Daniel C. Tessier

Enhanced secretion from insect cells of a foreign protein fused to the honeybee melittin signal peptide.

The baculovirus/insect cell system has been remarkably successful in yielding high levels of synthesis of many proteins which have been difficult to synthesize in other host/vector systems. The system is also capable of secreting heterologous proteins, but with generally low efficiency. We have increased the efficiency of secretion of the system by using signal peptides of insect origin to direct the secretion of a foreign protein. The precursor of the plant cysteine protease papain (propapain) has been used as a report enzyme to compare secretion efficiency. Insect cells infected with a baculovirus recombined with the gene encoding propapain fused to the sequence encoding the honeybee melittin signal peptide secreted over five times more papain precursor than the wild-type prepropapain which used the plant signal peptide. Based on these results, we have assembled pVT-Bac, an Autographa californica nuclear polyhedrosis virus transfer vector that may enhance secretion of other foreign proteins from insect cells. The vector incorporates a number of features: phage f1 ori to facilitate site-directed mutagenesis, the strong polyhedrin promoter upstream from the melittin signal peptide-encoding sequence, and eight unique restriction sites to facilitate fusion of heterologous genes.

Ligation of single-stranded oligodeoxyribonucleotides by T4 RNA ligase

Despite its unique ability to ligate single-stranded DNA molecules, T4 RNA ligase has so far seen little use in molecular biology due to long reaction times, modest yields, and apparent inability to promote ligation of long oligodeoxyribonucleotides. We describe here a set of reaction conditions which dramatically shorten the reaction time and give reproducible 40 to 60% ligation of DNA fragments of up to 40 bases in length. These improvements open promising new fields of application to T4 RNA ligase.

Expression in yeast of a cDNA copy of the K2 killer toxin gene.

SummaryA cDNA copy of the M2 dsRNA encoding the K2 killer toxin ofSaccharomyces cerevisiae was expressed in yeast using the yeastADH1 promoter. This construct produced K2-specific killing and immunity functions. Efficient K2-specific killing was dependent on the action of the KEX2 endopeptidase and the KEX1 carboxypeptidase, while K2-specific immunity was independent of these proteases. Comparison of the K2 toxin sequence with that of the K1 toxin sequence shows that although they share a common processing pathway and are both encoded by cytoplasmic dsRNAs of similar basic structure, the two toxins are very different at the primary sequence level. Site-specific mutagenesis of the cDNA gene establishes that one of the two potential KEX2 cleavage sites is critical for toxin action but not for immunity. Immunity was reduced by an insertion of two amino acids in the hydrophobic amino-terminal region which left toxin activity intact, indicating an independence of toxin action and immunity.

The expression in Escherichia coli of a synthetic gene coding for the precursor of papain is prevented by its own putative signal sequence.

A 1048-bp gene coding for prepropapain was assembled from chemically synthesized oligodeoxyribonucleotides and cloned into a variety of Escherichia coli expression plasmids. We observed loss of plasmid when the preproP gene was expressed in E. coli either as the native precursor or fused at the C terminus of the first 592 amino acids (aa) of beta-galactosidase (beta Gal). Deletion of the putative 26-aa signal peptide (pre-region) increased plasmid stability. The level of maintenance for the different plasmid constructs correlated with the level of expression detected by immunoblotting. Constitutive expression of the beta Gal-propapain fusion generated insoluble granules in a protease-deficient E. coli host. The fusion protein was easily purified to near homogeneity by differential solubilization of the granules.

Correlation of co-ordinated amino acid changes at the two-domain interface of cysteine proteases with protein stability

The engineering of a protein containing an alternative local residue packing for a set of side-chains has proven to be a major challenge because compositional, volumetric and steric constraints must be respected. Homologous proteins should provide examples of alternative groups of residues leading to a similar functional result. The functional significance of a pair of co-ordinated changes that are observed in the cysteine proteases family has been investigated by comparing the effect of individual or double changes on secretion, stability and activity of papain. The two changes are not independent. Detrimental effects of single mutations at one of the two positions can be partly suppressed by the co-ordinated mutation that reproduces naturally occurring contacts, indicating that these changes are concerted. Single mutations at the other position produce milder effects, suggesting a pathway for evolution.