Masanori Suzuki

Overproduction of human epidermal growth factor/urogastrone in Escherichia coli and demonstration of its full biological activities

Abstract A man-made gene coding for [21-Leu] human epidermal growth factor (hEGF)/β-urogastrone was constructed, inserted into a lacZ fusion-gene expression vector, and cloned into Escherichia coli . In the cloned cells the β-galactosidase/hEGF fusion gene was efficiently expressed and the yield of the hybrid protein reached 10% of the total cellular protein. The [21-Leu] hEGF synthesized in the bacterial cells was proved to be as functional as the natural hEGF or urogastrone and mouse EGF by the following criteria: (1) stimulation of cell proliferation, (2) stimulation of thymidine incorporation into cultured cells, (3) competition with mouse EGF for binding sites on the plasma membrane of human KB cells, and (4) stimulation of phosphorylation of a membrane-bound protein of human KB cell, which has an apparent molecular weight of 150 000 to 170 000 and is indistinguishable from the protein phosphorylated in the presence of mouse EGF in the sodium dodecyl sulfate—polyacrylamide electrophoretic gel. The hEGF produced in the bacterial cells also resulted in precocious eyelid-opening by the daily subcutaneous injection into newborn mice and in accelerated incisor eruption in the animals as mouse EGF did, indicating that the hEGF is also fully active in vivo or physiologically.

Presence of autoantibodies to peptidyl-prolyl cis-trans isomerase (cyclosporin A-binding protein) in systemic lupus erythematosus.

Several autoantibodies against cytoplasmic or nuclear components of cells have been reported in autoimmune diseases. We report here a previously unrecognized autoantibody to peptidyl-prolyl cis-trans isomerase (PPIase) in patients with systemic lupus erythematosus (SLE). PPIase, which catalyzes the cis-trans isomerization of proline imidic peptide bonds in oligopeptides, has recently been found to be identical to cyclophilin, a specific binding protein of a potent immunosuppressant, cyclosporin A. IgG and IgM anti-PPIase antibodies were detected in 40 and 20% of unselected patients with SLE, respectively, by ELISA. The reactivity of these sera was confirmed by immunoblotting experiments. Sera from rheumatoid arthritis patients showed no reactivity and 1 of 8 sera from systemic sclerosis patients and 1 of 25 sera from normal controls showed only weak reactivity. Unexpectedly, the anti-PPIase antibody was unable to inhibit PPIase activity, indicating that the autoantibody recognizes an epitope of PPIase which is different from the active site of PPIase. The levels of the anti-PPIase antibody in SLE patients correlated with remissions and flares of the disease. The anti-PPIase antibody was higher in patients with active SLE than those with inactive disease. The prevalence of the active stage of the disease was significantly higher in IgG anti-PPIase antibody-positive SLE patients as compared to antibody-negative SLE patients. These data define the presence of a new autoantibody against PPIase and its association with the activity and certain clinical manifestations in SLE.

Expression enhancement of the Tn5 neomycin-resistance gene by removal of upstream ATG sequences and its use for probing heterologous upstream activating sequences in yeast

We have constructed a series of promoter or upstream activating sequence (UAS)-probe plasmids carrying the Tn5-derived neomycin resistance gene whose seven additional ATG codons in the 5′-untranslated region were completely or partially removed. When the deleted version of the neo sequence retaining only one additional ATG (NeoD) was expressed under the control of a TDH3 promoter whose UAS was deleted, the transformed cells were unable to grow at a low concentration of the antibiotic G418. In contrast with this, yeast cells expressing the NeoC sequence and having no additional ATG exhibited a high level of G418-resistance. Moreover, the UAS-probe system using NeoD has been successfully applied for the identification of several E. coli DNA sequences that clearly function as UASs in yeast cells. Two of these prokaryotic sequences with UAS activity were identified as a part of the coding region of the tgt and the hydG gene, respectively.