The fate of phage lambda DNA in lambda-infected minicells.

The fate of phage lambda DNA in lambda-infected Escherichia coli minicells harboring the plasmid ColE1, and in plasmid-free minicells, were studied. Binding of lambda DNA to the minicell membrane, and formation of the supercoiled covalently-closed circular structure has been demonstrated. Phage infection abolishes plasmid DNA synthesis. Only a very slight, non-replicative lambda DNA synthesis occurs, soon after infection. This synthesis is associated with fragments of lambda DNA arising during, or soon after its penetration.     

Expression of the replication region of phage lambda DNA cloned into pBR322 in E. coli minicells

Replication region of bacteriophage lambda DNA was cloned into pBR322 plasmid by the use of two restriction enzymes--PstI and HindIII. The restriction analysis of four obtained plasmids revealed that lambda DNA was cloned in both orientations. Recombinant plasmids were transferred to the minicell-producing strain of E. coli and synthesis of the plasmid-mediated proteins was analysed by polyacrylamide-gel electrophoresis. All four recombinant plasmids produced lambda DNA replication proteins pO and pP as well as some proteins specific for pBR322. The orientation of cloned fragment did not affect the synthesis of lambda DNA replication proteins.     

Protein expression in E. coli minicells by recombinant plasmids.

The polypeptides synthesized in E. coli minicells from recombinant plasmids containing DNA fragments from cauliflower mosaic virus, Drosophila melanogaster, and mouse mitochondria were examined. Molecularly cloned fragments of cauliflower mosaic virus DNA directed the synthesis of high levels of three polypeptides, which were synthesized entirely from within the cloned virus DNA fragments independent of their insertion into the plasmid vehicles. Several fragments of D. melanogaster DNA were capable of initiating polypeptide synthesis; however, termination of these polypeptides was dependent upon the insertion into the plasmid vehicle. The majority of D. melanogaster DNA fragments examined did not direct the detectable synthesis of any polypeptides. Insertion of DNA into the Eco RI site of ColE1 and pSC101 plasmids resulted in the altered expression of plasmid-encoded polypeptides. In the case of ColE1, this site of insertion lies within the colicin E1 structural gene, and insertion of foreign DNA into the site results in the synthesis of an inactive truncated colicin E1 molecule. It is probable that the Eco RI site in pSC101 lies within the structural gene for a polypeptide involved in tetracycline resistance, and insertion of DNA into this site may also result in the synthesis of a truncated or elongated polypeptide.     

Error propagation in E. coli protein synthesis

A new approach to the error catastrophe theory, proposed by Leslie Orgel, is presented here. Our model is a development of previous models, but differs in several respects: the overall activity is assumed to be dependent on the error level, the effect of errors in the translating system, giving rise to additional errors in the succeeding generation of products, is explicitly included as a special term in our model, and scavenging enzymes are assumed to break down and eliminate products with a loose structure. Their efficiency is dependent on the error level. The model also takes into account the dilution of incorrect ribosomes and enzymes, and is described by a time-dependence in terms of ribosome/enzyme generations. The model and the contribution to the time development are discussed in the light of experiments on E. coli treated with streptomycin.     

Stringent control of protein synthesis in E. coli

The effect of ppGpp on the rate of protein synthesis has been determined in vivo. When the stringent response is triggered and then reversed in isogenic strains carrying either spoT^? or spoT⁺, the mutants lower their elevated ppGpp only slowly, whereas wild type cells do so rapidly. Protein synthesis resumes only after a lag in spoT^? cells but almost immediately in spoT⁺ cells. In spoT^?rel^? double mutants, ppGpp does not accumulate under these conditions and protein synthesis resumes immediately. Inhibition of protein synthesis in spoT^?rel⁺ cells therefore appears to be due to elevation of ppGpp levels and not to any other effect of the spoT^? mutation.     

Protein synthesis results in guanosine-5'-diphosphate-3'-diphosphate synthesis in Escherichia coli minicells.

Minicells of Escherichia coli DS410 synthesized guanosine-5'-diphosphate-3'-diphosphate and guanosine-5'-triphosphate-3'-diphosphate when synthesizing proteins in response to phage T7 infection. The guanosine-5'-diphosphate-3'-diphosphate synthesis was found to be relA+ dependent and inhibited by chloramphenicol.     

Nucleoside triphosphate pools in minicells of Escherichia coli.

The nucleoside triphosphate pools of Escherichia coli minicells are different from those in parental cells. The growth phase in which minicells accumulate significantly affects the pool sizes.     

Escherichia coli dnaJ- and dnaK-gene products: synthesis in minicells and membrane-affinity

Escherichia coli dnaJ- and dnaK-gene products have been identified in a system of minicells infected with the appropriate transducing lambda phages. The molecular weights of these polypeptides in dodecyl sulphate/acrylamide electrophoresis amounted to 39,000 and 77,000, respectively. Equilibrium sedimentation of minicell lysates in metrizamide density gradients has revealed that both these host proteins, indispensable for lambda DNA replication, are membrane-bound.     

Hollow-fiber membrane bioreactors using immobilized E. coli for protein synthesis

Actively growing Escherichia coli C600(pBR322), immobilized within the macroporous matrix of asymmetric-wall hollow-fiber membranes, has been propagated to extremely high densities, typically more than 10(12) cells/mL of accessible void volume, in some regions cells accounting for nearly 100% of the available macrovoid volume forming a tissue-like mass. Production rates of beta-lactamase, an enzyme used as an indicator of the culture's biosynthetic potential, remained at high and relatively stable levels for more than three weeks of continuous operation, and effluent supernatant enzyme activities attained 25% of the accumulated level measured in a 24-h shaker-flask culture. Based on the accessible void volume within the fiber wall, the beta-lactamase productivity was independent of the specific asymmetric membrane used. On a per cell basis, however, cells cultured using hollow-fiber membranes were only 10% as productive as those in the shaker-flask culture, possibly due to the high packing density or culture aging. By contrast, the hollow-fiber bioreactor was 100 times more productive than the shaker-flask culture on a reactor-volume basis, primarily as a consequence of the high cell densities. Reactor productivity was dependent on the number of cells in the reactor, suggesting that reactor performance was kinetically controlled and not mass transport limited.     

Mucopeptide biosynthesis by minicells of Escherichia coli.

Minicells produced by Escherichia coli chi925 incorporated amino acids and N-acetyl-d-glucosamine into mucopeptide.