Overproduction of E. coli xylose isomerase

Summary A promoterles DNA fragment containing theE. coli xylose isomerase gene and its ribosome binding site was ligated into a plasmid downstream from the strong P_L promoter. The plasmid was then used to transformE. coli strains containing a temperature-sensitive repressor (cI857). The transformants overproduced xylose isomerase when the repressor was thermally inactivated.     

The OR control system of bacteriophage lambda. A physical-chemical model for gene regulation

A quantitative model has been developed for processes in the bacteriophage lambda that control the switchover from lysogenic to lytic modes of growth. These processes include the interactions of cI repressor and cro proteins at the three DNA sites of the right operator, OR, the binding of RNA polymerase at promoters PR and PRM, the synthesis of cI repressor and cro proteins, and the degradative action of recA during induction of lysis. The model is comprised of two major physical-chemical components: a statistical thermodynamic theory for relative probabilities of the various molecular configurations of the control system; and a kinetic model for the coupling of these probabilities to functional events, including synthesis of regulatory proteins cI and cro. Using independently evaluated interaction constants and rate parameters, the model was found capable of predicting essential physiological characteristics of the system over an extended time. Sufficiency of the model to predict known physiological properties lends credence to the physical-chemical assumptions used in its construction. Several major physiological characteristics were found to arise as "system properties" through the non-linear, time-dependent, feedback-modulated combinations of molecular interactions prescribed by the model. These include: maintenance of the lysogenic state in the absence of recA-mediated cI repressor degradation; induction of lysis and the phenomenon of subinduction; and autogenous negative control of cro. We have used the model to determine the roles, within the composite system, of several key molecular processes previously characterized by studies in vitro. These include: co-operativity in cI repressor binding to DNA; interactions between repressors and RNA polymerase (positive control); and the monomer-dimer association of cI repressor molecules. A major role of cI repressor co-operativity is found to be that of guaranteeing stability of the lysogenic state against minor changes in cI repressor levels within the cell. The role of positive control seems to be that of providing for a peaked, rather than monotonic, dependence of PRM activity on cI repressor level, while permitting PR activity to be a step function. The model correlates an immense body of studies in vivo and in vitro, and it makes testable predictions about molecular phenomena as well as physiological characteristics of bacteriophage lambda. The approach developed in this study can be extended to include more features of the lambda system and to treat other systems of gene regulation.     

A new expression vector for the production of fused proteins in Escherichia coli

Summary The construction of a new expression vector for fused proteins production in Escherichia coli is reported. This new vehicle uses the trp promoter-operator control region for the high level expression of a DNA fragment that codes for the amino terminal fragment of the cI repressor protein. This truncated polypeptide is accumulated as inclusion bodies that are easily purified. To probe the benefits of the system, synthetic DNA that codes for the human insulin B chain, was cloned at the end of the DNA coding region for the cI truncated peptide. The hybrid peptide thus produced after induction, allowed an easy and reproducible purification of active insulin B chain.Abbreviation Ap ampicillin - bp base pairs - kD kilodaltons - Mr migration rate - PAGE polyacrylamide gel electrophoresis - Tc tetracycline - trp tryptophan     

Altered temperature induction sensitivity of the lambda pR/cI857 system for controlled gene E expression in Escherichia coli

Cell lysis of Gram-negative bacteria can be efficiently achieved by expression of the cloned lysis gene E of bacteriophage PhiX174. Gene E expression is tightly controlled by the rightward lambda pR promoter and the temperature-sensitive repressor cI857 on lysis plasmid pAW12. The resulting empty bacterial cell envelopes, called bacterial ghosts, are currently under investigation as candidate vaccines. Expression of gene E is stringently repressed at temperatures up to 30 degrees C, whereas gene E expression, and thus cell lysis, is induced at temperatures higher than 30 degrees C due to thermal inactivation of the cI857 repressor. As a consequence, the production of ghosts requires that bacteria have to be grown at 28 degrees C before the lysis process is induced. In order to reflect the growth temperature of pathogenic bacteria in vivo, it seemed favorable to extend the heat stability of the lambda pR promoter/cI857 repressor system, allowing pathogens to grow at 37 degrees C before induction of lysis. In this study we describe a mutation in the lambda pR promoter, which allows stringent repression of gene E expression at temperatures up to 36 degrees C, but still permits induction of cell lysis at 42 degrees C.     

Lactococcus lactis lytic bacteriophages of the P335 group are inhibited by overexpression of a truncated CI repressor

Phages of the P335 group have recently emerged as important taxa among lactococcal phages that disrupt dairy fermentations. DNA sequencing has revealed extensive homologies between the lytic and temperate phages of this group. The P335 lytic phage phi31 encodes a genetic switch region of cI and cro homologs but lacks the phage attachment site and integrase necessary to establish lysogeny. When the putative cI repressor gene of phage phi31 was subcloned into the medium-copy-number vector pAK80, no superinfection immunity was conferred to the host, Lactococcus lactis subsp. lactis NCK203, indicating that the wild-type CI repressor was dysfunctional. Attempts to clone the full-length cI gene in Lactococcus in the high-copy-number shuttle vector pTRKH2 were unsuccessful. The single clone that was recovered harbored an ochre mutation in the cI gene after the first 128 amino acids of the predicted 180-amino-acid protein. In the presence of the truncated CI construct, pTRKH2::CI-per1, phage phi31 was inhibited to an efficiency of plaquing (EOP) of 10(-6) in NCK203. A pTRKH2 subclone which lacked the DNA downstream of the ochre mutation, pTRKH2::CI-per2, confirmed the phenotype and further reduced the phi31 EOP to <10(-7). Phage phi31 mutants, partially resistant to CI-per, were isolated and showed changes in two of three putative operator sites for CI and Cro binding. Both the wild-type and truncated CI proteins bound the two wild-type operators in gel mobility shift experiments, but the mutated operators were not bound by the truncated CI. Twelve of 16 lytic P335 group phages failed to form plaques on L. lactis harboring pTRKH2::CI-per2, while 4 phages formed plaques at normal efficiencies. Comparisons of amino acid and DNA level homologies with other lactococcal temperate phage repressors suggest that evolutionary events may have led to inactivation of the phi31 CI repressor. This study demonstrated that a number of different P335 phages, lytic for L. lactis NCK203, have a common operator region which can be targeted by a truncated derivative of a dysfunctional CI repressor.     

Stimulation of RecA-mediated cleavage of phage phi 80 cI repressor by deoxydinucleotides

The presence of either deoxyguanylyl-(3'----5')-deoxyguanosine (d(G-G] or deoxyadenylyl-(3'----5')-deoxyguanosine (d(A-G] greatly stimulates cleavage of the phage phi 80 cI repressor mediated by the Escherichia coli RecA protein in vitro. No other deoxydinucleoside monophosphate or riboguanylyl-(3'----5')-guanosine (r(G-G] affects the cleavage reaction. Neither the cleavage site of the phi 80 cI repressor nor the requirement for single-stranded DNA and ATP for cleavage is altered by d(G-G). Photoaffinity labeling experiments with 32P-labeled 5'-phosphoryl deoxyguanylyl deoxyguanosine (pd(G-G], which also stimulates cleavage, show that pd(G-G) bound to the repressor under the conditions in which the repressor is cleaved by RecA protein. The binding increases the affinity of the repressor for RecA protein and thus greatly stimulates repressor cleavage. The cleavage reactions of LexA and lambda cI repressors by RecA protein are not affected by d(G-G).     

Bacteriophage lambda mutants (lambdatp) that overproduce repressor.

Lambda tp mutants, selected for their ability to form turbid plaques on lon hosts, overproduce repressor. The tp1 and tp2 mutations have been located within (or adjacent to) the cIII gene. The tp1 mutation reduced late gene expression, as measured by endolysin synthesis (in the absence of functional cI repressor) and progeny phage yield. The tp4 mutation was mapped in the cY-cII region, and complementation tests indicated that tp4 affects the diffusible product of the cII gene. The tp4 mutation also reduced progeny production, but did not markedly affect endolysin synthesis.     

Kinetics of bacteriophage lambda repressor synthesis directed by the PRE promoter: influence of temperature, multiplicity of infection, and mutation of PRM or the cro gene

Summary Expression of the P _RE (establishment) pathway for repressor synthesis is regulated both by phage-specific genetic elements and by physiological conditions. Here we describe the effects of temperature, multiplicity of infection, mutations in the cro gene, and a mutation in P _RM on P _RE-directed repressor synthesis. As Reichardt (1975a) has shown, repressor synthesis begins 5–15 min after infection by wildtype phage, and is shut off at 20–30 min after infection, depending on the temperature. At 43°, synthesis starts sooner, shuts off earlier, and leads to lower repressor levels than are attained at lower temperatures. Experiments with the temperature sensitive mutant crots20 demonstrate that, as had been shown previously in experiments at 30° and 37° C, cro protein is responsible for the shut-off of repressor synthesis at 43°. In addition to the effects of temperature, the kinetics of repressor synthesis are strongly affected by multiplicity of infection (moi). At mois greater than 10, repressor synthesis after infection by wildtype at 30° is dramatically inhibited. Unexpectedly, the P _RM mutation prm116, under certain conditions, can alleviate both cro-mediated shutoff and the inhibition of P _RE-directed repressor synthesis at high moi. These effects of prm116 are observed only at low temperature (30°–32° C) and at mois of about 6–10 or greater; they also appear to be cis-specific. Possible mechanisms for the effects of the prm116 mutation are discussed. Finally, these studies demonstrate that crots20, which was isolated as a temperature-sensitive lethal mutation in the cro gene (Herskowitz, unpublished), is temperature-sensitive with respect to the ability to shutoff P _RE-directed repressor synthesis; however, even at low temperature (30° C), the crots20 gene product is only partially active.     

Construction of a thermo-sensitive pRI857 vector for efficient DNA capturing in <Emphasis Type="Italic">Escherichia coli</Emphasis>

Objectives

To establish a positive cloning system with a zero background for high-throughput DNA cloning purpose.

Results

The cloning vector, pRI857, and the genomic-library construction vector, pRI857-BAC, were constructed based on the mechanism of expression of the thermo-sensitive cI857 repressor gene that can stringently repress the P_R promoter and kanamycin resistance gene (P_R-kan ^R ) at 30 °C, but have no effect on P_R-kan ^R gene at 37 °C or at higher temperatures. When the pRI857 vectors were transformed into E. coli with or without a target foreign DNA fragment inserted at the BfrBI site of the cI857 gene, only colonies with the foreign DNA fragment survive. We extended this method to construct a pRI857-BAC vector for genomic library cloning which displays an efficiency of ~10⁷ cfu per µg of genomic DNA, with no empty vectors detected.

Conclusions

Cloning by indirect activation of resistance marker gene represents a novel DNA-capturing system, which can be widely applied for high-throughput DNA cloning.

     

A novel bacterial vector system for monitoring protein-protein interactions in the cAMP-dependent protein kinase complex

A bacterial expression vector is described for investigation of protein-protein interactions. Important features of the vector include partition of the cI repressor of bacteriophage λ into two functional domains separated by a multicloning site, and low level auto-regulated expression of human genes as C-terminal fusions to the DNA-binding domain of cI. Two different reporter systems have been employed; expression of either a suppressor tRNA or the alkaline phosphatase gene is dependent in both cases on the extent of repression of the major leftward promoter of lambda (λP_L). The cAMP-dependent protein kinase (PKA) has been used as a model protein complex because both homodimer and heterodimer interactions are known to occur and because cAMP acts as a modulator of these interactions. It has been shown that the product of the repressor gene with newly incorporated expressed polylinker restriction sites still functions as a repressor. Substitution of the dimerisation domain of the cI repressor with the regulatory subunit of PKA does not diminish the ability of a cI fusion protein to repress expression of the reporter gene from λP_L, indicating that the regulatory subunit of PKA dimerises the fusion protein in the Escherichia coli cytoplasm. Substitution instead with the catalytic subunit of PKA destroys the repression ability of cI, which is partially restored by separate expression of the regulatory subunit within the same cell. Complete restoration is achieved using a host E. coli strain which has lost its ability to synthesise cAMP and again this can be reversed by the addition of exogenous cAMP to these cells. Human PKA has been reconstituted in the E. coli cytoplasm, where all subunit interactions appear functional and respond as expected to the allosteric modulator cAMP.     

Control of lysogeny and a genetic map of the temperate phage SM of Pseudomonas aeruginosa

76 mutants with impaired ability to lysogenize host cells were isolated in SM phage after mutagenesis using several chemical mutagens. By means of complementation test, these mutants were distributed into two groups, cI and cII. The mutants of the cI group were similar phenotypically to the cI mutants of phage lambda defective in synthesis of repressor. The mutants of the cII group establish and support the lysogenic state in infected cells with very low frequency. Temperature-sensitive mutants belonging to 13 complementation groups and nonlysogenizing mutants of the cI and cII groups were used in genetic mapping of SM phage. Mutual positions of markers and relative distances between them were determined by the method of two-factorial crosses. The greatest distance equal to 20 units of recombination was determined between ts 88 marker and one of early genes marked with ts 105 mutation. The genes cI and cII are closely linked to each other and also to ts 105 marker and are situated at one end of the genetic map.     

Physical mapping of the immunity region of phage phi 80

Mapping of the sites of cleavage of five restriction endonucleases (BglI, BglII, EcoRV, KpnI and PvuII) in the immunity region of bacteriophage phi 80 DNA is described. The order of the 27 restriction sites was established. This helped to localize the phi 80 cI gene within the 640 bp fragment of the immunity region. Recombinant plasmids carrying phi 80 "kil" function were constructed. The function is suppressed by the cI-coded repressor. The deletion AB43 which is present in the phi 80 vir mutant is located within the phi 80 DNA fragment carrying the cI gene.