Bacteriophage lambda repressor allelic modulation of the Rex exclusion phenotype

The sensitivity of delta red-gam delta ren mutants of bacteriophage lambda to Rex exclusion by lambda rexA+ rexB+ lysogens is modulated by the prophage cI repressor allele. We show the following: (i) lambda spi156 delta nin5 forms plaques on a cI+-rexA+-rexB+ lysogen with 10(5)-fold higher efficiency than on cI[Ts]-rexA+-rexB+ derivatives. (ii) The cI[Ts]857 allele augmentation of Rex exclusion is recessive to cI+. (iii) The cI857-mediated increase in Rex exclusion activity involves the participation of a genetic element mapping outside of cI-rexA-rexB.     

Analysis of the Escherichia coli proBA locus by DNA and protein sequencing

A 2.9 kb DNA fragment carrying the Escherichia coli proBA region, which encodes the first two enzymes of the proline biosynthetic pathway, was subcloned onto an expression plasmid carrying both the bacteriophage lambda PL promoter (lambda PL) and the lambda gene encoding a thermolabile cI repressor protein (cI857). Derepression of the lambda PL promoter by thermal inactivation of the cI857 repressor protein resulted in the simultaneous overproduction of the proB (gamma-glutamyl kinase) and proA (gamma-glutamyl phosphate reductase) gene products. Nucleotide sequence analysis of the proBA locus allowed gene assignments consistent with the NH2 and COOH-terminal analyses and amino acid compositions of homogeneous preparations of the proB and proA proteins. The contiguous nature of the proB and proA genes suggests that the two genes constitute an operon in which proB precedes proA.     

Joining of λ bacteriophage DNA moleculesin vitro using the gene product of the λint phage

The ability of cell extracts ofEscherichia coli 1100 prepared at different times after infection with bacteriophage λint 6 cI 857 or λ 857 to attach molecules of λ³²P-DNA to λ DNA adsorbed on a nitrocellulose membrane filter was compared. It was found that only with extracts from cells infected with bacteriophage λ cI 857 with an active int gene was it possible to attach molecules of λ³²P-DNA to λ DNA. This ability was reflected best in extracts prepared from cells 10 min after infection. A similar ability was observed also with extracts prepared from cells ofEscherichia coli 1100 (λ cI 857) after heat induction of the prophage. The maximum efficiency in this case was observed with cell extracts 15 min after the temperature rise.     

Streptomyces marker plasmids for monitoring survival and spread of streptomycetes in soil.

Plasmid constructs pNW1 through pNW6 containing a controllable xylE gene (for catechol 2,3-dioxygenase) were introduced into Streptomyces lividans strains to provide a selectable marker system. xylE functions in S. lividans under the control of bacteriophage lambda promoters lambda pL and lambda pR. Thermoregulated expression of xylE is provided through the lambda repressor cI857. Catechol 2,3-dioxygenase activity was increased 2.8-fold from plasmid construct pNW2 (lambda pL, xylE, cI857) and 9.5- and 7.4-fold from constructs pNW3 (lambda pR, xylE, cI857) and pNW5 (lambda pR, xylE, cI857), respectively, when the temperature was shifted from 28 degrees C to 37 degrees C. The stability of the constructs varied from 4.7% for pNW2 to 99.4% for pNW4 (lambda pL, xylE) over two rounds of sporulation. Marked S. lividans strains released into soil systems retained the XylE phenotype for more than 80 days, depending on the marker plasmid, when examined by a selective plating method. Furthermore, S. lividans harboring plasmid pNW5 was detectable by nucleic acid hybridization at less than 10 CFU g-1 (dry weight) of soil as mycelium and 10(3) CFU g-1 (dry weight) of soil as spores with the xylE marker DNA extracted from soil and amplified by using the polymerase chain reaction.     

Streptomyces marker plasmids for monitoring survival and spread of streptomycetes in soil.

Plasmid constructs pNW1 through pNW6 containing a controllable xylE gene (for catechol 2,3-dioxygenase) were introduced into Streptomyces lividans strains to provide a selectable marker system. xylE functions in S. lividans under the control of bacteriophage lambda promoters lambda pL and lambda pR. Thermoregulated expression of xylE is provided through the lambda repressor cI857. Catechol 2,3-dioxygenase activity was increased 2.8-fold from plasmid construct pNW2 (lambda pL, xylE, cI857) and 9.5- and 7.4-fold from constructs pNW3 (lambda pR, xylE, cI857) and pNW5 (lambda pR, xylE, cI857), respectively, when the temperature was shifted from 28 degrees C to 37 degrees C. The stability of the constructs varied from 4.7% for pNW2 to 99.4% for pNW4 (lambda pL, xylE) over two rounds of sporulation. Marked S. lividans strains released into soil systems retained the XylE phenotype for more than 80 days, depending on the marker plasmid, when examined by a selective plating method. Furthermore, S. lividans harboring plasmid pNW5 was detectable by nucleic acid hybridization at less than 10 CFU g-1 (dry weight) of soil as mycelium and 10(3) CFU g-1 (dry weight) of soil as spores with the xylE marker DNA extracted from soil and amplified by using the polymerase chain reaction.     

Temperature-inducible amber suppressor: construction of plasmids containing the Escherichia coli serU- (supD-) gene under control of the bacteriophage lambda pL promoter.

An Escherichia coli DNA fragment containing the structural gene serU132 for the nonsense suppressor tRNASer2am was identified and purified by being cloned into a plasmid vector. Information obtained from DNA sequence analysis was used to select a serU132 fragment for insertion downstream from the bacteriophage lambda pL promoter in two pBR322-lambda derivatives. In nonsense mutant strains bearing the resulting serU132 hybrid plasmids, the presence of the lambda cI857 repressor gene carried on the same plasmid or in a prophage genome permits thermal regulation of suppressor synthesis.     

Identification in vivo of promoter activity in the left site of the att region of bacteriophage lambda DNA

The promoter-probing vector (pSK plasmid) was explored for cloning of the fragments from lambda cI857 and lambda b2 DNAs containing different regions of the att site. We have constructed all-tet fusions where the fusions are: 1) HindIII/BamHI-491 base pairs (b. p.) fragment of lambda cI857 DNA containing POP' site (plasmid pSK-PP'); 2) AluI-242 b. p. fragment of lambda cI857 DNA containing the left arm of the POP' site (plasmid pSK-P); 3) AluI-242 b. p. fragment of lambda cI857 DNA with opposite orientation (plasmid pSK-P); 4) EcoRI/BamHI-750 b. p. fragment of lambda b2 DNA containing the right arm of the POP' site (plasmid pSK-P'). These fusions permit us to analyse the effect of various pieces of the attachment site on the expression tet gene as the result of reparation of this gene promoter. We find that expression of tet (tetracycline resistant phenotype) takes place in the pSK-PP' and pSK-P but not in the pSK-P' and pSK-P. These facts permit us to conclude that the left arm of the att site contains a rightward promoter functioning in vivo. We postulate that this promoter activity might correspond to the promoter patt, which was described in previous experiments in vitro.     

In vivo studies on the interaction of RecBCD enzyme and lambda Gam protein.

The interaction between the RecBCD enzyme of Escherichia coli and the lambda Gam protein was investigated. Two types of experiments were done. In one type, Gam protein was produced by transient induction of the cells lysogenic for lambda cI857gam+. The presence of Gam protein, which inhibits RecBCD nuclease, enabled these cells to support the growth of a gene 2 mutant of bacteriophage T4 (T4 2). The lysogens overproducing the RecB subunit of RecBCD enzyme could titrate Gam protein and thus prevent the growth of T4 2. In contrast, the lysogens overproducing either RecC or RecD retained their capacity for growth of T4 2. It is therefore concluded that the RecB subunit is capable of binding Gam protein. In the second type of experiments, Gam protein was provided by derepressing the gamS gene on the plasmid pSF117 (S. A. Friedman and J. B. Hays, Gene 43:255-263, 1986). The presence of this protein did not interfere with the growth of wild-type cells (which were F-). Gam protein had a certain effect on recF mutants, whose doubling time became significantly longer. This suggests that the recF gene product plays an important role in maintenance of viability of the Gam-expressing cells. Gam protein exerted the most striking effect on growth of Hfr bacteria. In its presence, Hfr bacteria grew extremely slowly, but their ability to transfer DNA to recipient cells was not affected. We showed that the effect on growth of Hfr resulted from the interaction between the RecBCD-Gam complex and the integrated F plasmid.     

Degradation of ribosomal RNA in bacteriophage lambda lysogens after thermal induction

Stable RNA of Escherichia coli was extensively degraded about 40 min after thermal induction of lysogenized lambda cI857 phages at 42 degrees C. When several nuclease-deficient host cells were tested, RNase I activity in the host cells was inferred to be involved in the RNA degradation. Ribosomal structure was detectably altered before the degradation of ribosomal RNA was observed. 30S and 50S subunits began to sediment at 25-28S and 45-58S, respectively, still containing intact RNA. Nonpermissive host cells lysogenized with lambda cI857 susR produced progeny phages in normal burst size after thermal induction and then degraded stable RNA, though they were not lysed. In contrast cells lysogenized with lambda cI857 susS produced ten times more progeny phages under the same condition, but did not degrade stable RNA. These results indicate that the lambda S gene product, which acts as a positive effector of lysis, induced the degradation of stable RNA, presumably by a still uncharacterized effect on the cytoplasmic membrane.     

Renaturation of denatured lambda repressor requires heat shock proteins

The temperature-sensitive bacteriophage lambda cI857 repressor protein rapidly renatures after thermal inactivation. E. coli mutants in the heat shock protein genes dnaK, dnaJ, and grpE do not efficiently reactivate heat-denatured repressor. Our results suggest that protein refolding is promoted by heat shock proteins and that such a process is the basis of the homeostatic role played by these proteins in the heat shock response.     

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.     

Selective retention of recombinant plasmids coding for human insulin

Plasmids may be lost from Escherichia coli K-12 hosts that are cultured without selection for plasmid retention. This is particularly true for chimeric plasmids that incorporate genes for human insulin into vectors derived from pBR322. The cIts857 gene of bacteriophage lambda was inserted into the bla gene of the human-insulin-coding plasmids, pIA7 delta 4 delta 1, pIB7 delta 4 delta 1 and pHI7 delta 4 delta 1, generating the new plasmids pPR17, pPR18 and pPR19, respectively, which produced the thermosensitive lambda repressor. The cI gene was downstream from the pM and pbla promoters, so that it may have been expressed from either or both promoters. Separate E. coli K-12 RV308 host strains containing the new recombinants were lysogenized with the repressor-defective bacteriophage lambda cI90. Loss of the plasmid from the lysogens causes concomitant loss of the lambda repressor and cell death, because the prophage is induced to enter the lytic growth cycle. The system effectively forces retention of the plasmid in all viable cells in the culture.     

pHG276: a multiple cloning site pBR322 copy number vector expressing a functional lac alpha peptide from the bacteriophage lambda PR promoter

The bacteriophage lambda early promoter PR has been used to direct the synthesis of lac alpha in a plasmid containing the multiple cloning site of pUC8. The copy number of the plasmid is controlled by the rop(rom) gene and the plasmid incorporates the cI857 gene for temperature regulation of lac alpha expression. Isolation of recombinant derivatives with DNA inserts in the multiple cloning region can be identified by insertional inactivation of lac alpha and consequently, a Lac- phenotype in a host carrying the M15 deletion of lac. The potential of pHG276 as a fully regulated expression vector is examined.     

Method for selection of transposable DNA and characterization of a new insertion sequence, IS493, from Streptomyces lividans.

A method to select for transposable elements from Streptomyces spp. by using insertional inactivation of a repressor gene that functions in Escherichia coli was developed. Plasmid pCZA126, which can replicate in Streptomyces spp. or E. coli, contains a gene coding for the lambda cI857 repressor and a gene, under repressor control, coding for apramycin resistance. E. coli cells containing the plasmid are apramycin sensitive but become apramycin resistant if the cI857 repressor gene is disrupted. Plasmids propagated in Streptomyces spp. can be screened for transposable elements that have disrupted the cI857 gene by transforming E. coli cells to apramycin resistance. This method was used to isolate a new 1.6-kilobase insertion sequence, IS493, from Streptomyces lividans CT2. IS493 duplicated host DNA at the target site, had inverted repeats at its ends, and contained two tandem open reading frames on each strand. IS493 was present in three copies in the same genomic locations in several S. lividans strains. Two of the copies appeared to be present in regions of similar DNA context that extended at least 11.5 kilobases. Several other Streptomyces spp. did not appear to contain copies of IS493.     

Cloning, expression, and purification of gene 3 endonuclease from bacteriophage T7

The structural gene for the single-stranded endonuclease coded for by gene 3 of bacteriophage T7 has been cloned in pGW7, a derivative of the plasmid pBR322, which contains the lambda PL promoter and the gene for the temperature-sensitive lambda repressor, cI857. The complete gene 3 DNA sequence has been placed downstream of the PL promoter, and the endonuclease is overproduced by temperature induction at mid-log phase of Escherichia coli carrying the recombinant plasmid pTP2. Despite the fact that cell growth rapidly declines due to toxic effects of the excess endonuclease, significant amounts of the enzyme can be isolated in nearly homogeneous form from the induced cells. An assay of nuclease activity has been devised using gel electrophoresis of the product DNA fragments from DNA substrates. These assays show the enzyme to have an absolute requirement for Mg(II) (10 mM), a broad pH optimum near pH 7, but significant activity from pH 3 to pH 9, and a 10-100-fold preference for single-stranded DNA (ssDNA). The enzyme is readily inactivated by ethylenediaminetetraacetic acid or high salt. The differential activity in favor of ssDNA can be exploited to map small single-stranded regions in double-stranded DNAs as shown by cleavage of the melted region of an open complex of T7 RNA polymerase and its promoter.