Escherichia coli ghost production by expression of lysis gene E and Staphylococcal nuclease.
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The production of bacterial ghosts from Escherichia coli is accomplished by the controlled expression of phage phiX174 lysis gene E and, in contrast to other gram-negative bacterial species, is accompanied by the rare detection of nonlysed, reproductive cells within the ghost preparation. To overcome this problem, the expression of a secondary killing gene was suggested to give rise to the complete genetic inactivation of the bacterial samples. The expression of staphylococcal nuclease A in E. coli resulted in intracellular accumulation of the protein and degradation of the host DNA into fragments shorter than 100 bp. Two expression systems for the nuclease are presented and were combined with the protein E-mediated lysis system. Under optimized conditions for the coexpression of gene E and the staphylococcal nuclease, the concentration of viable cells fell below the lower limit of detection, whereas the rates of ghost formation were not affected. With regard to the absence of reproductive cells from the ghost fractions, the reduction of viability could be determined as being at least 7 to 8 orders of magnitude. The lysis process was characterized by electrophoretic analysis and absolute quantification of the genetic material within the cells and the culture supernatant via real-time PCR. The ongoing degradation of the bacterial nucleic acids resulted in a continuous quantitative clearance of the genetic material associated with the lysing cells until the concentrations fell below the detection limits of either assay. No functional, released genetic units (genes) were detected within the supernatant during the lysis process, including nuclease expression. (+info)
Reorganization of the Mu transpososome active sites during a cooperative transition between DNA cleavage and joining.
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Transposition of mobile genetic elements proceeds through a series of DNA phosphoryl transfer reactions, with multiple reaction steps catalyzed by the same set of active site residues. Mu transposase repeatedly utilizes the same active site DDE residues to cleave and join a single DNA strand at each transposon end to a new, distant DNA location (the target DNA). To better understand how DNA is manipulated within the Mu transposase-DNA complex during recombination, the impact of the DNA immediately adjacent to the Mu DNA ends (the flanking DNA) on the progress of transposition was investigated. We show that, in the absence of the MuB activator, the 3 '-flanking strand can slow one or more steps between DNA cleavage and joining. The presence of this flanking DNA strand in just one active site slows the joining step in both active sites. Further evidence suggests that this slow step is not due to a change in the affinity of the transpososome for the target DNA. Finally, we demonstrate that MuB activates transposition by stimulating the reaction step between cleavage and joining that is otherwise slowed by this flanking DNA strand. Based on these results, we propose that the 3 '-flanking DNA strand must be removed from, or shifted within, both active sites after the cleavage step; this movement is coupled to a conformational change within the transpososome that properly positions the target DNA simultaneously within both active sites and thereby permits joining. (+info)
Generating a synthetic genome by whole genome assembly: phiX174 bacteriophage from synthetic oligonucleotides.
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We have improved upon the methodology and dramatically shortened the time required for accurate assembly of 5- to 6-kb segments of DNA from synthetic oligonucleotides. As a test of this methodology, we have established conditions for the rapid (14-day) assembly of the complete infectious genome of bacteriophage X174 (5386 bp) from a single pool of chemically synthesized oligonucleotides. The procedure involves three key steps: (i). gel purification of pooled oligonucleotides to reduce contamination with molecules of incorrect chain length, (ii). ligation of the oligonucleotides under stringent annealing conditions (55 degrees C) to select against annealing of molecules with incorrect sequences, and (iii). assembly of ligation products into full-length genomes by polymerase cycling assembly, a nonexponential reaction in which each terminal oligonucleotide can be extended only once to produce a full-length molecule. We observed a discrete band of full-length assemblies upon gel analysis of the polymerase cycling assembly product, without any PCR amplification. PCR amplification was then used to obtain larger amounts of pure full-length genomes for circularization and infectivity measurements. The synthetic DNA had a lower infectivity than natural DNA, indicating approximately one lethal error per 500 bp. However, fully infectious X174 virions were recovered after electroporation into Escherichia coli. Sequence analysis of several infectious isolates verified the accuracy of these synthetic genomes. One such isolate had exactly the intended sequence. We propose to assemble larger genomes by joining separately assembled 5- to 6-kb segments; approximately 60 such segments would be required for a minimal cellular genome. (+info)
The three-dimensional structure of frozen-hydrated bacteriophage phi X174.
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The three-dimensional structure of bacteriophage phi X174 (phi X174) was determined to approximately 2.6 nm resolution from images of frozen-hydrated 114 S particles. The outer surface of phi X174 is characterized by several prominent features: (i) 12 mushroom-shaped caps (approximately 7.1 nm wide x 3.8 nm high) are situated at each of the vertices of the icosahedral virion and extend to a maximum radius of 16.8 nm; (ii) a "collar" of density surrounds the base of each apical cap; and (iii) 20 conical protrusions (approximately 2.3 nm high) lie along the three-fold symmetry axes. The caps have a pentagonal morphology composed of five globular "subunits" and appear to be loosely connected to the underlying capsid. The distribution of the four gene products present in virions (60 copies each of gpF, gpG, and gpJ, and 12 copies of gpH), and the single-stranded DNA (ssDNA) genome cannot be directly discerned in the reconstructed density map, although plausible assignments can be made on the basis of solvent-excluded volume estimates and previous biochemical data. Thus, gpG accounts for most of the mass in the caps; gpH, a presumed cap protein, cannot be identified in part due to the symmetry-averaging procedures, but may be partially located within the interior of the capsid; and gpF and gpJ make up the remainder of the capsid. The genome appears to be less densely packaged inside the capsid compared to many dsDNA viruses whose nucleic acid is arranged in a liquid-crystalline state. (+info)
The DNA synthesizing subunit of polymerase-primase from calf thymus.
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The DNA synthesizing subunit (alpha-subunit) of DNA polymerase-alpha from calf thymus was separated from the other three subunits by immunoaffinity chromatography. The enzymatic properties of the alpha-subunit were characterized and compared with those of the four-subunit complex. Free alpha-subunit behaved in many respects like the four-subunit polymerase-primase. It was inhibited by aphidicolin and butylanilino-deoxyATP and catalyzed DNA synthesis on both gapped duplex DNA as well as primed single-stranded DNA with a preference of gapped DNA. The alpha-subunit is a quasi-processive enzyme with a processivity for about 9 nucleotides incorporated per single primer binding event. This is 2-fold lower than the processivity of the four-subunit complex. Despite this moderate processivity, free alpha-subunit was able to synthesize long stretches of DNA on singly primed natural psi X174am16 DNA. The accuracy of DNA synthesis of the free alpha-subunit was determined by using the psi X174am16 reversion assay to be 1 error per 50,000 nucleotides incorporated. An in vitro accuracy of 1 error in 54,000 nucleotides incorporated was measured in parallel for the four-subunit complex. Thus, the smaller subunits do not contribute to the overall accuracy of DNA polymerase-alpha. Consistent with this result is the observation that the polymerase to 3'----5'-exonuclease ratio was less than 1 to 2,500,000. Therefore, there is no evidence for the action of a cryptic proofreading activity with the alpha-subunit of DNA polymerase-alpha of mammalian origin. (+info)
Coordinated leading- and lagging-strand synthesis at the Escherichia coli DNA replication fork. III. A polymerase-primase interaction governs primer size.
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Studies with a rolling-circle DNA replication system reconstituted in vitro with a tailed form II DNA template, the DNA polymerase III holoenzyme (Pol III HE), the Escherichia coli single-stranded DNA binding protein, and the primosome, showed that within the context of a replication fork, the oligoribonucleotide primers that were formed were limited to a length in the range of 9 to 14 nucleotides, regardless of whether they were subsequently elongated by the lagging-strand DNA polymerase. This is in contrast to the 8-60-nucleotide-long primers synthesized by the primosome in the absence of DNA replication on a bacteriophage phi X174 DNA template, although when primer synthesis and DNA replication were catalyzed concurrently in this system, the extent of RNA polymerization decreased. As described in this report, we therefore examined the effect of the DNA Pol III HE on the length of primers synthesized by primase in vitro in the absence of DNA replication. When primer synthesis was catalyzed either: i) by the primosome on a phi X174 DNA template, ii) by primase on naked DNA with the aid of the DnaB protein (general priming), or iii) by primase alone at the bacteriophage G4 origin, the presence of the DNA Pol III HE in the reaction mixtures resulted in a universal reduction in the length of the heterogeneous RNA products to a uniform size of approximately 10 nucleotides. dNTPs were not required, and the addition of dGMP, an inhibitor of the 3'----5' exonuclease of the DNA Pol III HE, did not alter the effect; therefore, neither the 5'----3' DNA polymerase activity nor the 3'----5' exonuclease activity of the DNA Pol III HE was involved. E. coli DNA polymerase I, and the DNA polymerases of bacteriophages T4 and T7 could not substitute for the DNA Pol III HE. The Pol III core plays a crucial role in mediating this effect, although other subunits of the DNA Pol III HE are also required. These observations suggest that the association of primase with the DNA Pol III HE during primer synthesis regulates its catalytic activity and that this regulatory interaction occurs independently of, and prior to, formation of a preinitiation complex of the DNA Pol III HE on the primer terminus. (+info)
Proteolysis of bacteriophage phi X174 prohead accessory protein gpB by Escherichia coli OmpT protease is not essential for phage maturation in vivo.
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To examine whether cleavage of the phi X174 prohead accessory protein, gpB, by the OmpT protease is required for phage development in vivo, a phage mutant lacking the OmpT cleavage site and an Escherichia coli C delta ompT strain were constructed. The results of burst size experiments suggest that neither the cleavage site nor the OmpT protein is required for phi X174 development. (+info)
Functional relationship between the J proteins of bacteriophages phi X174 and G4 during phage morphogenesis.
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The functions of the small DNA-binding protein, gpJ, of bacteriophages phi X174 and G4 were examined by in vivo cross-complementation and sucrose gradient sedimentation. The morphogenetic roles of the two proteins may differ. The phi X174 J protein may be required for the formation or stabilization of the phi X174 prohead. (+info)