In order to develop a transgenic zebrafish line with green fluorescent protein (enhanced green fluorescent protein, EGFP) expressed specifically in muscle and heart, the recombinant expression vector constructed using the zebrafish ttn.2 gene promoter fragment and EGFP gene coding sequence and the capped mRNA of Tol2 transposase were co-injected into the zebrafish 1-cell stage embryos. The stable genetic Tg (ttn.2: EGFP) transgenic zebrafish line was successfully developed by fluorescence detection, followed by genetic hybridization screening and molecular identification. Fluorescence signals and whole-mount in situ hybridization showed that EGFP expression was located in muscle and heart, the specificity of which was consistent with the expression of ttn.2 mRNA. Inverse PCR showed that EGFP was integrated into chromosomes 4 and 11 of zebrafish in No. 33 transgenic line, while integrated into chromosome 1 in No. 34 transgenic line. The successful construction of this fluorescent transgenic zebrafish line, Tg (ttn.2: EGFP), laid a foundation for the research of muscle and heart development and related diseases. In addition, the transgenic zebrafish lines with strong green fluorescence can also be used as a new ornamental fish.
Animals ; Zebrafish/genetics* ; Animals, Genetically Modified/genetics* ; Green Fluorescent Proteins/metabolism* ; Zebrafish Proteins/genetics* ; Promoter Regions, Genetic

Motor neurons are an important type of neurons that control movement. The transgenic fluorescent protein (FP)-labeled motor neurons of zebrafish line is disadvantageous for studying the morphogenesis of motor neurons. For example, the individual motor neuron is indistinguishable in this transgenic line due to the high density of the motor neurons and the interlaced synapses. In order to optimize the in vivo imaging methods for the analysis of motor neurons, the present study was aimed to establish a microtubule-fluorescent fusion protein mosaic system that can label motor neurons in zebrafish. Firstly, the promotor of mnx1, which was highly expressed in the spinal cord motor neurons, was subcloned into pDestTol2pA2 construct combined with the GFP-α-Tubulin fusion protein sequence by Gateway cloning technique. Then the recombinant constructs were co-injected with transposase mRNA into the 4-8 cell zebrafish embryos. Confocal imaging analysis was performed at 72 hours post fertilization (hpf). The results showed that the GFP fusion protein was expressed in three different types of motor neurons, and individual motor neurons were mosaically labeled. Further, the present study analyzed the correlation between the injection dose and the number and distribution of the mosaically labeled neurons. Fifteen nanograms of the recombinant constructs were suggested as an appropriate injection dose. Also, the defects of the motor neuron caused by the down-regulation of insm1a and kif15 were verified with this system. These results indicate that our novel microtubule-fluorescent fusion protein mosaic system can efficiently label motor neurons in zebrafish, which provides a more effective model for exploring the development and morphogenesis of motor neurons. It may also help to decipher the mechanisms underlying motor neuron disease and can be potentially utilized in drug screening.
Animals ; Animals, Genetically Modified ; Green Fluorescent Proteins/pharmacology* ; Microtubules/metabolism* ; Motor Neurons ; Zebrafish/genetics* ; Zebrafish Proteins/genetics*

The transposon vector containing enhanced green fluorescent protein (EGFP) was injected into early housefly (Musca domestica L.) eggs by microinjection method to realize stable gene expression in vivo for verification, and to study housefly gene function. A borosilicate glass micro injection needle suitable for microinjection of housefly eggs was made, the softening treatment conditions of housefly egg shells were explored, and a microinjection technology platform suitable for housefly was constructed with a high-precision microsyringe Nanoject Ⅲ as the main body. The recombinant plasmid PiggyBac-[3×P3]-EGFP containing the eye-specific 3×P3 promoter and EGFP and the stable genetic expression helper plasmid pHA3pig helper were microinjected into the treated housefly eggs. After emergence, the eye luminescence was observed, and the expression and transcription level of EGFP were detected. The results showed that the normal hatching rate of housefly eggs was 55% when rinsed in bleaching water for 35 s. The hardness of the egg shell treated for 35 s was suitable for injection and the injection needle was not easy to break. About 3% of the emerged housefly eyes had green fluorescence. Through further molecular detection, EGFP specific fragments with a size of 750 bp were amplified from DNA and RNA of housefly. Through the technical platform, the stable expression of reporter genes in housefly can be conveniently and effectively realized, and a bioreactor with housefly as the main body can be established, which provides certain reference value for subsequent research on housefly gene function.
Animals ; Animals, Genetically Modified ; Gene Expression ; Genes, Reporter ; Green Fluorescent Proteins/genetics* ; Houseflies/genetics* ; Microinjections

Gene expression labeling and conditional manipulation of gene function are important for elaborate dissection of gene function. However, contemporary generation of pairwise dual-function knockin alleles to achieve both conditional and geno-tagging effects with a single donor has not been reported. Here we first developed a strategy based on a flipping donor named FoRe to generate conditional knockout alleles coupled with fluorescent allele-labeling through NHEJ-mediated unidirectional targeted insertion in zebrafish facilitated by the CRISPR/Cas system. We demonstrated the feasibility of this strategy at sox10 and isl1 loci, and successfully achieved Cre-induced conditional knockout of target gene function and simultaneous switch of the fluorescent reporter, allowing generation of genetic mosaics for lineage tracing. We then improved the donor design enabling efficient one-step bidirectional knockin to generate paired positive and negative conditional alleles, both tagged with two different fluorescent reporters. By introducing Cre recombinase, these alleles could be used to achieve both conditional knockout and conditional gene restoration in parallel; furthermore, differential fluorescent labeling of the positive and negative alleles enables simple, early and efficient real-time discrimination of individual live embryos bearing different genotypes prior to the emergence of morphologically visible phenotypes. We named our improved donor as Bi-FoRe and demonstrated its feasibility at the sox10 locus. Furthermore, we eliminated the undesirable bacterial backbone in the donor using minicircle DNA technology. Our system could easily be expanded for other applications or to other organisms, and coupling fluorescent labeling of gene expression and conditional manipulation of gene function will provide unique opportunities to fully reveal the power of emerging single-cell sequencing technologies.
Alleles ; Animals ; CRISPR-Cas Systems ; DNA End-Joining Repair ; DNA, Circular/metabolism* ; Embryo, Nonmammalian ; Gene Editing/methods* ; Gene Knock-In Techniques ; Gene Knockout Techniques ; Genes, Reporter ; Genetic Loci ; Genotyping Techniques ; Green Fluorescent Proteins/metabolism* ; Integrases/metabolism* ; Luminescent Proteins/metabolism* ; Mutagenesis, Insertional ; Single-Cell Analysis ; Zebrafish/metabolism*

Animals ; Antigens, Surface/genetics* ; Cell Communication/genetics* ; Copulation/physiology* ; Fallopian Tubes/metabolism* ; Female ; Fertilization/genetics* ; GPI-Linked Proteins/genetics* ; Gene Expression Regulation ; Genes, Reporter ; Green Fluorescent Proteins/metabolism* ; Litter Size ; Luminescent Proteins/metabolism* ; Male ; Mice ; Mice, Inbred C57BL ; Mice, Knockout ; Mitochondria/metabolism* ; Reproduction/genetics* ; Signal Transduction ; Sperm Count ; Sperm Motility/genetics* ; Spermatozoa/metabolism* ; Uterus/metabolism*

Spermatogonial stem cells (SSCs) transmit genetic information to the next progeny in males. Thus, SSCs are a potential target for germline modifications to generate transgenic animals. In this study, we report a technique for the generation of transgenic rats by in vivo manipulation of SSCs with a high success rate. SSCs in juvenile rats were transduced in vivo with high titers of lentivirus harboring enhanced green fluorescent protein and mated with wild-type females to create founder rats. These founder rats expressed the transgene and passed on the transgene with an overall success rate of 50.0%. Subsequent generations of progeny from the founder rats both expressed and passed on the transgene. Thus, direct modification of SSCs in juvenile rats is an effective means of generating transgenic rats through the male germline. This technology could be adapted to larger animals, in which existing methods for gene modification are inadequate or inapplicable, resulting in the generation of transgenic animals in a variety of species.
Animals ; Green Fluorescent Proteins ; Lentivirus ; Male ; Rats ; Rats, Transgenic ; Spermatogonia/metabolism*

OBJECTIVE: To construct a eukaryotic expression vector of human tissue factor pathway inhibitor-2 (TFPI-2) and to investigate the effect of TFPI-2 gene on the growth of acute monocytic leukemia cell line (SHI-1). METHODS: The cDNA of TFPI-2 was obtained by genetic chemical synthesis, the TFPI-2 gene and the linear vector fragment were ligated and inserted into the multiple cloning site of PEGFP-N1 vector, and the eukaryotic expression vector PEGFP-N1-TFPI-2 was transfected SHI-1 cells, then the obtained SHI-1 cells was observed by fluorescence microscopy; MTT assay was used to detect the effect of TFPI-2 gene on the relative growth rate of SHI-1 cells at the different time-point; RT-PCR was used to detect TFPI-2 mRNA expression levels in the cells of each group before and after TFPI-2 transfection; TFPI-2 protein expression was detected by Western blot. The cells which successfully transfected with PEGFP-N1-TFPI-2 vector were named as SHI-1-TFPI-2 (experimental group), and the cells transfected with the empty vector pEGFP-N1 and the untransfected cells were named as SHI-1-V and SHI-1-P and used as the control group. RESULTS: The human TFPI-2 gene eukaryotic expression vector PEGFP-N1-TFPI-2 was successfully constructed, then the transfected into SHI-1 cells, observed by fluorescence microscopy 24 hours later, as a result, the PEGFP-N1-TFPI-2 was successfully transferred into SHI-1 cells, and the number of fluorescent cells increased after 48 h and 72 h. RT-PCR showed that the gray scale ratio of TFPI-2 gene to β- actin in the experimental group was higher than that in the control group. The gray scale ratio was 0.51±0.04 in SHI-1-V group, 0.52±0.03 in SHI-1-P group, 0.87±0.08 in SHI-1-TFPI-2 group, and the difference between SHI-1-TFPI-2 and SHI-1-V, SHI-1-P group was statistically significant (P＜0.05). CONCLUSION The expression of TFPI-2 gene in PEGFP-N1-TFPI-2 can inhibit the growth of SHI-1 cells, which provides a research direction for gene therapy of leukemia in the future.
Eukaryota ; Genetic Vectors ; Glycoproteins ; metabolism ; Green Fluorescent Proteins ; Humans ; Transfection

Self-assembling amphipathic peptides (SAPs) have alternating hydrophilic and hydrophobic residues and can affect the thermal stabilities and catalytic properties of the fused enzymes. In this study, a novel multifunctional tag, S1vw (HNANARARHNANARARHNANARARHNARARAR) was developed to modify fused enzymes. After fusing S1vw at the enzymes/proteins N-terminus through a PT-linker, the crude enzymatic activities of polygalacturonate lyase and lipoxygenase were enhanced 3.1- and 1.89-fold, respectively, compared to the wild-type proteins. The relative fluorescence intensity of the green fluorescent protein was enhanced 16.22-fold. All the three S1vw fusions could be purified by nickel column with high purities and acceptable recovery rates. Moreover, S1vw also induced the thermostabilities enhancement of the fusions, with polygalacturonate lyase and lipoxygenase fusions exhibiting 2.16- and 3.2-fold increase compared with the corresponding wild-type, respectively. In addition, S1vw could enhance the production yield of green fluorescent protein in Escherichia coli and Bacillus subtilis while the production of GFP and its S1vw fusion changed slightly in Pichia pastoris. These results indicated that S1vw could be used as a multifunctional tag to benefit the production, thermal stability and purification of the fusion protein in prokaryotic expression system.
Escherichia coli ; Green Fluorescent Proteins ; Hydrophobic and Hydrophilic Interactions ; Peptides ; Pichia ; Recombinant Fusion Proteins ; metabolism

OBJECTIVE: To establish the STO cell lines expressing green fluorescent protein (GFP) and mouse leukemia inhibitory factor (LIF) , and try to culture the mouse embryonic stem cells (mESCs) by using the established STO-GFP-mLIF cells as the feeder layer. METHODS: The lentiviral particles containing GFP and mLIF and puromycin-resistance gene were constructed and transduced into STO cell lines. The cell lines stably expressing GFP and mLIF genes were screened out. The expression level of the inserted exogenous LIF gene was tested by Western blot and ELISA. The STO-GFP-mLIF cells were treated with different concentrations of mitomycin C (5, 10, 15, 20 µg/ml) for different time (1.5, 2.5, 3, 3.5 hours) to prepare feeder layers and the cell proliferation level on feeder layer was observed. Mouse embryonic stem cells were cultured on mitomycin C-treated feeder layer and the growth of cell colonies was observed. RESULTS: The expression level of LIF protein in STO-GFP-mLIF cells was up-regulated, as compared with STO cells (P＜0.05). It was confirmed that the optimal concentration and time for inhibiting the proliferetion of STO-GFP-mLIF cells by mitomycin C were 10 µg/ml and 3 hours respectively. The observation also found that the embryonic stem cells could develop into typic "birdnest" shaped stem cell colony on mitomycin C-treated feeder layer. CONCLUSION The stable STO cell lines effectively expressing green fluorescent protein and mouse leukemia inhibitory factor have been established successfully, which can maintain the undifferentiated state of mouse embryonic stem cells.
Animals ; Cell Differentiation ; Cell Line ; Cell Separation ; Embryonic Stem Cells ; Feeder Cells ; Green Fluorescent Proteins ; Leukemia Inhibitory Factor ; Mice

OBJECTIVE: To investigate the effects of autophagy on osteogenic differentiation of stem cells from the apical papilla (SCAPs) in the presence of tumor necrosis factor- (TNF-) stimulation . METHODS: SCAPs treated with TNF- (0, 5, and 10 ng/mL) with or without 5 mmol/L 3-MA were examined for the expression of autophagy marker LC3-Ⅱ using Western blotting. The cells were transfected with GFP-LC3 plasmid and fluorescence microscopy was used for quantitative analysis of intracellular GFP-LC3; AO staining was used to detect the acidic vesicles in the cells. The cell viability was assessed with CCK-8 assays and the cell apoptosis rate was analyzed using flow cytometry. The cells treated with TNF- or with TNF- and 3-MA were cultured in osteogenic differentiation medium for 3 to 14 days, and real- time PCR was used to detect the mRNA expressions of osteogenesis-related genes (ALP, BSP, and OCN) for evaluating the cell differentiation. RESULTS: TNF- induced activation of autophagy in cultured SCAPs. Pharmacological inhibition of TNF--induced autophagy by 3-MA significantly decreased the cell viability and increased the apoptosis rate of SCAPs ( < 0.05). Compared with the cells treated with TNF- alone, the cells treated with both TNF- and 3-MA exhibited decreased expressions of the ALP and BSP mRNA on days 3, 7 and 14 during osteogenic induction ( < 0.05) and decreased expression of OCN mRNA on days 3 and 7 during the induction ( < 0.05). CONCLUSIONS Autophagy may play an important role during the osteogenic differentiation of SCAPs in the presence of TNF- stimulation.
Autophagy ; drug effects ; physiology ; Cell Differentiation ; drug effects ; physiology ; Cell Survival ; drug effects ; Cells, Cultured ; Dental Papilla ; cytology ; Green Fluorescent Proteins ; Humans ; Osteogenesis ; physiology ; Stem Cells ; drug effects ; physiology ; Transfection ; Tumor Necrosis Factor-alpha ; administration & dosage ; antagonists & inhibitors ; pharmacology