Showing papers on "Lambda phage published in 1997"

Proteolysis of the phage lambda CII regulatory protein by FtsH (HflB) of Escherichia coli.

Abstract: Rapid proteolysis plays an important role in regulation of gene expression. Proteolysis of the phage lambda CII transcriptional activator plays a key role in the lysis-lysogeny decision by phage lambda. Here we demonstrate that the E. coli ATP-dependent protease FtsH, the product of the host ftsH/hflB gene, is responsible for the rapid proteolysis of the CII protein. FtsH was found previously to degrade the heat-shock transcription factor sigma32. Proteolysis of sigma32 requires, in vivo, the presence of the DnaK-DnaJ-GrpE chaperone machine. Neither DnaK-DnaJ-GrpE nor GroEL-GroES chaperone machines are required for proteolysis of CII in vivo. Purified FtsH carries out specific ATP-dependent proteolysis of CII in vitro. The degradation of CII is at least 10-fold faster than that of sigma32. Electron microscopy revealed that purified FtsH forms ring-shaped structures with a diameter of 6-7 nm.

The catalytic domain of lambda site-specific recombinase.

Abstract: The Escherichia coli phage lambda integrase protein (Int) belongs to the large Int family of site-specific recombinases. It is a heterobivalent DNA binding protein that makes use of a high energy covalent phosphotyrosine intermediate to catalyze integrative and excisive recombination at specific chromosomal sites (att sites). A 293-amino acid carboxy-terminal fragment of Int (C65) has been cloned, characterized, and used to further dissect the protein. From this we have cloned and characterized a 188-amino acid, protease-resistant, carboxy-terminal fragment (C170) that we believe is the minimal catalytically competent domain of Int. C170 has topoisomerase activity and converts att suicide substrates to the covalent phosphotyrosine complexes characteristic of recombination intermediates. However, it does not show efficient binding to att site DNA in a native gel shift assay. We propose that lambda Int consists of three functional and structural domains: residues 1-64 specify recognition of "arm-type" DNA sequences distant from the region of strand exchange; residues 65-169 contribute to specific recognition of "core-type" sequences at the sites of strand exchange and possibly to protein-protein interactions; and residues 170-356 carry out the chemistry of DNA cleavage and ligation. The finding that the active site nucleophile Tyr-342 is in a uniquely protease-sensitive region complements and reinforces the recently solved C170 crystal structure, which places Tyr-342 at the center of a 17-amino acid flexible loop. It is proposed that C170 is likely to represent a generic Int family domain that thus affords a specific route to studying the chemistry of DNA cleavage and ligation in these recombinases.

Kinetic analysis of the endonuclease activity of phage lambda terminase: assembly of a catalytically competent nicking complex is rate-limiting.

Abstract: The terminase enzyme from bacteriophage λ is responsible for excision of a single genome from a concatameric DNA precursor and its insertion into an empty viral procapsid. The enzyme possesses a site-specific endonuclease activity which is responsible for excision of the viral genome and the formation of the 12 base-pair single-stranded “sticky” ends of mature λ DNA. We have previously reported a kinetic analysis of the endonuclease activity of λ terminase which showed an enzyme concentration-dependent change in the kinetic time course of the reaction [Tomka, M. A., & Catalano, C. E. (1993b) J. Biol. Chem. 268, 3056−3065]. We presented a model which suggested that the rate-limiting step in the nuclease reaction was the assembly of a catalytically competent prenicking complex. Here, we provide additional evidence for a slow assembly step in the nuclease reaction and demonstrate that the observed rate is affected by protein concentration, but not by the length of the DNA substrate. Consistent with our model...

Cloning and characterization of bacteriophage-like DNA from Haemophilus somnus homologous to phages P2 and HP1.

Abstract: In an attempt to identify and characterize components of a heme uptake system of Haemophilus somnus, an Escherichia coli cosmid library of H. somnus genomic DNA was screened for the ability to bind hemin (Hmb+). The Hmb+ phenotype was associated with a 7,814-bp HindIII fragment of H. somnus DNA that was subcloned and sequenced. Thirteen open reading frames (orfs) were identified, all transcribed in one direction, and transposon mutagenesis identified orf7 as the gene associated with the Hmb+ phenotype. Orf7 (178 amino acids) has extensive homology with the lysozymes of bacteriophages P-A2, P21, P22, PZA, phi-29, phi-vML3, T4, or HP1. The orf7 gene complemented the lytic function of the K gene of phage P2 and the R gene of phage lambda. A lysozyme assay using supernatants from whole-cell lysates of E. coli cultures harboring plasmid pRAP501 or pGCH2 (both of which express the orf7 gene product) exhibited significant levels of lysozyme activity. The orf6 gene upstream of orf7 has the dual start motif common to the holins encoded by lambdoid S genes, and the orf6 gene product has significant homology to the holins of phages HP1 and P21. When expressed from a tac promoter, the orf6 gene product caused immediate cell death without lysis, while cultures expressing the orf7 gene product grew at normal rates but lysed immediately after the addition of chloroform. Based on this data, we concluded that the Hmb+ phenotype was an artifact resulting from the expression of cloned lysis genes which were detrimental to the E. coli host. The DNA flanking the cloned lysis genes contains orfs that are similar to structural and DNA packaging genes of phage P2. Polyclonal antiserum against Orf2, which is homologous to the major capsid precursor protein (gpN) of phage P2, detected a 40,000-M(r) protein expressed from pRAP401 but did not detect Orf2 in H. somnus, lysates. The phage-like DNA was detected in the serum-susceptible preputial strains HS-124P and HS-127P but was absent from the serum-resistant preputial strains HS-20P and HS-22P. Elucidation of a potential role for this cryptic prophage in the H. somnus life cycle requires more study.

Fis is required for illegitimate recombination during formation of lambda bio transducing phage.

Abstract: Specialized transducing particles of phage lambda are formed by illegitimate recombination during prophage induction. We examined the effects of an Esherichia coli int, xis, himA, himD, or fis mutation on illegitimate recombination during formation of lambda Spi- phage, a class of lambda bio transducing phage. This type of phage is distinguishable from the docL and docR particles, which contain one cohesive end and are formed by cutting of the cos site, by plaque formation of lambda bio on Escherichia coli P2 lysogens. The yields of lambda Spi- phage in the int, xis, int-xis deletion, and b2 deletion mutants were about 50- to 200-fold higher than that of the wild-type prophage when bacteria were irradiated with UV light. This result indicates that Int and Xis functions, and the att site, are not required for illegitimate recombination. The yield of lambda Spi- phage in the himA, himD, or fis mutant carrying lambda delta int-xis prophage was 2.6-, 3.3-, or 17-fold lower, respectively, than that in the wild-type bacteria under UV irradiation. Analysis of the nucleotide sequences of the junctions of the transducing phages indicates that recombination at the hotspots, as well as at non-hotspots, takes place between short homologous sequences. Because the growth of infecting phages was not suppressed by the himA, himD, or fis mutation, we conclude that Fis is required, but IHF is only partially required, for short-homology-dependent illegitimate recombination during the formation of lambda bio transducing phage.

Mutations of the coat protein gene of bacteriophage lambda that overcome the necessity for the fi gene; the efi domain

Abstract: The functions of most of the 10 genes involved in phage lambda capsid morphogenesis are well understood. The function of the FI gene is one of the exceptions. Mutants in FI fail to mature and package DNA. The gene product (gpFI) seems to act as a catalyst for the formation of an intermediate in capsid assembly called complex II, which contains a procapsid (an empty capsid precursor), terminase (the enzyme that cleaves the DNA precursor and packages it into the procapsid) and DNA. The mechanism for this stimulation remains unknown. It has also been reported that gpFI appeared to stimulate terminase-mediated cos cleavage, in the absence of procapsids, by increasing enzyme turnover. In comparison with other head-gene mutants, FI mutants are leaky, producing approx. 0.1 phage per infected cell. Some second-site revertants of FI- phages, called 'fin', that bypass the necessity for gpFI, have been isolated and found to harbour a mutation in the genes that code for the two subunits of terminase. In the course of mapping additional fin mutants, it was discovered that some mapped outside the terminase genes. To localize the mutations, restriction fragments of fin mutant DNAs were subcloned into plasmids and their ability to contribute to fin function was determined by marker-rescue analysis. The location of the fin mutation was further delineated by deletion analysis of a plasmid that was positive for fin. This showed that some fin mutations mapped to a region comprising genes E, D and a portion of C. The sequencing of this entire region in several fin isolates showed that the fin mutations are clustered in a small region of gene E corresponding to a portion of 26 amino acid residues of the coat protein (gpE). We have called this region of the protein the EFI domain. All the mutations result in an increase in positive charge relative to the wild-type protein. These results suggest that DNA maturation and packaging are in part controlled by an interaction between gpFI and capsid gpE.

Modulation of EcoKI restriction in vivo: role of the lambda Gam protein and plasmid metabolism.

Abstract: Two novel types of alleviation of DNA restriction by the EcoKI restriction endonuclease are described. The first type depends on the presence of the gam gene product (Gam protein) of bacteriophage lambda. The efficiency of plating of unmodified phage lambda is greatly increased when the restricting Escherichia coli K-12 host carries a gam+ plasmid. The effect is particularly striking in wild-type strains and, to a lesser extent, in the presence of sbcC and recA mutations. In all cases, Gam-dependent alleviation of restriction requires active recBCD genes of the host and recombination (red) genes of the infecting phage. The enhanced capacity of Gam-expressing cells to repair DNA strand breaks might account for this phenomenon. The second type is caused by the presence of a plasmid in a restricting host lacking RecBCD enzyme. Commonly used plasmids such as the cloning vector pACYC184 can produce such an effect in strains carrying recB single mutations or in recBC sbcBC strains. Plasmid-mediated restriction alleviation in recBC sbcBC strains is independent of the host RecF, RecJ, and RecA proteins and phage recombination functions. The presence of plasmids can also relieve restriction in recD strains. This effect depends, however, on the RecA function in the host. The molecular mechanism of the plasmid-mediated restriction alleviation remains unclear.

Induction threshold of the Q - mutant of bacteriophage λ in Escherichia coli

Abstract: Temperature induction of bacteriophage λ in Escherichia coli depends on bacterial population density. The lowest rate of viability loss at the temperature threshold results in maximal gene expression of λ. λ-Infection causes bacterial cells to lose cell viability and thus decrease temperature induction efficiency. In addition, shifting-up in temperature increases the probability of progeny λ; thus, the mortality of bacterial hosts increases and the expression of recombinant proteins by naked λ significantly decrease.

Thermostable phage lambda operator mutants for regulating gene expression

Abstract: The present invention concerns a method for selecting New PR or PL operator sequences from lambdoid phages which have different thermostability compared to the wild-type sequence with regard to binding a repressor. In addition new mutated PR or PL operator sequences and their use for the temperature-regulated expression of genes and for production of improved vaccines is disclosed.