Transgenic mice were generated in which 5 kb of the 5′ flanking promoter region of the human Factor IX (FIX) gene fused to various FIX constructs (gene, minigene and cDNA) were stably integrated in the germ line. Several transgenic mouse lines expressed high circulating levels of active and correctly processed recombinant human FIX. The presence of at least one FIX intron had a positive effect on the expression. The FIX transgenes were expressed in a tissue‐specific manner in the liver of transgenic mice. By crossing transgenic mice synthesizing FIX with others prone to develop hepatoma, progeny which co‐express the transgenes in hepatocytes were obtained. Hepatoma‐derived cell lines were shown to have a differentiated phenotype and secrete active human FIX for many generations.
We have constructed new B domain deletion derivatives of human factor VIII (FVIII) by manipulating the cDNA using recombinant DNA techniques. One of these new derivatives, FVIII delta II, in which amino acids 771(pro)-1666(asp) have been deleted, no longer contains the protease cleavage site at amino acid position 1648(arg)-1649(glu) known to be involved in the initial step of FVIII processing. We have expressed this molecule in both baby hamster kidney (BHK) 21 cells using the vaccinia virus (VV) expression system and have established Chinese hamster ovary (CHO) derived permanent cell lines expressing either recombinant (r)FVIII or FVIII delta II. The characteristics of FVIII delta II have been compared to those of rFVIII and/or plasma derived (pd) FVIII. FVIII delta II has the following properties: (i) it exhibits FVIII procoagulant activity; (ii) it is expressed at 5-fold higher levels than is the complete molecule in comparable systems; (iii) it migrates for the most part as a single major band on SDS-PAGE, in contrast to the complete molecule; (iv) it is activated to a greater extent by thrombin than is either rFVIII or pdFVIII; and (v) it retains the ability to bind von Willebrand factor (vWf).
Two murine monoclonal antibodies (MAbs), designated MATG2014 and MATG2033, were generated. They are reactive with the external envelope glycoprotein gp130 of the simian immunodeficiency virus of macaque monkey (SIVmac251), and display a cell-free virus neutralizing activity in vitro. In addition, MATG2014 cross-reacts with HIV-2Rod gp140. Epitope mapping of these MAbs was performed by screening and SIVmac peptide library expressed in yeast and confirmed using synthetic peptides. MATG2014 and MATG2033 recognize two overlapping epitopes localized in an 18 residue domain between amino acid 171 and 188 of the SIVmac251 gp130. Sera from experimentally SIV-infected macaques are immunoreactive with this neutralizing domain. Sequence comparison with related SIV and HIV-2 viral strains indicates a low variability of this region, consistent with the cross-reactivity of MATG2014 with HIV-2Rod gp140. This domain should then be considered in designing experimental vaccines.
Parameters influencing the efficiency of expression of the human immune interferon (IFN-gamma) gene in E. coli were studied by comparing a series of eight in vitro-derived gene variants. These contained all possible combinations of silent mutations in the first three codons of the mature IFN-gamma polypeptide coding sequence. Expression levels varied up to 50-fold among the different constructions. Comparison of messenger RNA secondary structure models for each variant suggested that the presence of stem-loop structures blocking the translation initiation signals could drastically decrease the efficiency of IFN-gamma synthesis. With variants displaying no stable mRNA secondary structure in the region, a C----U transition at position +11 after the AUG resulted in a 5-fold increase in expression indicating that RNA primary structure also plays an important role in expression. In addition we demonstrate that, in this system, a spacing of 8 nucleotides between the Shine-Dalgarno region and AUG was optimal for gene expression and that the steady-state production level of IFN-gamma rose exponentially with increasing rate of synthesis.
A stable transformed cell line constitutively expressing human factor IX has been established. Wild-type Chinese hamster ovary cells (CHO cells) were transformed using a polycistronic expression vector carrying a previously isolated factor IX cDNA and a selection gene encoding the Escherichia coli xanthine-guanine phosphoribosyl transferase. One clone, CHO 622.4, contains a high number of genomically integrated plasmids and secretes 1-3 mg factor IX 1-' day-' into the culture medium with a biological activity ranging from 25% to 40%. The recombinant molecule was purified either by conventional chromatography or by immunoaffinity chromatography using antibodies specific to a calcium-induced factor IX conformer. The purified recombinant protein migrates as a single band with the same mobility as that of natural factor IX on SDS/polyacrylamide gels. N-terminal sequencing shows two differently processed forms of recombinant factor IX: whereas the majority of the zymogen is correctly processed, approximately 20% of the purified recombinant molecule contains an 18-amino-acid NH2-extension corresponding to the precursor form of factor IX. Analysis of the 4-carboxyglutamic acid content indicates a high but incomplete carboxylation (70%) of the recombinant molecule as compared to natural factor IX.The carbohydrate composition of both the natural and recombinant molecules has been determined. Both molecules have a N-glycan structure of similar complexity, indicating that factor IX contains all the information to direct the same glycosylation pattern in human liver cells and in an unrelated cell line such as CHO-K1 .Hemophilia B, an X-linked bleeding disorder, is due to a deficiency in blood-clotting factor IX. Factor IX is synthesised as a preprozymogen in the liver and is subjected to four post-translational modifications : glycosylation, NH2-terminal processing, vitamin-K-dependant 4-carboxylation of the first 12 glutamic acid residues and 3-hydroxylation of an aspartic acid residue [l -31. Due to these complexities, factor IX production using recombinant DNA technology requires the use of mammalian cells as expression host. Several mammalian cell lines have been tested for their ability to produce active human factor IX: baby hamster kidney cells [4], rat hepatoma cells [5], human hepatoma cells [6], CHO cells deficient in dihydrofolate reductase [7]. More recently, using a different approach, the complete factor IX cDNA was expressed in transgenic mice [8]. The isolation and characterisation of the recombinant molecule have been previously described in only one study [7].In this paper we report the expression of human recombinant factor IX in a stable wild-type CHO cell line transformed with a dicistronic expression vector. The recombinant molecule has been purified, N-terminally sequenced, the ex- tent of 4-carboxylation of glutamic acid determined, and carbohydrate composition compared to the natural molecule. MATERIALS AND METHODS Construction of factor I X expression vector, pTG381Factor IX cDNA was recovered fr...
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