Expression of human parathyroid hormone in mammalian cells, Escherichia coli and Saccharomyces cerevisiae.

The entire human parathyroid hormone (hPTH) cDNA gene with its natural signal and pro-region is expressed in transfected mouse mammary tumor cells (C127I cells) and Chinese hamster lung cells (DON cells) under control of the murine metallothioneine-1 promoter in a vector in which replication functions are provided by the entire genome of bovine papilloma virus type I (BPV-1). Authentic hPTH is efficiently produced by the non-endocrine cells and secreted to the growth medium without any abberant processing. Immunoblots from SDS-PAGE gels of concentrated growth medium reveal one band corresponding to intact, undegraded hPTH. Purification by reversed-phase HPLC results in a peptide with an amino acid content and N-terminal sequence identical to hPTH. For comparison, hPTH cDNA with deleted prepro-region is also expressed as secretory proteins in Escherichia coli and in Saccharomyces cerevisiae. In E. coli the vector construct is based on the staphylococcal protein A promoter employing protein A signal sequence. In S. cerevisiae a mating factor alpha expression system containing the factor alpha-signal sequence is employed. The results show that intact hPTH is secreted in addition to proteolytically cleaved fragments in both microorganisms. Thus, the signal sequences promote efficient secretion, and correct N-terminal processing of hPTH in both mammalian, bacterial and yeast cells. However, the folding characteristics of hPTH make it susceptible to internal proteolytical cleavage which appears to be species specific in yeast and E. coli.

Replication of bovine papillomavirus vectors in murine cells.

Varying capacities for autonomous replication have been obtained with bovine papillomavirus type 1 (BPV-1)-based expression vectors in mouse C127 cells. Both integration of the vector DNA into the genome of the host cell and replication as monomeric extrachromosomal elements have been observed. In this study, we have examined what features of BPV-1 vectors influence their replication potential. Transfection of the entire BPV-1 genome into C127 cells resulted in the replication of extrachromosomal monomeric BPV-1 elements. The same result was obtained when a plasmid sequence was inserted into the BPV-1 DNA. However, introduction of foreign, transcriptionally active units resulted in chromosomal integration of the expression vectors. This result was obtained with clones isolated by co-transfection followed by neomycin selection, as well as with clones isolated from neoplastic foci. Supertransfection of a BPV-1-based expression vector into cells harbouring unintegrated replicating BPV-1 genomes resulted in integration of the vector DNA, whereas replication of the resident BPV-1 genomes was unaffected. Extrachromosomal replication of such a vector was achieved when the enhancer and promoter region of the foreign gene were deleted.