Formation of poliomyelitis subviral particles in the yeast Saccharomyces cerevisiae.

The sequence of the poliovirus genome encoding 3CD (a protease) was transferred to the yeast Saccharomyces cerevisiae on expression vectors with either a constitutive or an inducible promoter. Transformants could only be obtained with vectors carrying the inducible transcription unit. Extracts of induced cells were able to cleave cell-free synthesized P1, the precursor of the poliovirus capsid proteins, into VP0, VP3 and VP1. In yeast cells constitutively expressing P1, induction of 3CD expression resulted in only trace amounts of processed products. Processing could be improved considerably by simultaneous induction of both P1 and 3CD expression. Analysis of extracts of such induced cells revealed the presence of particles that resembled authentic subviral particles.

Synthesis of fusion proteins containing antigenic determinants of foot-and-mouth disease virus.

Part of the genome of foot-and-mouth disease virus (FMDV) type 01,BFS, including the sequence encoding the capsid polypeptide VP1, was cloned in Escherichia coli following a new cloning strategy. The clone containing the VP1 sequence was used for the construction of two expression plasmids encoding VP1 fusion proteins. Subsequently, substantial amounts of the two VP1-beta-galactosidase fusion proteins, containing either one (amino acid region 140-160) or two (amino acid regions 140-160 and 200-213) antigenic determinants of the virus, were synthesized by E. coli bacteria. The protein containing the amino acid region 140-160 of VP1 fused to beta-galactosidase efficiently induced antibodies in rabbits specifically reacting with FMDV type 01,BFS. The same protein was also capable of eliciting neutralizing antibodies. The fusion protein containing both antigenic determinants did not efficiently induce antibodies reacting with FMDV.

Functional heterogeneity of transferrin-bound iron: iron uptake by cell suspensions from bone marrow and liver and by cell cultures of fibroblasts and lymphoblasts.

According to the hypothesis of Fletcher and Huehns, functional differences exist between both iron-binding sites of transferrin. The site designated A should mainly be involved in the delivery of iron to erythroid cells, whereas site B should donate its iron preferentially to cells involved in the absorption and storage of iron. In the present study this hypothesis could be confirmed by in vitro experiments with various cell types. Iron transferrin preincubated with rat bone marrow cells donates less iron to rat bone marrow cells, Chinese hamster fibroblasts, human fibroblasts and human lymphoblasts than freshly prepared iron transferrin equal in iron and transferrin concentraion. Rat liver parenchymal cells, however, take up more iron from preincubated than from freshly prepared iron transferrin. Obviously, site A not only donates iron preferentially to erythroid cells but also to (rapidly) dividing nonerythroid cells in culture. From experiments with iron transferrin mixtures in which radioiron was present at low or high iron saturation, it could be concluded that rat bone marrow cells take up iron equally well from monoferric as from diferric transferrin. The observed functional heterogeneity could, therefore, not be ascribed to differences between monoferric and diferric transferrin.