Multimedia computing technology teaching is a new kind teaching method. It conquers many shortcomings such as poor video, poor expression in traditional teaching of microbiology. But it can also strangle the improvising creation of different teachers in teaching and then lead it to be typical " computer teaching" . So we should obey the teaching discipline in making multimedia computing technology courseware. It can lead many sections part from the class teaching if just emphasize the full use of video and audio. We should make the purpose obviously, and make it as easy as possible in teaching, and we should also explore the fixed regularity to make the teaching and studying integrated perfectly.

To investigate the improving effect of inter-chain disulfide formation on protein trans-splicing, we introduce a Cys point mutation at Tyr(664) in heavy chain and at Thr(1826) in light chain of B-domain-deleted FVIII (BDD-FVIII). By co-transfection of COS-7 cell with the two Cys mutated chain genes, the intracellular protein splicing, inter-chain disulfide formation, secreted BDD-FVIII and bioactivity in culture supernatant were observed. The data showed that a strengthened spliced BDD-FVIII with an inter-chain disulfide detected by Western blotting and an elevated secretion of spliced BDD-FVIII (128 +/- 24 ng mL(-1)) compared to control (89 +/- 15 ng mL(-1)), assayed by a sandwich ELISA. A Coatest was performed to assay the secretion of bioactivity in culture supernatant and shown a much higher value (0.94 +/- 0.08 u mL(-1)) compared to that of control (0.62 +/- 0.15 u mL(-1)). It suggests that inter-chain disulfide formation could improve protein trans-splicing based dual-vector delivery of BDD-FVIII gene providing experimental evidence for ongoing in vivo study.
Animals ; COS Cells ; Cercopithecus aethiops ; Cysteine ; genetics ; metabolism ; Disulfides ; metabolism ; Factor VIII ; genetics ; metabolism ; Gene Transfer Techniques ; Genetic Vectors ; Mutation ; Peptide Fragments ; genetics ; metabolism ; Protein Splicing ; Transfection

Low levels of coagulation factor VIII (fVIII) protein expression caused by its inefficient secretion and the over-sized fVIII gene affect the transgene-based gene therapy for hemophilia A adversely. Our previous study demonstrated that intein-mediated protein trans-splicing for delivery of the fVIII gene with a dual-vector system could improve secretion of post-translationally spliced fVIII by light chain in cis. In this study, a human/porcine hybrid fVIII (HP-fVIII) containing replaced A1 and A3 domains of porcine fVIII was investigated for secretion and activity of the spliced HP-fVIII after intein-based dual-vector delivery of the HP-fVIII gene. A pair of expression plasmids comprising intein-fused HP-fVIII heavy and light chains were constructed and transiently co-transfected into COS-7 cells. The spliced HP-fVIII and bio-activity in culture media were quantitatively analyzed by ELISA and Coatest method respectively. The intracellular splicing of HP-fVIII was detected by Western blotting. The results showed that in the culture supernatant of cells co-transfected with HP-fVIII, the amount and activity of spliced HP-fVIII were significantly higher than those of spliced hfVIII secreted from the cells co-transfected with human fVIII [(184+/-34 ng/mL) vs (48+/-12) ng/mL, P<0.01; (1.18+/-0.22) IU/mL vs (0.31+/-0.10) IU/mL, P<0.01], demonstrating the dramatically enhancing effect of porcine A1 and A3 domains on the secretion of intein-spliced HP-fVIII. The spliced HP-fVIII protein and its activity were also detected in the supernatant from combined cells separately transfected with intein-fused HP-fVIII heavy and light chain genes, indicating that the intein-mediated HP-fVIII splicing was independent of cellular mechanism and could occur outside the cell after the secretion of precursor proteins. Additionally, an intracellularly spliced HP-fVIII band was found with a molecular weight similar to human fVIII protein, confirming the HP-fVIII splicing. These results provided experimental basis for ongoing study using intein-based dual adeno-associated virus (AAV) vector to transfer HP-fVIII gene in animal models.
Animals ; COS Cells ; Cercopithecus aethiops ; Dependovirus ; genetics ; metabolism ; Factor VIIIa ; biosynthesis ; genetics ; Genetic Vectors ; Humans ; Inteins ; Protein Splicing ; Recombinant Fusion Proteins ; genetics ; Swine ; Trans-Splicing

The mutation of cystic fibrosis transmembrane conductance regulator (CFTR) gene leads to an autosomal recessive genetic disorder cystic fibrosis (CF). The gene therapy for CF using adeno-associated virus (AAV) vectors delivering CFTR gene is restricted by the contents limitation of AAV vectors. In this study the split CFTR genes severed at its regulatory domain were delivered by a dual-vector system with an intein-mediated protein trans-splicing as a technique to investigate the post-translational ligation of CFTR half proteins and its function as a chloride ion channel. A pair of eukaryotic expression vectors was constructed by breaking the human CFTR cDNA before Ser712 codon and fusing with Ssp DnaB intein coding sequences. After co-transfection into baby hamster kidney (BHK) cells followed by transient expression, patch clamps were carried out to record the chloride current of whole-cell and the activity of a single channel, and the ligation of two halves of CFTR was observed by Western blotting. The results showed that the intein-fused half genes co-transfected cells displayed a high whole cell chloride current and activity of a single channel indicating the functional recovery of chloride channel, and an intact CFTR protein band was figured out by CFTR-specific antibodies indicating that intein can efficiently ligate the separately expressed half CFTR proteins. The data demonstrated that protein splicing strategy could be used as a strategy in delivering CFTR gene by two vectors, encouraging our ongoing research program on dual AAV vector system based gene transfer in gene therapy for cystic fibrosis.
Animals ; Cells, Cultured ; Chlorides ; metabolism ; Codon ; genetics ; Cricetinae ; Cystic Fibrosis ; therapy ; Cystic Fibrosis Transmembrane Conductance Regulator ; genetics ; metabolism ; DNA, Complementary ; genetics ; Dependovirus ; genetics ; Genetic Therapy ; Genetic Vectors ; Humans ; Inteins ; physiology ; Kidney ; cytology ; Protein Processing, Post-Translational ; Recombinant Proteins ; genetics ; metabolism ; Trans-Splicing ; Transfection

Coagulation factor VIII (fVIII) is a secretion protein and plays a crucial role in the coagulation cascade. Hemophilia A resulted from deficiency of fVIII is the most common X-linked recessive bleeding disorder. Gene therapy is recognized as an attractive strategy for the eventual cure of this disease. However, the gene therapy is hampered by the big size of fVIII gene when using the most promising gene vectors, adeno-associated virus (AAV) vectors. In this study we explored the intein-mediated protein trans-splicing to deliver a Phe(309)-->Ser mutant full-length fVIII (F309SfVIII) gene by using a dual-vector system. An intein is a protein sequence embedded within a precursor protein and can excise itself through protein splicing. The F309SfVIII is proven to be beneficial to its secretion. The F309SfVIII gene was broken into heavy and light chains before Ser(1239) in B domain and fused with the coding sequences of Ssp DnaB intein respectively to construct a pair of plasmid vectors by inserting them into the pcDNA3.1 vectors. Forty-eight hours after co- or separate transfection of 293 cells, the co-transfected cell lysate showed an obvious ligated F309SfVIII protein band by Western blot with a polyclonal antibody against fVIII. The amounts of secreted F309SfVIII protein in culture supernatants and their bioactivities were (71+/-9) ng/mL and (0.38+/-0.09) IU/mL determined by ELISA and Coatest assay respectively. The supernatant from combined cells with separate transfections also displayed lower levels of F309SfVIII antigen and fVIII activity [(25+/-6) ng/mL and (0.12+/-0.05) IU/mL], indicating the F309SfVIII could be formed by splicing both before and after secretion. The content of F309SfVIII heavy chain protein from co-transfected cell supernatant was higher than that of intein-fused heavy chain transfection alone [(135+/-10) ng/mL vs (37+/-7) ng/mL, P<0.01)]. These data demonstrated that intein could be used as a technical strategy in a dual-vector system delivering F309SfVIII gene with improved secretion of fVIII providing an alternative approach to circumvent the packaging limitation of AAV for F309SfVIII gene transfer, which encourages our continuing study in hemophilia A gene therapy in vivo.
Cell Line ; Dependovirus ; Factor VIII ; metabolism ; Genetic Vectors ; Humans ; Inteins ; Protein Splicing

This study is to construct a chimeric human/porcine BDD-FVIII (BDD-hpFVIII) containing the substituted porcine A1 and A3 domains which proved to have a pro-secretory function. By exploring Ssp DnaB intein's protein trans-splicing a dual-vector was adopted to co-transfer the chimeric BDD-hpFVIII gene into cultured COS-7 cell to observe the intracellular BDD-hpFVIII splicing by Western blotting and secretion of spliced chimeric BDD-hp FVIII protein and bio-activity using ELISA and Coatest assay, respectively. The dada showed that an obvious protein band of spliced BDD-hpFVIII can be seen, and the amount of spliced BDD-hpFVIII protein and bio-activity in the supernatant were up to (340 +/- 64) ng x mL(-1) and (2.52 +/- 0.32) u x mL(-1) secreted by co-transfected cells which were significantly higher than that of dual-vector-mediated human BDD-FVIII gene co-transfection cells [(93 +/- 22) ng x mL(-1), (0.72 +/- 0.13) u x mL(-1)]. Furthermore, a spliced BDD-hpFVIII protein and activity can be detected in supernatant from combined cells separately transfected with intein-fused BDD-hpFVIII heavy and light chain genes indicating that intein-mediated BDD-hpFVIII splicing occurs independently of cellular mechanism. It provided evidence for enhancing FVIII secretion in the research of animal models using intein-based dual vector for the delivery of the BDD-hpFVIII gene.
Animals ; COS Cells ; Cercopithecus aethiops ; Factor VIII ; genetics ; metabolism ; secretion ; Genetic Vectors ; Humans ; Inteins ; Peptide Fragments ; genetics ; metabolism ; secretion ; Plasmids ; Protein Splicing ; Swine ; Trans-Splicing ; Transfection

As synthesized by vascular endothelial cells and megakaryocytes, the von Willebrand factor (vWF) plays an important hemostatic role in the binding to and stabilizing blood coagulation factor VIII (FVIII) and preventing its enzymatic degradation. Our recent work demonstrated intein can efficiently ligate BDD-FVIII (B-domaim deleted FVIII) posttranslationally by protein trans-splicing after transfer of split BDD-FVIII gene by a dual-vector system. In this study we investigated the effect of vWF on secretion and activity of intein-ligated BDD-FVIII. We observed the levels of full-length BDD-FVIII antigen secreted into culture supernatant by ELISA and their activity by Coatest assay after transfection of cultured 293 cells with intein-fused BDD-FVIII heavy- and light-chain genes simultaneously with the vWF gene co-transfected. The data showed that the amount of full-length BDD-FVIII protein and their bioactivity in vWF gene co-transfected cell supernatant were 235 +/- 21 ng x mL(-1) and 1.98 +/- 0.2 u x mL(-1), respectively, greater than that of non-vWF co-transfected cell (110 +/- 18) ng x mL(-1) and 1.10 +/- 0.15 u x nL(-1)) or just BDD-FVIII gene transfected control cell (131 +/- 25 ng x mL(-1) and 1.22 +/- 0.18 u x mL(-1)) indicating the benefit of vWF gene co-transfection in the secretion and activity of intein-spliced BDD-FVIII protein. It provided evidence that vWF gene co-transfer may be useful to improve efficacy of gene therapy for hemophilia A in protein splicing-based split FVIII gene transfer.
Factor VIII ; genetics ; metabolism ; secretion ; Genetic Therapy ; Genetic Vectors ; HEK293 Cells ; Hemophilia A ; therapy ; Humans ; Inteins ; Peptide Fragments ; genetics ; metabolism ; secretion ; Plasmids ; Protein Splicing ; Trans-Splicing ; Transfection ; von Willebrand Factor ; genetics ; metabolism ; physiology

We recently demonstrated that an intein-mediated protein splicing can be used to transfer B-domain-deleted FVIII (BDD-FVIII) gene by a dual-vector. In this study, we observed the effect of a variant heavy chain with six potential glycosylation sites of B domain and L303E/F309S mutations in its A1 domain, which were proven to be beneficial for FVIII secretion, on secretion of spliced BDD-FVIII. By transient co-transfection of cultured 293 cells with intein-fused variant heavy chain (DMN6HCIntN) and light chain (IntCLC) genes, the culture supernatant was analyzed quantitatively by ELISA for secreted spliced BDD-FVIII antigen and by a chromogenic assay for bioactivity. The data showed that the amount of spliced BDD-FVIII protein and coagulation activity in culture supernatant from DMN6HCIntN plus IntCLC co-transfected cells were up to (149 +/- 23) ng x mL(-1) and (1.12 +/- 0.14) u x mL(-1) respectively greater than that of intein-fused wild type heavy (HCIntN) and light chain (IntCLC) co-transfected cells [(99 +/- 14) ng x mL(-1) and (0.77 +/- 0.13) u x mL(-1)] indicating that the variant heavy chain is able to improve the secretion of spliced BDD-FVIII and activity. A cellular mechanism-independent BDD-FVIII splicing was also observed. It provided evidence for ongoing animal experiment using intein-mediated dual-AAV vector technology for delivery of the BDD-FVIII genes.
Factor VIII ; genetics ; metabolism ; secretion ; Glycosylation ; HEK293 Cells ; Humans ; Inteins ; Mutation ; Peptide Fragments ; genetics ; metabolism ; secretion ; Protein Splicing ; Trans-Splicing ; Transfection

Adolescent ; Adult ; Aged ; Clavicle ; injuries ; Female ; Fracture Fixation, Internal ; methods ; Fractures, Bone ; surgery ; Humans ; Male ; Middle Aged ; Scapula ; injuries

In our recent study by exploring an intein-based dual-vector to deliver a B-domain-deleted FVIII (BDD-FVIII) gene, it showed that covalently ligated intact BDD-FVIII molecules with a specific coagulant activity could be produced from expressed heavy and light chains by protein trans-splicing. Here, we assessed the hypothesis that the efficiency of trans-splicing may be increased by adding to the intein sequences a pair of leucine zippers that are known to bring about specific and strong protein binding. The intein-fused heavy and light chain genes were co-transferred into cultured COS-7 cells using a dual-vector system. After transient expression, the intracellular BDD-FVIII splicing was observed and the spliced BDD-FVIII and bioactivity secreted to culture media were quantitatively analyzed. An enhanced splicing of BDD-FVIII with decreased protein precursors from gene co-transfected cells was observed by Western blotting. The amount of spliced BDD-FVIII and bioactivity secreted to the culture media were 106 +/- 12 ng x mL(-1) and 0.89 +/- 0.11 U x mL(-1) analyzed by ELISA and Coatest method respectively, which was greater than leucine zipper free intein-fused heavy and light chain genes co-transfected cells (72 +/- 10 ng x mL(-1) and 0.62 +/- 0.07 U x mL(-1)). The activity of cellular mechanism-independent protein splicing was also improved, as showed by the increasing of spliced BDD-FVIII and bioactivity in culture media from combined cells separately transfected with heavy and light chain genes which was 36 +/- 11 ng x mL(-1) and 0.28 +/- 0.09 U x mL(-1). It demonstrated that the leucine zippers could be used to increase the efficiency of protein trans-splicing to improve the efficacy of a dual-vector mediated BDD-FVIII gene delivery by strengthening the interaction between the two intein-pieces fused to heavy and light chains. It provided evidence for further study in animal model using a dual-adeno-associated virus vector to deliver FVIII gene in vivo.
Animals ; COS Cells ; Cercopithecus aethiops ; Factor VIII ; chemistry ; genetics ; metabolism ; Genetic Vectors ; Inteins ; Leucine Zippers ; Peptide Fragments ; chemistry ; genetics ; metabolism ; Protein Splicing ; Trans-Splicing ; Transfection