutaneous fat (P < 0.01) and that the expression among heart, liver, spleen, lung, kidney, large intestine, small intestine and pancreas was insignificantly different (P > 0.05). In addition, according to the temporal expression pattern in adipocytes, the expression of ST13 was up-regulated in differentiated adipocytes, and the expression was the highest at the 108th hour of induction, significantly higher than that at other time points (P < 0.01). In conclusion, this gene expresses in various tissues of goat and regulates the differentiation of goat subcutaneous adipocytes.
Adipocytes ; Animals ; Cloning, Molecular ; Goats/genetics* ; Liver ; Phylogeny ; Real-Time Polymerase Chain Reaction ; Sheep

The Cashmere goat is mainly used to produce cashmere, which is very popular for its delicate fiber, luscious softness and natural excellent warm property. Keratin associated protein (KAP) and bone morphogenetic protein (BMP) of the Cashmere goat play an important role in the proliferation and development of cashmere fiber follicle cells. Bacterial artificial chromosome containing kap6.3, kap8.1 and bmp4 genes were used to increase the production and quality of Cashmere. First, we constructed bacterial artificial chromosomes by homology recombination. Then Tol2 transposon was inserted into bacterial artificial chromosomes that were then transfected into Cashmere goat fibroblasts by Amaxa Nucleofector technology according to the manufacture's instructions. We successfully constructed the BAC-Tol2 vectors containing target genes. Each vector contained egfp report gene with UBC promoter, Neomycin resistant gene for cell screening and two loxp elements for resistance removing after transfected into cells. The bacterial artificial chromosome-Tol2 vectors showed a high efficiency of transfection that can reach 1% to 6% with a highest efficiency of 10%. We also obtained Cashmere goat fibroblasts integrated exogenous genes (kap6.3, kap8.1 and bmp4) preparing for the clone of Cashmere goat in the future. Our research demonstrates that the insertion of Tol2 transposons into bacterial artificial chromosomes improves the transfection efficiency and accuracy of bacterial artificial chromosome error-free recombination.
Animals ; Bone Morphogenetic Proteins ; genetics ; Chromosomes, Artificial, Bacterial ; DNA Transposable Elements ; Fibroblasts ; Goats ; genetics ; Keratins ; genetics ; Transfection

The study of mammary gland bioreactor is in the ascendant. In order to generate transgenic goats of well-controlled expression of exogenic genes, we constructed a human lactoferrin (hLF) gene targeting vector containing promoter, exon 1, intron1 and some of exon 2 (about 6.1 kb fragment) and exon 6 approximately 9 (about 3.3 kb fragment) of the goat beta-casein gene as well as hLF minigene, neo gene inserted into them and tk gene ligated to the 3' end of the construct. The 9.4 kb goat genomic sequences as homologous arms were initially amplified by PCR with local goat tissue DNA. The expression vector was named pBC-tk-neo-hlf. Then the recombinant plasmid pBC-tk-neo-hlf containing hLF minigene was transfected into mice mammary tumor cell line C127 by liposome, cell clones were selected with G418. After proliferating, the transfected cells were induced with insulin, luteotropic hormone and hydrocortisone. The result of Western-blotting analysis showed that the transfected cells can secrete hLF protein, and the recombinant protein expressed in cultured cell supernatant has the similar molecular weight as the native protein. The expression level detected by ELISA was 0.21 microg/mL. This result indicated that the targeting vector could efficiently direct the expression of hLF in mammary cells,and it confirmed the validity of the constructed vector. At the same time, C127 cell line proved to be useful for evaluating the regulation of a foreign gene expression in mammary gland specific expression vector.
Animals ; Caseins ; genetics ; Cell Line, Tumor ; Goats ; Humans ; Lactoferrin ; genetics ; Mammary Glands, Animal ; cytology ; metabolism ; Mice ; Molecular Weight ; Transfection

To make a universal gene targeting vector fitting for most gene and delete positive selection gene after targeting successfully, a vector named pA2T was constructed by inserting one neomycin gene (neo) for positive selection and two same herpes simplex virus thymidine kinase gene HSV-tk1 and HSV-tk2 for negative selection into the vector of pGEM-3Z, and two locus of crossing-over (x) in P1 (LoxP) and two different multiple cloning sites (MCS) were inserted into two flanks of neo separately. There were eight rare cloning sites between neo and HSV-tk1 and five rare cloning sites between neo and HSV-tk2, and neo, HSV-tk1 and HSV-tk2 could be translated respectively in the pA2T. Transfection of the pA2T into goat fetus fibroblast cells with Lipofectamine 2000 conferred resistance to geneticin (G418) and resistance to ganciclovir (GAC) in the cells, which suggested the positive and negative selectable markers could express in the cells and thus the vector pA2T could be used as a universal gene targeting vector. Transformation of the pA2T into the BM25.8 expressing Cre recombinase conferred neo was deleted in the pA2T, which suggested the LoxP was active. Thus, this vector can be inserted by most gene sequences as homologous sequences and positive selection gene can be deleted after targeting successfully, which is very convenience for the production of transgenic animals using gene targeting method.
Animals ; Animals, Genetically Modified ; genetics ; Cloning, Molecular ; Ganciclovir ; pharmacology ; Gene Targeting ; methods ; Genetic Vectors ; genetics ; Gentamicins ; pharmacology ; Goats ; Integrases ; genetics ; Neomycin ; pharmacology ; Phosphotransferases ; genetics ; metabolism

To knock out β-lactoglobulin (BLG) gene and insert human lactoferrin (hLF) coding sequence at BLG locus of goat, the transcription activator-like effector nucleases (TALEN) mediated recombination was used to edit the BLG gene of goat fetal fibroblast, then as donor cells for somatic cell nuclear transfer. We designed a pair of specific plasmid TALEN-3-L/R for goat BLG exon III recognition sites, and BLC14-TK vector containing a negative selection gene HSV-TK, was used for the knock in of hLF gene. TALENs plasmids were transfected into the goat fetal fibroblast cells, and the cells were screened three days by 2 μg/mL puromycin. DNA cleavage activities of cells were verified by PCR amplification and DNA production sequencing. Then, targeting vector BLC14-TK and plasmids TALEN-3-L/R were co-transfected into goat fetal fibroblasts, both 700 μg/mL G418 and 2 μg/mL GCV were simultaneously used to screen G418-resistant cells. Detections of integration and recombination were implemented to obtain cells with hLF gene site-specific integration. We chose targeting cells as donor cells for somatic cell nuclear transfer. The mutagenicity of TALEN-3-L/R was between 25% and 30%. A total of 335 reconstructed embryos with 6 BLG-/hLF+ targeting cell lines were transferred into 16 recipient goats. There were 9 pregnancies confirmed by ultrasound on day 30 to 35 (pregnancy rate of 39.1%), and one of 50-day-old fetus with BLG-/hLF+ was achieved. These results provide the basis for hLF gene knock-in at BLG locus of goat and cultivating transgenic goat of low allergens and rich hLF in the milk.
Animals ; Animals, Genetically Modified ; genetics ; Female ; Fibroblasts ; Gene Knock-In Techniques ; Gene Knockout Techniques ; Goats ; genetics ; Humans ; Lactoferrin ; genetics ; Lactoglobulins ; genetics ; Milk ; chemistry ; Nuclear Transfer Techniques ; Plasmids ; Pregnancy ; Transfection