Gene fusion vectors based on the gene for staphylococcal protein A

Two plasmid vectors, containing the gene coding for staphylococcal protein A and adapted for gene fusion, have been constructed. These vectors will allow fusion of any gene to the protein A gene, thus giving hybrid proteins which can be purified, in a one-step procedure, by IgG affinity chromatography. As an example of the practical use of such vectors, the protein A gene has been fused to the lacZ gene of Escherichia coli. E. coli strains containing such plasmids produce hybrid proteins with both IgG binding and β-galactosidase activities. The hybrid protein(s) can be immobilized on IgG-Sepharose by its protein A moiety with high efficiency without losing its enzymatic activity and they can be eluted from the column by competitive elution with pure protein A. The fused protein(s) also binds to IgG-coated microtiter wells which means that the in vivo product can be used as an enzyme conjugate in ELISA tests.     

The aconitase C-terminal domain is an independent dual targeting element

The tricarboxylic acid cycle enzyme aconitase in yeast is a single translation product, which is dual targeted and distributed between the mitochondria and the cytosol by a unique mechanism involving reverse translocation. There is limited understanding regarding the precise mechanism of reverse translocation across the mitochondrial membranes. Here, we examined the contribution of the mature part of aconitase to its dual targeting. We created a set of aconitase mutants harboring two kinds of alterations: (1) point mutations or very small deletions in conserved sites and (2) systematic large deletions. These mutants were screened for their localization by a α-complementation assay, which revealed that the aconitase fourth domain that is at the C-terminus (amino acids 517-778) is required for aconitase distribution. Moreover, fusion of this C-terminal domain to mitochondria-targeted passenger proteins such as dihydrofolate reductase and orotidine-5′-phosphate decarboxylase, conferred dual localization on them. These results indicate that the aconitase C-terminal domain is both necessary and sufficient for dual targeting, thereby functioning as an “independent signal”. In addition, the same C-terminal domain was shown to be necessary for aconitase efficient posttranslational import into mitochondria.     

Asp-to-Asn Substitution at the First Position of the DxD TOPRIM Motif of Recombinant Bacterial Topoisomerase I Is Extremely Lethal to E. coli

The TOPRIM domain found in many nucleotidyl transferases contains a DxD motif involved in magnesium ion coordination for catalysis. Medium- to high-copy-number plasmid clones of Yersinia pestis topoisomerase I (YpTOP) with Asp-to-Asn substitution at the first aspartate residue (D117N) of this motif could not be generated in Escherichia coli without second-site mutation even when expression was under the control of the tightly regulated BAD promoter and suppressed by 2% glucose in the medium. Arabinose induction of a single-copy YpTOP-D117N mutant gene integrated into the chromosome resulted in ∼ 10⁵-fold of cell killing in 2.5 h. Attempt to induce expression of the corresponding E. coli topoisomerase I mutant (EcTOP-D111N) encoded on a high-copy-number plasmid resulted in either loss of viability or reversion of the clone to wild type. High-copy-number plasmid clones of YpTOP-D119N and EcTOP-D113N with the Asn substitution at the second Asp of the TOPRIM motif could be stably maintained, but overexpression also decreased cell viability significantly. The Asp-to-Asn substitutions at these TOPRIM residues can selectively decrease Mg²⁺ binding affinity with minimal disruption of the active-site geometry, leading to trapping of the covalent complex with cleaved DNA and causing bacterial cell death. The extreme sensitivity of the first TOPRIM position suggested that this might be a useful site for binding of small molecules that could act as topoisomerase poisons.     

Escherichia coli plasmid vectors containing synthetic translational initiation sequences and ribosome binding sites fused with the lacZ gene

The construction of a series of Escherichia coli plasmid vectors suitable for assaying the effects of gene control signals fused with the E. coli lacZ gene is reported. A synthetic deoxyoligonucleotide dodecamer 5'-CATGAATTCATG GTACTTAAGTAC-5' containing two translation initiation codons (ATG) separated by an EcoRI site was ligated with a lacZ gene derivative which lacks the codons for the first eight amino acids in plasmid pMC1403 (Casadaban et al., 1980). Two ribosome-binding sequences were synthesised and inserted into the EcoRI site before an ATG, and the effects of these sequences on lacZ gene expression in vivo measured by assaying beta-galactosidase activity. The E. coli ribosomal RNA gene (rrnB) promoter, the tetracycline resistance gene promoter, and a lambda phage promoter were cloned using these plasmids. The plasmids are 9.9 kb in size, have ampicillin resistance as a selectable marker and are generally useful for the detection and in vivo assay of gene control regions.     

Cloning SV40 HindIII restriction fragments into M13 bacteriophage

The six HindIII restriction fragments of the simian virus 40 (SV40) genome were cloned into the bacteriophage M13mp5 vector to generate strand-specific hybridization probes.     

Region- and strand-specific mutagensis of a recombinant plasmid

Techniques were developed to mutagenize a single DNA strand in a specific region of the tetracycline-resistance (tetr) gene of the plasmid pKB280 that also carries the lambda repressor gene. Separate annealings of complementary single strands gave two isomeric, circular plasmids containing a 275-nucleotide, single-stranded region (gap) in the tetr gene. One of the isomeric, gapped plasmids was mutagenized specifically with sodium bisulfite such that an estimated 98% of the molecules had suffered at least one C to U conversion in the gap. The mutagenized gap was filled in with DNA polymerase. These molecules transformed Escherichia coli strain MM294 to lambda-immunity with the same frequency as unmutagenized, gap-filled pKB280. Of the lambda-immune transformants, 32% were Tcr and 68% were Tcs. Restriction analysis of plasmids from some Tcs transformants showed losses of restriction sites within the gap and at the gap termini, but none outside the gap. No deletions were detected.