IHF stimulation of lambda cII gene expression is inhibited by the E. coli NusA protein

The effects of E. coli proteins Integrative Host Factor (IHF) and NusA on the regulation of lambda cII gene expression are presented. As reported previously (Peacock et al. [1984] Proc. Natl. Acad. Sci. USA 81, 6009-6013), IHF stimulates the DNA-directed in vitro synthesis of cII protein or its first dipeptide, fMet-Val. Whereas NusA, by itself, has no effect on cII expression, the presence of NusA inhibits the IHF-mediated stimulation of cII synthesis.     

Purified bacteriophage lambda O protein binds to four repeating sequences at the lambda replication origin.

The bacteriophage lambda O protein is needed for initiation of lambda DNA replication. Several lines of evidence suggest that initiation requires that this protein interacts with a specific sequence called ori (for origin) in lambda DNA. We have purified this protein to near homogeneity and studied the protection against nuclease cleavage of the origin DNA sequences. Our data demonstrate that the O protein binds within an interval of about 95 base pairs (bp), which contains four tandemly arranged 19bp repeating sequences, ATCCCTCAAAACGA (G)GG GAT(A). At a low concentration of O protein, the inner two repeats are primarily covered, while binding to the outer two repeats requires a high concentration of O protein. From the molecular size of O protein (32,000 daltons), and the internal symmetry in each 19bp repeat, we inferred that the O protein may bind in dimeric form, and that the 95bp region may be filled only when four such dimers have bound. This interaction is discussed in connection with the "activation" of the ori by O protein leading to initiation of DNA synthesis.     

A novel protein binds a key origin sequence to block replication of an E. coli minichromosome

A sequence of three tandem repeats of a 13-mer in the replication origin (oriC) of E. coli is the highly conserved site of opening of the duplex for initiation of DNA synthesis. A protein that binds this sequence has been discovered in E. coli and purified to homogeneity. This novel 33 kd polypeptide behaves as a dimer. Binding to the 13-mers is specific and limited to this region. At a ratio of 10-20 monomers per oriC plasmid, the binding blocks initiation by preventing the opening of the 13-mer region by dnaA protein. Once the 13-mers are opened by dnaA protein action, the 33 kd protein is without effect on the subsequent stages of replication. The specificity of binding and profound inhibitory effect suggest a regulatory role for this protein at an early stage of chromosome initiation.     

The Escherichia coli Fis protein stimulates bacteriophage lambda integrative recombination in vitro

The Escherichia coli nucleoid-associated protein Fis was previously shown to be involved in bacteriophage lambda site-specific recombination in vivo, enhancing the levels of both integrative recombination and excisive recombination. While purified Fis protein was shown to stimulate in vitro excision, Fis appeared to have no effect on in vitro integration reactions even though a 15-fold drop in lysogenization frequency had previously been observed in fis mutants. We demonstrate here that E. coli Fis protein does stimulate integrative lambda recombination in vitro but only under specific conditions which likely mimic natural in vivo recombination more closely than the standard conditions used in vitro. In the presence of suboptimal concentrations of Int protein, Fis stimulates the rate of integrative recombination significantly. In addition, Fis enhances the recombination of substrates with nonstandard topologies which may be more relevant to the process of in vivo phage lambda recombination. These data support the hypothesis that Fis may play an essential role in lambda recombination in the host cell.     

Multiply branched replicative intermediates in E. coli and bacteriophage lambda

Summary Multiple branched DNA fragments present in a fast sedimenting complex comprising a minute fraction of the E. coli genome have been isolated. Similar structures were also observed among bacteriophage DNA replicative intermediates after infection of synchronized E. coli cells. These structures were found to be associated with the amino acid and thymidine starvation steps required for synchronization and originate either by initiation from secondary sites or by snap-back of daughter strands containing substantial single stranded regions in the vicinity of the growing point.     

Degradation in vitro of bacteriophage lambda N protein by Lon protease from Escherichia coli

Lon protease from Escherichia coli degraded lambda N protein in a reaction mixture consisting of the two homogeneous proteins, ATP, and MgCl2 in 50 mM Tris, Ph 8.0. Genetic and biochemical data had previously indicated that N protein is a substrate for Lon protease in vivo (Gottesman, S., Gottesman, M., Shaw, J. E., and Pearson, M. L. (1981) Cell 24, 225-233). Under conditions used for N protein degradation, several lambda and E. coli proteins, including native proteins, oxidatively modified proteins, and cloned fragments of native proteins, were not degraded by Lon protease. Degradation of N protein occurred with catalytic amounts of Lon protease and required the presence of ATP or an analog of ATP. This is the first demonstration of the selective degradation of a physiological substrate by Lon protease in vitro. The turnover number for N protein degradation was approximately 60 +/- 10 min-1 at pH 8.0 in 50 mM Tris/HCl, 25 mM MgCl2 and 4 mM ATP. By comparison the turnover number for oxidized insulin B chain was 20 min-1 under these conditions. Kinetic studies suggest that N protein (S0.5 = 13 +/- 5 microM) is intermediate between oxidized insulin B chain (S0.5 = 160 +/- 10 microM) and methylated casein (S0.5 = 2.5 +/- 1 microM) in affinity for Lon protease. N protein was extensively degraded by Lon protease with an average of approximately six bonds cleaved per molecule. In N protein, as well as in oxidized insulin B chain and glucagon, Lon protease preferentially cut at bonds at which the carboxy group was contributed by an amino acid with an aliphatic side chain (leucine or alanine). However, not all such bonds of the substrates were cleaved, indicating that sequence or conformational determinants beyond the cleavage site affect the ability of Lon protease to degrade a protein.     

Protein degradation in E. coli: the lon mutation and bacteriophage lambda N and cII protein stability

The Ion gene of E. coli controls the stability of two bacteriophage lambda proteins. The functional half-life of the phage N gene product, measured by complementation, is increased about 5-fold in Ion mutant strains, from 2 min to 10 min. The chemical half-life of N protein, determined by its disappearance on polyacrylamide gels following pulse-chase labeling, increases about three-fold in Ion cells. In contrast to its effect on the N protein, the Ion mutation produces a 50% decrease in the chemical half-life of cII protein. The decay rate of many other phage proteins, including the unstable gene O product, remains unaffected by a host Ion defect. A Ion mutation alters lambda physiology in two ways. First, upon infection, the phage enters the lytic pathway predominantly. This may result from the deficiency of cII protein caused by its decreased stability, since cII product is required for establishment of lysogeny. Second, brief thermal induction of a Ion (lambda c1857) lysogen leads irreversibly to lysis; repression cannot be restablished and the treated cells are committed to forming infective centers. Although N product is normally required for rapid commitment, Ion lysogens become committed more rapidly than Ion+ lysogens, even in the absence of N function. These results identify for the first time native proteins whose stability is affected by the Lon proteolytic pathway. They also indicate that the Lon system may be important in regulating gene expression in E. coli.     

A secondary attachment site for bacteriophage lambda in trpC of E. coli.

We have determined the nucleotide sequence of a secondary lambda attachment site in trpC. Direct sequence analysis of lambdatrp transducing phage DNA fragments carrying the two prophage attachment sites reveals a 6 nucleotide homology in the crossover region which is a subset of the 15 nucleotide core sequence in the primary lambda attachment site: GCTTTTTTATACTAA. This 6 nucleotide sequence is also present in the intact trpC genome at the attachment site, as shown by analysis of trpC mRNA spanning this region.     

P. mirabilis RecA protein catalyses cleavage of E. coli LexA protein and the lambda repressor in vitro

Summary The cloned recA ⁺ gene of Proteus mirabilis substitutes for a defective RecA protein in Escherichia coli recA ^– mutants, and restores recombination, repair and phage induction functions to near normal levels. In a previous report, we described the purification and charactrisation of the recombination activities of the P. mirabilis RecA protein (West et al. 1983b). In this paper, we show that the purified protein catalyses the cleavage of both the Escherichia coli LexA protein and the bacteriophage lambda repressor in vitro. These results provide a direct biochemical basis for the interspecies complementation observed in vivo and suggest that P. mirabilis has an SOS regulatory network similar to that of E. coli.     

Terminase host factor: a histone-like E. coli protein which can bind to the cos region of bacteriophage lambda DNA.

Terminase Host Factor (THF), an E. coli protein capable of fulfilling the host factor requirement for in vitro bacteriophage lambda terminase activity, displays properties characteristic of the prokaryotic type II DNA-binding or "histone-like" proteins. It is a 22 K basic, heat- and acid-stable protein which binds non-specifically to various DNAs. Conditions can be established, however, where THF binds preferentially to the cohesive end site (cos) of lambda DNA forming several distinct complexes as visualized by band retardation in polyacrylamide gels. DNase I footprinting reveals that THF can protect several regions of the top strand on the right side (+) of cos but does not bind as well to the left side (-). The binding regions are separated either by unprotected or by DNase I- hypersensitive bases. Under the conditions used in these experiments, DNA which does not contain cos lambda sequences does not show this pattern of protection. Several repeated motifs in the cos lambda nucleotide sequence may represent a consensus sequence for THF interaction. THF may be similar to other "histone-like" proteins which display both non-specific and selective DNA-binding capacities.