Improvement in the heterogeneous N-termini and the defective N-glycosylation of human interleukin-6 by genetic engineering.

Recombinant human interleukin-6 (IL-6), expressed in Chinese hamster ovary cells, has heterogeneous N-termini of Ala1 and Val3, as does naturally occurring IL-6. This heterogeneity is thought to be caused by difficulty in cleavage of the signal sequence. To obtain homogeneous IL-6, Pro at -1 was exchanged for Ala by site-directed mutagenesis. Alternatively, the signal sequence was replaced with that of human granulocyte-colony-stimulating factor. In both cases, the IL-6 designed to start with Ala1 was still heterogeneous, while the IL-6 designed to start with Val3 showed a homogeneous N-terminus. It is suggested that the heterogeneity of the N-terminus is caused not only by the signal sequence, but also by the succeeding sequences of the mature protein. Only a portion of recombinant human IL-6 is N-glycosylated. Asn46, being exchanged for Gln by site-directed mutagenesis, was confirmed to be partially N-glycosylated. The defective N-glycosylation was assumed to be caused by interference or tension from a disulfide bond near the N-glycosylation site. To verify this hypothesis, the Cys45 and Cys51 forming the disulfide bond were exchanged for Ser. The N-glycosylated species became predominant upon this substitution, suggesting that formation of the disulfide bond is a cause of the defective N-glycosylation.

Role of sugar chains in the expression of the biological activity of human erythropoietin.

Various deglycosylated derivatives of recombinant human erythropoietin (hEPO) were prepared and used to determine the role of the sugar chains in the expression of its biological activity in vivo and in vitro. Three N-linked oligosaccharides of hEPO have been partially or fully removed to obtain N-glycan (NG) (2)-, NG(1)-, and NG(0)-hEPO carrying two, one, and no N-linked sugar chains, respectively. The preparation lacking only O-linked sugar chain O O-glycan (OG) (0)-hEPO was also used. As de-N-glycosylation proceeded, the in vivo activity of the hormone decreased drastically, and the activity of these derivatives was correlated with the number of sialic acids bound to them. On the contrary, the in vitro activity was increased by the de-N-glycosylation; NG(0)-hEPO showed a 3-fold higher specific activity than the intact hormone. This was confirmed by binding experiments of the derivatives to target cells. The in vitro activity and the affinity also correlated with the number of sialic acids bound to the deglycosylated hEPO preparations. On the other hand, OG(0)-hEPO was as active as the intact hormone in vivo and in vitro. In conclusion, the N-linked sugar chains are not required for in vitro activity but required for in vivo activity, acting as anchors for the essential terminal sialic acids. The O-linked sugar chain has no essential role in the biological activity of the hormone in vivo or in vitro.

cDNA clones of Japanese hepatitis C virus genomes derived from a single patient show sequence heterogeneity.

Twelve cDNA clones of Japanese hepatitis C virus (HCV) have been isolated from liver tissue of a single non-A, non-B hepatitis patient. These clones represented the non-structural domains of HCV. The degree of substitution in the nucleotide sequences and deduced amino acid sequences between these clones was 9.5 and 7.7%, respectively. This high level of substitution suggested that repeated infections of different HCVs may have occurred in the patient.

Physicochemical and biological characterization of asialoerythropoietin. Suppressive effects of sialic acid in the expression of biological activity of human erythropoietin in vitro.

Various partially or fully desialylated human erythropoietins were obtained by neuraminidase digestion of the hormone, without non-specific proteolysis and degradation of carbohydrates. Asialoerythropoietin showed a specific activity of 220-IU/mg protein in vivo, although that of the intact erythropoietin was 2.2 x 10(5) IU/mg. A linear relationship was found between the logarithm of the specific activity in vivo and the number of sialic acids. The asialoerythropoietin showed a four-times-higher specific activity in vitro compared with intact erythropoietin using mouse bone marrow cells. It also showed an approximately six-times-higher specific activity in a colony-forming assay for the erythroid colony-forming unit and the erythroid burst-forming unit. Partially or fully de-N-glycosylated erythropoietin derivatives also showed lower in vivo activity but higher in vitro activity than the intact erythropoietin, dependent on the number of sialic acids. To clarify the reason for the enhanced biological activity of asialoerythropoietin in vitro, the binding of intact 125I-erythropoietin or 125I-asialoerythropoietin to cells containing specific receptors for the hormone was analyzed. 125I-asialoerythropoietin bound to spleen cells from anemic mice approximately five times faster than did intact 125I-erythropoietin. The amount of 125I-asialoerythropoietin internalized by target cells, measured in the absence of NaN3, was four times higher than that of intact erythropoietin. These results demonstrate that asialoerythropoietin binds to its receptor faster than the intact form. This may be the main reason for the increased activity of asialoerythropoietin in vitro.