Isolation and characterization of lambda transducing bacteriophages for the su1+ (supD minus) amber suppressor of Escherichia coli.

Specialized lambda transducing phages for the sul+ (supD-) amber suppressor in Escherichia coli K-12 have been isolated, using a secondary site lambda-cI857 lysogen in which we have shown the prophage to be closely linked to sul+.sul+ transducing particles were detected frequently, at 10-5 per plaque-forming unit, in lysates prepared from the secondary-site lysogens. High-frequency transducing lysates were obtained from several independently isolated sul+ transductants and were analyzed by CsCl equilibrium density gradient centrifugation. The transducing phages are defective; marker rescue analysis indicates that the lambda-N gene is not present. In lambda-cI857DELTANdSul+, a bio-type transducing phage, the genes specifying recombination and excision functions have been replaced by bacterial deoxyribonucleic acid.     

Isolation of specialized transducing bacteriophages carrying the structural genes of the hexuronate system in Escherichia coli K-12: exu region.

In Escherichia coli HfrH 58, isolated by Shimada et al., a heat-inducible phage has been integrated in a secondary attachment site. We have characterized tha nature of the lambda integration. The exuR regulatory gene is inactivated by prophage integration. Genetic and biochemical analysis indicated a gene order: uxaA-uxaC-exuT-(exuR')-lambdaNRAJ (exuR'). By induction of HfrH 58, one class of deletions extending into the exu region was obtained. Analysis of these deletions confirms the exu region topography and the regulatory mechanism of the hexuronate system previously described. It has been possible to regenerate a functional exuR gene by prophage exision. Various lambda transducing particles plaque-forming and defective transducing phages carrying the left part or the right part of the exu region, have been derived from the secondary site lysogen HfrH 58. A phage carrying the entire exuR region was constructed by a cross between these two types of phage. The construction and characterization of these exu transducing phages are presented.     

Isolation and characterization of specialized lambda transducing bacteriophage carrying the metBJF methionine gene cluster.

Secondary attachment site lysogens of Deltaatt(lambda)Deltappc-argECBH strains of Escherichia coli with lambdacI857 integrated into the bfe gene (88 min) were isolated. Of 20 such lysogens examined, 2 produce lysates with transducing phage containing the metBJF gene cluster (87 min). Reintroduction of the ppc-argECBH chromosome segment (which lies between the bfe and met genes) into these strains virtually abolishes the production of met transducing phage. All of the phage examined have lost essential genes from the left arm of the lambda chromosome. Approximately 85% of the phage appear to have the same genetic composition, containing the metBJF gene cluster, but not the closely linked gene cytR, and having lost phage genes G and J. Analytical CsCl density gradient centrifugation of five representatives of this major class of phage shows four of them to have identical densities (lighter than lambda), while the fifth cannot be resolved from lambda. The four apparently identical phage were isolated from three separate lysates, which suggests the existence of preferred sites for illegitimate recombination on the bacterial and phage chromosomes. Three specialized transducing phage that carry cytR in addition to metB, metJ, and metF have also been studied. Each of these viruses has a different amount of phage deoxyribonucleic acid. Two of them have less deoxyribonucleic acid than lambda, whereas the third has about the same amount. The metB, metF, and cytR genes of the transducing phage have been shown to function in vivo. The phage-borne metB and metF genes are subject to metJ-mediated repression.     

Mutants in the y region of bacteriophage lambda constitutive for repressor synthesis: their isolation and the characterization of the Hyp phenotype

Bacteriophage lambdahyp mutants have been isolated as survivors of Escherichia coli K-12 bacteria lysogenic for lambda Nam7am53cI857. The hyp mutants are characterized by (i) their localization in the y region very close to the imm lambda/imm434 boundary, (ii) polarity on O gene expression, (iii) immediate recovery of lambda immunity at 30 degrees C after prolonged growth of lambda Nam7am53cI857 hyp lysogens at 42 degrees C even in the presence of an active cro gene product, (iv) ability of phage lambda v2v3vs326 but not lambda v1v2v3 to propagate on lambda cI+hyp lysogens, (v) inability to express lambda exonuclease activity after prophage induction, and (vi) inviability at any temperature of phage carrying the hyp mutation. All these properties are referred to collectively as the Hyp phenotype. We show that the Hyp phenotype is due to cII-independent constitutive cI-gene-product synthesis originating in the y region, which results in the synthesis of anti-cro RNA species, and constitutive levels of cro gene product present even in lambda cI+hyp lysogens. A model is presented which is consistent with all the experimental observations.     

Operator-promoter functions in the threonine operon of Escherichia coli.

The prophage curing properties of secondary-site lysogens of coliphage lambda have been studied. The site of integration in the original lysogen (L79) is within the ooerator-promoter region of the thr operon. As a result, expression of the thr enzymes is reduced, and the strain is a leaky threonine auxotroph. Heat pulse curing of strain L79 and a thr+ lysogenic revertant (L79-20) showed that heat pulse curing of both lysogens was int and xis dependent and occurred by correct excisions of the prophage. The heat pulse curing restored strain L79 to prototrophy whereas strain L79-20 synthesized the thr enzymes constitutively and at high levels. This indicates that the reversion mutation in strain L79-20 occurred outside of the prophage and within the operator-promoter region of the thr operon. In contrast, spontaneous curing of both lysogens occurred by both correct and incorrect excisions. Spontaneously cured derivatives of strain L79-20 gave rise to three classes of regulatory mutants affecting operator and promoter functions to the thr operon.     

The Bacteriophage λ Attachment Site in Wild Strains of Escherichia coli

The attachment site (attlambda) of bacteriophage lambda was examined in wild strains of Escherichia coli. Although the att region is non-coding, the DNA sequence was invariant in the 13 strains examined. Two other non-coding regions showed nine changes, all associated with a single strain. In four of 33 strains, sequences were inserted in or near the attlambda site and in two of these the insert was related to lambda. Among strains that can be lysogenized by lambda, integration was via the attlambda site in all cases. Some resistant strains can be lysogenized, and these have been termed "lenient." Most of these fail to give normal phage yield after induction. In some cases rare lysogens have been formed in cells that belong to a mutant subpopulation.     

Excision of bacteriophage lambda from a site in the arabinose B gene.

A lambda lysogen with the prophage inserted into the arabinose B gene of Escherichia coli strain K-12 has been prepared. Induction of the phage from this lysogen yields viable phage at a frequency 4 X 10(-6) that found for induction of lysogens with phage inserted at the normal attachment site. Over 30% of the phage particles induced from the insertion in ara are arabinose-transducing phage. The excision end points of 62 independently isolated, nondefective araC-transducing phage containing less than the entire araC gene were genetically determined and were found to be randomly distributed through the araC gene. The amount of arabinose deoxyribonucleic acid contained on four selected transducing phage was determined by electron microscopy of deoxyribonucleic acid heteroduplexes, providing a physical map of the araC gene. The efficiency with which these phage transduce araC and araB point mutations was found to be approximately proportional to the homology length available for recombination.     

Prophage map of converting corynebacteriophage beta.

A prophage map for corynebacteriophage beta consisting of seven markers has been constructed and compared with the vegetative map. The mapping system utilizes heteroimmune double lysogens and capitalizes on the fact that these double lysogens are very unstable and throw off monolysogenic segregants. The prophage map, produced by characterizing the recombinant phage in these monolysogenic segregants, appears to be a cyclic permutation of the vegetative map with the gene for toxin at one end of the prophage map and the gene for phage immunity at the other. This permutation is in accord with the Campbell model for insertion of lambda phage if a site between the toxin and immunity genes in the vegetative map is designated as the phage attachment site. The position of the gene for toxin in the prophage map suggests that converting phages may have originated as specialized transducing phages for this gene.     

A bacteriophage T4 gene which functions to inhibit Escherichia coli Lon protease.

A bacteriophage T4 gene which functions to inhibit Escherichia coli Lon protease has been identified. This pin (proteolysis inhibition) gene was selected for its ability to support plaque formation by a lambda Ots vector at 40 degrees C. Southern blot experiments indicated that this T4 gene is included within the 4.9-kilobase XbaI fragment which contains gene 49. Subcloning experiments showed that T4 gene 49.1 (designated pinA) is responsible for the ability of the Ots vector to form plaques at 40 degrees C. Deficiencies in Lon protease activity are the only changes known in E. coli that permit lambda Ots phage to form plaques efficiently at 40 degrees C. lon+ lysogens of the lambda Ots vector containing pinA permitted a lambda Ots phage to form plaques efficiently at 40 degrees C. Furthermore, these lysogens, upon comparison with similar lysogens lacking any T4 DNA, showed reduced levels of degradation of puromycyl polypeptides and of canavanyl proteins. The lon+ lysogens that contained pinA exhibited other phenotypic characteristics common to lon strains, such as filamentation and production of mucoid colonies. Levels of degradation of canavanyl proteins were essentially the same, however, in null lon lysogens which either contained or lacked pinA. We infer from these data that the T4 pinA gene functions to block Lon protease activity; pinA does not, however, appear to block the activity of proteases other than Lon that are involved in the degradation of abnormal proteins.     

Gene Regulation in N Mutants of Bacteriophage λ

Mutants (N(-)nin) of bacteriophage lambda in which the N gene product is not required for growth on wild-type Escherichia coli do not plate on recA bacterial mutants. Secondary mutants, selected for growth on recA, lie within the immunity region to the right of gene cI and appear identical to the cro mutants of Eisen et al. In an N(+) phage, a cro mutation causes enhanced and prolonged production of lambda exonuclease. N(-)cro phages make no detectable exonuclease, but show an increased rate of specific excision from lysogens and are excluded by P2 prophage. These properties, together with the ability to plate on recA, suggest that N(-)cro phages express genes to the left of N at a rate that is very low but higher than that for N(-)cro(+) phages. N(-)nin phages can integrate at the normal site on the bacterial chromosome, but specific excision from lysogens is immeasurably low.     

Genetic and physical studies of lambda transducing bacteriophage carrying the beta subunit gene of the Escherichia coli ribonucleic acid polymerase.

The prophage lambdac1857 was inserted into the bfe gene located near rif (the structural gene for the beta subunit of deoxyribonucleic acid [DNA]-dependent ribonucleic acid polymerase) on the Escherichia coli chromosome. Induced lysates (low-frequency transducing lysates) of such a lysogen contained defective lambda phage particles (lambdadrif+) that can specifically transduce the wild-type rif+ gene. Upon transduction into a recipient strain carrying recA, heterogenotes harboring both the wild-type and the mutant rif genes were isolated. Rec+ derivatives of these heterogenotes produce high-frequency transducing lysates that contain lambdadrif+ and normal active phages at a ratio of 1 to 2. The results of marker rescue experiments and of density determination with several transducing phages indicate that most of the late genes are deleted and replaced by a segment of the chromosomal DNA carrying the bfe-rif region. The length of the chromosomal segment seems to vary between approximately 0.5 and 0.6% of the total bacterial DNA among the three independently isolated lambdadrif+ phages. Electron microscopy of heteroduplex DNA consisting of one strand from lambdadrif+-6 and the other from lambdaimm-21 phages directly confirmed that most of the phage DNA of the "left arm" was replaced by the bacterial DNA. The heteroduplex study also demonstrated that the integration of prophage lambda into the bfe region occurred at the normal cross-over point within the phage attachment site.     

Evidence that the outer membrane protein gene nmpC of Escherichia coli K-12 lies within the defective qsr'' prophage.

Recombinants between phage lambda and the defective qsr' prophage of Escherichia coli K-12 were made in an nmpC (p+) mutant strain and in the nmpC+ parent. The outer membrane of strains lysogenic for recombinant qsr' phage derived from the nmpC (p+) strain contained a new protein identical in electrophoretic mobility to the NmpC porin and to the Lc porin encoded by phage PA-2. Lysogens of qsr' recombinants from the nmpC+ strain and lysogens of lambda p4, which carries the qsr' region, did not produce this protein. When observed by electron microscopy, the DNA acquired from the qsr' prophage showed homology with the region of the DNA molecule of phage PA-2 which contains the lc gene. Relative to that of the recombinant from the nmpC (p+) mutant, the DNA molecule of the recombinant from the nmpC+ parent contained an insertion near the lc gene. These results were supported by blot hybridization analysis of the E. coli chromosome with probes derived from the lc gene of phage PA-2. A sequence homologous to the lc gene was found at the nmpC locus, and the parental strains contained an insertion, tentatively identified as IS5B, located near the 3' end of the porin coding sequence. We conclude that the structural gene for the NmpC porin protein is located within the defective qsr' prophage at 12.5 min on the E. coli K-12 map and that this gene can be activated by loss of an insertion element.     

Integration of the related prophages lambda, phi 80 and their hybrid lambda att80 into the secondary chromosomal att sites of wild-type Escherichia coli

The family of lambdoid phages displays a varying specificity of integration into the host chromosome. The lambda phage DNA failed to get inserted at the secondary attachment site(s) of the gal operon (frequency less than 2.6 X 10(-8)) in the presence of the primary (normal) one. By contrast, phi 80 and the lambda att80 hybrid integrated into wild-type Escherichia coli at least, at two secondary att sites of the btuB locus, the latter phage being also capable of integration in the vicinity of purE and purC (frequency 2 X 10(-3) to 10(-4)). Integration of phi 80 and lambda att80 into btuB occurred with about the same frequency as in cells deleted for normal insertion site (0.7 divided by 4.0 X 10(-6)). An analysis of the secondary lysogens with the prophage in btuB showed them to be polylysogens; the additional prophage(s) was found in the primary att site. We also failed to observe integration of phi 80 and lambda att80 with formation of secondary monolysogens into other foci (frequency less than 0.0035, if multiplicity of infection was 10(-3) or 10). It is presumed that phi 80 and lambda att80 prophages get only integrated at secondary att sites in case the primary site is occupied.     

Isolation and characterization of nondefective transducing lambda bacteriophages carrying fla genes of Escherichia coli K-12.

In Escherichia coli K-12, 11 fla genes and a hag gene are located between his and uvrC, making two clusters at map positions 42.5 and 43.0 min. Nondefective transducing lambda phages for these genes were isolated. Low-frequency-transducing donors were constructed starting from lysogens of lambda cI857 in which the prophage is integrated at a secondary attachment site at 44 min on the E. coli map. Two strategies were used to delete the region between the prophage and the fla genes. Deletion mutants of the supD locus between fla and the prophage were isolated by selecting for loss of Su1+, an allele of supD. A strain with a deletion starting within the prophage and ending at a position close to the fla genes was isolated from heat-resistant derivatives of the lysogen. A lysogen of lambda b2 was then constructed in which the prophage had integrated at the site of the defective prophage by means of recombination with residual lambda deoxyribonucleic acid. From low-frequency-transducing lysate of the donor strains thus constructed, either directly or in combination with a procedure that extends the loci transduced, various lambda pfla's were isolated. lambda pflaL1 carries all nine fla genes at 43 min, and lambda pflaH14 carries hag and two fla genes at 42.5 min.     

Xis and Fis proteins prevent site-specific DNA inversion in lysogens of phage HK022.

HK022, a temperate coliphage related to lambda, forms lysogens by inserting its DNA into the bacterial chromosome through site-specific recombination. The Escherichia coli Fis and phage Xis proteins promote excision of HK022 DNA from the bacterial chromosome. These two proteins also act during lysogenization to prevent a prophage rearrangement: lysogens formed in the absence of either Fis or Xis frequently carried a prophage that had suffered a site-specific internal DNA inversion. The inversion is a product of recombination between the phage attachment site and a secondary attachment site located within the HK022 left operon. In the absence of both Fis and Xis, the majority of lysogens carried a prophage with an inversion. Inversion occurs during lysogenization at about the same time as prophage insertion but is rare during lytic phage growth. Phages carrying the inverted segment are viable but have a defect in lysogenization, and we therefore suggest that prevention of this rearrangement is an important biological role of Xis and Fis for HK022. Although Fis and Xis are known to promote excision of lambda prophage, they had no detectable effect on lambda recombination at secondary attachment sites. HK022 cIts lysogens that were blocked in excisive recombination because of mutation in fis or xis typically produced high yields of phage after thermal induction, regardless of whether they carried an inverted prophage. The usual requirement for prophage excision was bypassed in these lysogens because they carried two or more prophages inserted in tandem at the bacterial attachment site; in such lysogens, viable phage particles can be formed by in situ packaging of unexcised chromosomes.     

A deletion analysis of hybrid phage carrying the US region of Herpes simplex virus type 1 (Patton). I. Isolation of deletion derivatives and identification of chi-likes sequences

The EcoRI-H fragment (15.4 kb) of Herpes simplex virus type 1 (HSV-1) has been cloned in lambda gtWES in both orientations. This fragment contains the entire US region and has about 900 bp of terminal redundant sequences derived from the internal and terminal repeats of the S region. 56 independent plaque-forming deletion derivatives of the lambda gt/WES::EcoRI-H hybrid phage were isolated using either EDTA resistance or ability to grow on Escherichia coli(P2) lysogens as selective methods. The endpoints of these deletions were located using nine restriction enzymes that cleave within the EcoRI-H fragment. All of the deletions have at least one endpoint within the cloned fragment. Several unusual features of the lambda hybrids, including heterogeneity of a particular region in the HSV-1 EcoRI-H fragment and the presence of chi-like sequences in the US region of HSV-1, are discussed.     

Analysis of lambda insertions in the fucose utilization region of Escherichia coli K-12: use of lambda fuc and lambda argA transducing bacteriophages to partially order the fucose utilization genes

Escherichia coli K-12 strains have deletions for the normal lambda integration site were lysogenized with bacteriophage lambda at a site within the L-fucose utilization system (fuc). The frequency of lambda integration at this site is approximately 2 X 10(-8) to 5 X 10(-7). Studies of the lytic properties of these strains indicated very infrequent cell lysis with a relatively low phage burst size. Transductional ability of the phage lysates was found to be normal, comparable to that found in conventional low-frequency transducing lysates. Two major classes of transducing phage were found. One carried the markers argA and fucA (a fucose utilization gene of unknown function previously referred to as fuc-1) and the gene for D-arabinose utilization (dar+). The other carried only fucC, the gene specifying L-fuculose-1-phosphate aldolase. A minor class of phage was found that carried fucA, but not argA or dar+. Upon consideration of the transductional nature of these phage classes, we are proposing that the gene order for the L-fucose utilization system is dar, fucA, (lambda), fucC.