Escape synthesis of the biotin operon in induced lambda b-2 lysogens

Overexpression of the Bacteriophage T4 motB Gene Alters H-NS Dependent Repression of Specific Host DNA

The bacteriophage T4 early gene product MotB binds tightly but nonspecifically to DNA, copurifies with the host Nucleoid Associated Protein (NAP) H-NS in the presence of DNA and improves T4 fitness. However, the T4 transcriptome is not significantly affected by a motB knockdown. Here we have investigated the phylogeny of MotB and its predicted domains, how MotB and H-NS together interact with DNA, and how heterologous overexpression of motB impacts host gene expression. We find that motB is highly conserved among Tevenvirinae. Although the MotB sequence has no homology to proteins of known function, predicted structure homology searches suggest that MotB is composed of an N-terminal Kyprides-Onzonis-Woese (KOW) motif and a C-terminal DNA-binding domain of oligonucleotide/oligosaccharide (OB)-fold; either of which could provide MotB’s ability to bind DNA. DNase I footprinting demonstrates that MotB dramatically alters the interaction of H-NS with DNA in vitro. RNA-seq analyses indicate that expression of plasmid-borne motB up-regulates 75 host genes; no host genes are down-regulated. Approximately 1/3 of the up-regulated genes have previously been shown to be part of the H-NS regulon. Our results indicate that MotB provides a conserved function for Tevenvirinae and suggest a model in which MotB functions to alter the host transcriptome, possibly by changing the association of H-NS with the host DNA, which then leads to conditions that are more favorable for infection.

Direct cloning from enrichment cultures, a reliable strategy for isolation of complete operons and genes from microbial consortia

Enrichment cultures of microbial consortia enable the diverse metabolic and catabolic activities of these populations to be studied on a molecular level and to be explored as potential sources for biotechnology processes. We have used a combined approach of enrichment culture and direct cloning to construct cosmid libraries with large (>30-kb) inserts from microbial consortia. Enrichment cultures were inoculated with samples from five environments, and high amounts of avidin were added to the cultures to favor growth of biotin-producing microbes. DNA was extracted from three of these enrichment cultures and used to construct cosmid libraries; each library consisted of between 6,000 and 35,000 clones, with an average insert size of 30 to 40 kb. The inserts contained a diverse population of genomic DNA fragments isolated from the consortia organisms. These three libraries were used to complement the Escherichia coli biotin auxotrophic strain ATCC 33767 Delta(bio-uvrB). Initial screens resulted in the isolation of seven different complementing cosmid clones, carrying biotin biosynthesis operons. Biotin biosynthesis capabilities and growth under defined conditions of four of these clones were studied. Biotin measured in the different culture supernatants ranged from 42 to 3,800 pg/ml/optical density unit. Sequencing the identified biotin synthesis genes revealed high similarities to bio operons from gram-negative bacteria. In addition, random sequencing identified other interesting open reading frames, as well as two operons, the histidine utilization operon (hut), and the cluster of genes involved in biosynthesis of molybdopterin cofactors in bacteria (moaABCDE).

The functional boundaries of the Q-utilization site required for antitermination of late transcription in bacteriophage lambda

Expression of the late genes of bacteriophage lambda requires, in addition to the host functions, the lambda p'R promoter, the antiterminator sequence qut, and the product of gene Q which interacts with the Q utilization (qut) site. In the absence of the Q function or qut site, the p'R-initiated transcription is blocked by the t'R terminator at the 194th nucleotide downstream of the start point, s'R, producing a short 6 S mRNA. In this study the position and boundaries of the qut site were deduced by constructing plasmids containing various portions of the p'R-qut region, the t'R1 terminator, and the reporter gene galK. We measured galK gene expression in response to the gamma Q gene product supplied in trans by a prophage or Q-expression plasmid. We show that among the lambda proteins, the Q gene product alone is necessary and sufficient for complete qut-mediated transcription antitermination in vivo. These antitermination experiments, employing plasmids that contain different lengths of lambda p'R-qut sequence, identified the right boundary of the qut site, which is located between +4 and +18 (for s'R = +1). The functional left boundary of qut does not extend upstream from the -26th nucleotide of the p'R promoter, as based on the following experiments. The promoter function of the truncated (-26)p'R-s'R-(+18) sequence can be restored by fusion to the complete but qut-less p'R, pp, or PLac promoter; however, no antitermination was observed for such a p-(-26)p'R-s'R-(+18)-t'R-galK plasmid. Thus we conclude that the qut site partially overlaps with the p'R promoter sequence. However, promoters that contain the -10 region of p'R, s'R, and the +1 to +18 qut sequence did mediate Q-dependent antitermination when properly fused to the homologous or heterologous -35 promoter regions. Only those transcripts that start at s'R (+1 or very near to it) and also contain at least the first 18 nucleotides (actually greater than 4 and less than or equal to 18) of 6 S RNA appear to be a target for the Q-qut-mediated transcription antitermination, which acts not only at t'R but also at other Rho-independent or Rho-dependent terminators.

Overproduction, purification and characterization of the F traT protein

A lambda transducing phage (ED lambda 110) which carries the sex factor F surface exclusion genes, traS and traT, was characterized by both genetic and physiochemical techniques. The transducing segment consists of 5.2 kilobases of F tra DNA, and carries the carboxy-terminal one-half of the upstream traG gene, as well as traS, traT, and the adjacent downstream gene traD. These tra proteins could be identified in infected UV-irradiated cells, and the major part of their synthesis was found to occur from the phage's late promoter pR' under Q control. Lysogens for ED lambda 110 were induced and found to greatly overproduce the traT gene product (TraTp), an outer membrane protein normally found in about 20,000 copies per cell, to levels which exceeded the major outer membrane proteins. This led to the development of a simple purification procedure for TraTp, the most important step of which was the construction of an appropriate ompB derivative to eliminate the major outer membrane porin proteins, which have several physical properties in common with TraTp. Purified TraTp was added to mixtures of donor and recipient cells and found to inhibit mating. The specificity of this assay was demonstrated by using an R100-1 donor, which responds to a heterologous surface exclusion system, and by using an altered TraTp containing a missense amino acid substitution. A mechanism by which TraTp mediates surface exclusion is proposed.

A nucleotide change in the anticodon of an Escherichia coli serine transfer RNA results in supD-amber suppression

The tRNAs specified by the wild type and amber suppressor alleles of the Escherichia coli supD gene have been identified, and their primary structures determined. The sequences differ by a single nucleotide in the middle of the anticodon. A CUA anticodon allows the suppressor tRNA to read the UAG stop codon; the CGA anticodon in the minor serine tRNA species from which the suppressor is derived is specific for the serine codon UCG.

Regulation of expression of the Escherichia coli dnaG gene and amplification of the dnaG primase

We have isolated lambda transducing phages carrying the Escherichia coli primase gene (dnaG) and mapped restriction sites in the cloned bacterial DNA segments. Several different DNA fragments containing the dnaG gene were inserted into multicopy plasmids. An analysis of the primase levels in cells harboring such plasmids indicates that sequences far upstream from the dnaG gene are required for optimal primase expression. Using this knowledge, we constructed a plasmid with a thermoinducible copy-number, pRLM61, which was employed to amplify intracellular primase levels approximately 100-fold. The dnaG gene is transcribed clockwise with respect to the E. coli genetic map, and a HindIII site located 180 base pairs upstream from the dnaG gene separates the gene from its primary promoter. An apparent transcription termination signal is positioned 30-70 base pairs in front of the primase gene. Transcription proceeds past this strong terminator only when RNA polymerase has first transcribed the bacterial DNA segment proximal to the HindIII site. We suggest that primase expression in E. coli is positively regulated by a mechanism of transcription antitermination mediated by a bacterial factor. We propose, furthermore, that the neighboring structural genes for primase and for the sigma subunit of RNA polymerase are coordinately regulated as part of an operon. This arrangement may enable the bacterial cell to readily control the level of initiation of DNA and RNA synthesis and thus to respond quickly and efficiently to changing conditions.

Transcriptional termination sites in the b2 region of bacteriophage lambda that are unresponsive to antitermination

A bacteriophage lambda cloning vector carrying the trp/lacW205 substitution is described. The vector facilitates the fusion in vitro of genetic control signals to the lacZ structural gene of Escherichia coli. This system was used to define transcriptional termination sites in the lambda b2 region. This region contains termination sites that are unresponsive to the lambda antiterminating proteins pQ and pN.

Cloning and characterization of a transcription termination signal in bacteriophage lambda unresponsive to the N gene product

The pHA10 plasmid was designed for the cloning and selection of transcriptional termination signals. This study demonstrates the use of pHA10 as a cloning vehicle in the selection and characterization of an N-unresponsive terminator. Following the random cloning of lambda DNA, and N-unresponsive transcription terminator was isolated. Hybridization of in vivo 32P-labeled RNA to various DNA fragments, using the Southern (1975) blotting technique, revealed that the transcriptional barrier that cannot be overridden in the presence of N is located close to the end of gene J of lambda DNA. The terminator determines the 3'-end of the pL operon and prevents the transcription of the anti-sense DNA strand of lambda late genes. The primary structure and other characteristics of this terminator are now under investigation.

A bacteriophage lambda vector for cloning large DNA fragments made with several restriction enzymes

Lambda derivatives are described that can be used for cloning DNA fragments of about 20 kilobase pairs (kb) generated by restriction enzymes EcoRi, HindIII, BamHI, MboI and BglII. Recombinants can be selected by their Spi- phenotype and their propagation is facilitated by the presence of a chi site.

The phage promoter responsible for the expression of the inserted beta-galactosidase gene in bacteriophage lambda plac5

The lac transducing phage, lambda plac5, carries a segment of the E. coli lac operon on the left side of the b2 region of the lambda phage. In the absence of additional cyclic AMP, beta-galactosidase can only be expressed from the phage promoter, and the expression of the inserted lac promoter is suppressed. This phage promoter responsible for beta-galactosidase synthesis is shown to be under the control of the cI and N gene products; however, the repressive action of the cro gene product at high multiplicity of infection is not observed although some turn off at very late time is detected. To pin down this phage promoter, results described in this communication and those described elsewhere can rule out the promoter PI, PR, P'R, and the promoter PL also looks rather unlikely. No firm identification of this phage promoter has been made, but the promoter(s) in the b2 region (the b2 promoter) is proposed. The phage promoter responsible for beta-galacrosidase synthesis is shown to be a weak promoter, requires the Q gene product or one (or more) of the late gene products for activation, and the time of expression is very late.

Investigations of the F conjugation gene traI:traI mutants and lambdatraI transducing phages

A series of traI point and deletion mutants of Flac, and a traM mutant, were characterised. Complementation tests with an amber Flac traI mutant confirmed their genotypes, and in addition all the traI mutants, but not the traM mutant, were complemented by pRS31 (PSC101 traDI) and EDlambda109 (lambdatraI). Judging from the efficiencies of plating of F-specific phages, none of the mutations affected pilus formation. The traI products of F and of the F-like plasmid R1 were interchangeable with each other but not with that of R100, while the traM product of F could not be replaced by those of R1 or of R100. Neither traI nor traM were needed for conjugal transfer of ColE1. Three lambda transducing phages carrying traI were isolated by in vivo or in vitro techniques, and characterised by genetic complementation tests, by analysis of the fragments produced by restriction endonucleases, and by measurement of heteroduplex molecules. The genetic structures together with the sizes and F coordinates, of the transfer regions carried by the phages were thereby determined. Comparison of the proteins synthesised in UV-irradiated cells by one of the lambdatraI phages with those made by a derivative carrying an amber traI mutation, allowed the traI product to be identified as a protein of molecular weight 174,000. In addition, the molecular weights of the traD (84,000), traS (18,000), and traT (25,000) products made by the lambdatraSTD1 phage EDlambda107 were measured. The possible roles of the traI and traM products in conjugation are discussed.

In vitro synthesis and and regulation of the biotin enzymes of Escherichia coli K-12

The synthesis and regulation of two of the enzymes of the biotin operon of Escherichia coli, 7,8-diaminopelargonic acid aminotransferase and dethiobiotin synthetase, were studied in vitro in a coupled transcription-translation system. These enzymes are encoded by genes located on opposite strands of the divergently transcribed operon (A. Guha, Y. Saturen, and W. Szybalski, J. Mol. Biol. 56:53-62, 1971). The kinetics of synthesis of both the enzymes were determined and the efficiency of the system was 0.3 to 0.4% that of the in vivo rate of synthesis in derepressed cells. Guanosine 3'-diphosphate 5'-diphosphate at 0.2 mM concentration stimulated the synthesis of 7,8-diaminopelargonic acid aminotransferase two- to threefold but had no effect on dethiobiotin synthetase synthesis. Biotin, which was most effective as the corepressor in vivo, also functioned in vitro at physiological concentrations in conjunction with a crude repressor protein isolated from a lysogen carrying the bioR gene. However, the two strands showed differential repression. At a repressor concentration where 7,8-diaminopelargonic acid aminotransferase synthesis was completely repressed, the repression of dethiobiotin synthetase was only 20% and did not exceed 50% with increasing repressor concentrations. Although the exact reason for the partial repression remains to be resolved, our data clearly suggest that the biotin operon is regulated from two separate operators.

Regional replication of the bacterial chromosome induced by derepression of prophage lambda. III. Role of the replication in escape synthesis of gal operon

Recent evidence suggests that the escape synthesis of gal operon following derepression of the prophage lambda in Escherichia coli K12 involves transcription originating at the lambda promoter (PL) to extend through gal under the conditions in which lambda DNA replication is prevented. Whether the observed expression of gal is due to transcription initiating at PL or at the bacterial promoter for gal (Pgal) was examined in the case of lambda DNA replication being normal. The experiments are based on that two types of transcription are distinguished from each other by the following properties: 1. Pgal-promoted transcription is inhibited by chloramphenicol, while PL-promoted transcription is not. 2. PL-promoted transcription suppresses the polar effect caused by nonsense mutation in a bacterial gene, while Pgal-promoted transcription does not do so. -he results have suggested that gal escape synthesis in lambda-induced lysogen results from transcription which initiates not only at PL but also at Pgal. The Pgal-promoted transcription may be a consequence, direct or indirect, of the concomitant replication of gal DNA.

Overproducing araC protein with lambda-arabinose transducing phage

Escherichia coli infected with bacteriophage lambda-arabinose transducing phage were tested as sources of araC protein. Infection of cells with such phage produces an intracellular concentration of araC protein up to 100 times that present in wild-type E. coli, apparently resulting from fusion of the araC gene to bacteriophage lambda promoters. Lysates from these phage-infected cells may be fractionated to yield another 100-fold enrichment in araC activity so that the total enrichment is 10,000-fold. A nonsense mutation in araC provided proof of the identification on gel electrophoresis of a band in the purified material. Biologically active araC protein is a dimer with 28,000 M.W. subunits. The araC gene in these phage replaces the int-xis genes but is oriented in the opposite direction. Nonetheless, it appears to be transcribed in this position by the phage promoter pr via transcription the long way around. Furthermore, because araC gene is in this position, we were able to isolate phage on which the araC gene was under phage late gene control by deletion of the late gene transcription stop signals in the b2 region.

Escape synthesis of RNA polymerase subunits and termination factor rho following induction of prophage lambda in Escherichia coli

Synthesis of RNA polymerase subunits and of transcription termination factor p was studied after thermoinduction of prophage lambdac1857 located at several unusual sites on the chromosome of Escherichia coli. When a lysogen carrying the prophage at the bfe gene was induced at 42 degrees C, the rate of synthesis of core polymerase subunits (alpha, beta and beta') rapidly decreased, followed by a marked increase after about 10 min. The latter increase was observed specifically in the "bfe lysogen" and not in any of the other lysogens tested. Similarly, the rate of synthesis of p factor increased appreciably in the induced ilv lysogen carrying the prophage at the ilv gene, and possibly in the bfe lysogen as well, but not in other lysogens examined. Taken together with other evidence, these results suggest that the enhanced syntheses of beta and beta' subunits of RNA polymerase and of p factor observerd represent "escape synthesis", resulting from the close linkage of the prophage genome to the respective structural genes. In contrast, omega factor synthesis was stimulated upon induction of any of the lysogens used without respect to the site of prophage location, suggesting the involvement of an entirely different mechanism.

Regional replication of the bacterial chromosome induced by derepression of prophage lambda. II. Direction and origin

We have demonstrated previously by DNA-DNA hybridization that induction of lambda phage with wild type O and P genes results in an increase of bacterial DNA in the chromosomal region adjacent to the left of the prophage; is a segment between gal and attlambda (gal DNA) (Imae and Fukasawa, 1970). Evidence is presented in this report that such an increase of bacterial DNA is also seen in the region to the right of the prophage; a segment between bio and attlambda (bio DNA). We postulate therefore that the bidirectional replication of lambda DNA extends beyond the prophage and copies the neighboring host DNA until the prophage is excised. The model is verified by making use of excision-defective lambda phages. The synthesis of gal DNA (or bio DNA) slows down to a halt within 40 min after the induction in the normal lysogens. The results are attributed to the prophage excision: (1) In lysogens for lambdaint, synthesis of the bacterial DNA continues for longer times. (2) The synthesis of the bacterial DNA slows down to a halt in lysogens for lambdaxis or lambdab2 as in the control. However lambda DNA synthesis also slows down in parallel so that the amount of the bacterial DNA relative to that of lambda DNA synthesized by a given time stays constant from 20 min to 80 min. During that time the relative amount of the bacterial DNA rapidly decreases in the normal lysogen.

Mode of action of alpha-dehydrobiotin, a biotin analogue

Alpha-Dehydrobiotin, like biotin, represses coordinately the 7,8-diaminopelargonic acid aminotransferase and the dethiobiotin synthetase enzymes that are encoded on the l and r strands, respectively, of the bioA operon. The rate of synthesis for both enzymes is inhibited about 80% in the presence of alpha-dehydrobiotin. Homobiotin and alpha-methylbiotin are less effective than alpha-dehydrobiotin in repressing the synthesis of the two enzymes. The selective repression of transcription from l and by alpha-dehydrobiotin and homobiotin, previously reported in hybridization experiments, is not observed at the enzyme level. A combination of equal concentrations of biotin and alpha-dehydrobiotin which was reported to enhance selectively the level of messenger ribonucleic acid transcribed from the l strand does not increase the rate of synthesis of the aminotransferase enzyme. Instead, the enzymes encoded on both strands are essentially completely inhibited as with biotin alone. Strain differences have been ruled out to account for the different results obtained by the two methodologies. Our evidence would suggest that alpha-dehydrobiotin acts like biotin, presumably as the co-repressor, in the repression of the bioA operon. The low rates of enzyme synthesis observed in the presence of the biotin analogue is the result of incomplete repression due to a lower affinity of either the analogue for the repressor or of the co-repressor/repressor complex for the operator. While our evidence would support the concept of a two promoter/operator complex, both would have to respond equally to biotin and its analogues. The evidence, however, does not rule out other possible alternative models for the regulation of the biotin operon.