A new class of promoter mutations in the lactose operon of Escherichia coli

Integrating T7 RNA Polymerase and Its Cognate Transcriptional Units for a Host-Independent and Stable Expression System in Single Plasmid

Metabolic engineering and synthetic biology usually require universal expression systems for stable and efficient gene expression in various organisms. In this study, a host-independent and stable T7 expression system had been developed by integrating T7 RNA polymerase and its cognate transcriptional units in single plasmid. The expression of T7 RNA polymerase was restricted below its lethal threshold using a T7 RNA polymerase antisense gene cassette, which allowed long periods of cultivation and protein production. In addition, by designing ribosome binding sites, we further tuned the expression capacity of this novel T7 system within a wide range. This host-independent expression system efficiently expressed genes in five different Gram-negative strains and one Gram-positive strain and was also shown to be applicable in a real industrial d- p-hydroxyphenylglycine production system.

Differential role of base pairs on gal promoters strength

Sequence alignments of promoters in prokaryotes postulated that the frequency of occurrence of a base pair at a given position of promoter elements reflects its contribution to intrinsic promoter strength. We directly assessed the contribution of the four base pairs in each position in the intrinsic promoter strength by keeping the context constant in Escherichia coli cAMP-CRP (cAMP receptor protein) regulated gal promoters by in vitro transcription assays. First, we show that base pair frequency within known consensus elements correlates well with promoter strength. Second, we observe some substitutions upstream of the ex-10 TG motif that are important for promoter function. Although the galP1 and P2 promoters overlap, only three positions where substitutions inactivated both promoters were found. We propose that RNA polymerase binds to the -12T base pair as part of double-stranded DNA while opening base pairs from -11A to +3 to form the single-stranded transcription bubble DNA during isomerization. The cAMP-CRP complex rescued some deleterious substitutions in the promoter region. The base pair roles and their flexibilities reported here for E. coli gal promoters may help construction of synthetic promoters in gene circuitry experiments in which overlapping promoters with differential controls may be warranted.

Fermentation conditions for high-level expression of the tac-promoter-controlled calf prochymosin cDNA in Escherichia coli HB101

Escherichia coli HB101 harboring an expression plasmid that bears the calf prochymosin gene controlled by the tac promoter was cultivated under different conditions in order to find an optimal fermentation arrangement that would lead to maximal prochymosin yield. Our results indicate that it is advantageous to use lactose in the double role of inducer and carbon/energy source when foreign gene expression is controlled by the tac promoter and the gene product is only moderately toxic owing to its accumulation in the form of an intracellular body. Glucose, on the other hand, may be used when expression should be repressed. Growth temperature substantially influenced the specific rate of prochymosin and beta-lactamase gene expression and the plasmid copy number. Three phases were distinguished in the time course of the fermentation on lactose: exponential growth practically without prochymosin synthesis, linear growth with prochymosin synthesis, and prochymosin synthesis without growth of biomass. The synthesis of prochymosin in the form of intracellular inclusion body was accompanied by the loss of respiratory activity of the cell and the loss of its ability to multiply. Sixteen hours cultivation at 37 degrees C in a complex medium with lactose as inducer and carbon/energy source resulted in up to 30% of the volume and 48% of the total protein of biomass being accumulated for as prochymosin inclusion bodies. The concentration of extractable enzymatically active chymosin in the culture reached 12 mg/L.

Detailed map of a cis-regulatory input function

Most genes are regulated by multiple transcription factors that bind specific sites in DNA regulatory regions. These cis-regulatory regions perform a computation: the rate of transcription is a function of the active concentrations of each of the input transcription factors. Here, we used accurate gene expression measurements from living cell cultures, bearing GFP reporters, to map in detail the input function of the classic lacZYA operon of Escherichia coli, as a function of about a hundred combinations of its two inducers, cAMP and isopropyl beta-d-thiogalactoside (IPTG). We found an unexpectedly intricate function with four plateau levels and four thresholds. This result compares well with a mathematical model of the binding of the regulatory proteins cAMP receptor protein (CRP) and LacI to the lac regulatory region. The model is also used to demonstrate that with few mutations, the same region could encode much purer AND-like or even OR-like functions. This possibility means that the wild-type region is selected to perform an elaborate computation in setting the transcription rate. The present approach can be generally used to map the input functions of other genes.

The -45 region of the Escherichia coli lac promoter: CAP-dependent and CAP-independent transcription

The lactose (lac) operon promoter is positively regulated by the catabolite gene activator-cyclic AMP complex (CAP) that binds to the DNA located 61.5 bp upstream of the transcription start site. Between the CAP binding site and the core promoter sequence is a 13-bp sequence (from -38 to -50 [the -45 region]). The possible roles of the -45 region in determining the CAP-independent level of lac expression and in the CAP activation process were studied by isolating and characterizing random multisite mutations. Only a small percentage of mutants have dramatic effects on lac promoter activity. Among the mutations that did affect expression, a 26-fold range in lac promoter activity in vivo was observed in the CAP-independent activity. The highest level of CAP-independent lac expression (13-fold the level of the wild-type lac promoter) correlated with changes in the -40 to -45 sequence and required an intact RNA polymerase alpha subunit for in vitro expression, as expected for an upstream DNA recognition element. Mutant promoters varied in their ability to be stimulated by CAP in vivo, with levels ranging from 2-fold to the wild-type level of 22-fold. Only a change of twofold in responsiveness to CAP could be attributed to direct DNA sequence effects. The -40 to -45 sequence-dependent enhancement of promoter activity and CAP stimulation of promoter activity did not act additively. The mutant promoters also displayed other characteristics, such as the activation of nascent promoter-like activities overlapping lac P1 and, in one case, replicon-dependent changes in promoter activity.

The products of the kdpDE operon are required for expression of the Kdp ATPase of Escherichia coli

The expression of the Kdp system for K+ uptake in Escherichia coli requires the products of two genes, kdpD and kdpE. These genes constitute an operon adjacent to the kdpABC operon that encodes the three membrane protein subunits of Kdp. Both operons are transcribed in the same direction and overlap; the kdpDE promoter is in kdpC, the last gene of the kdpABC operon. Transcription of the kdpDE operon is at a low level when Kdp is not expressed; transcription increases about 10-fold when kdpABC is turned on, indicating significant read-through of the kdpDE operon by transcripts beginning at the promoter of kdpABC operon. The proximal region of the kdpD gene is the site of most mutations that lead to constitutive expression of the kdpABC operon.

In vivo interaction of Escherichia coli lac repressor N-terminal fragments with the lac operator

Escherichia coli lac repressor is a tetrameric protein composed of 360 amino acid subunits. Considerable attention has focused on its N-terminal region which is isolated by cleavage with proteases yielding N-terminal fragments of 51 to 59 amino acid residues. Because these short peptide fragments bind operator DNA, they have been extensively examined in nuclear magnetic resonance structural studies. Longer N-terminal peptide fragments that bind DNA cannot be obtained enzymatically. To extend structural studies and simultaneously verify proper folding in vivo, the DNA sequence encoding longer N-terminal fragments were cloned into a vector system with the coliphage T7 RNA polymerase/promoter. In addition to the wild-type lacI gene sequence, single amino acid substitutions were generated at positions 3 (Pro3----Tyr) and 61 (Ser61----Leu) as well as the double substitution in a 64 amino acid N-terminal fragment. These mutations were chosen because they increase the DNA binding affinity of the intact lac repressor by a factor of 10(2) to 10(4). The expression of these lac repressor fragments in the cell was verified by radioimmunoassays. Both wild-type and mutant lac repressor N termini bound operator DNA as judged by reduced beta-galactosidase synthesis and methylation protection in vivo. These observations also resolve a contradiction in the literature as to the location of the operator-specific, inducer-dependent DNA binding domain.

Mutational analysis of the histidine operon promoter of Salmonella typhimurium

We isolated a collection of 67 independent, spontaneous Salmonella typhimurium his operon promoter mutants with decreased his expression. The mutants were isolated by selecting for resistance to the toxic lactose analog o-nitrophenyl-beta-D-thiogalactoside in a his-lac fusion strain. The collection included base pair substitutions. small insertions, a deletion, and one large insertion identified as IS30 (IS121), which is resident on the Mu d1 cts(Apr lac) phage used to construct the his-lac fusion. Of the 37 mutations that were sequenced, 14 were unique. Six of the 14 were isolated more than once, with the IS30 insertion occurring 16 times. The mutations were located throughout the his promoter region, with two in the conserved - 35 hexamer sequence, four in the conserved - 10 hexamer sequence (Pribnow box), seven in the spacer between the - 10 and -35 hexamer sequences, and the IS30 insertions just upstream of the -35 hexamer sequence. Four of the five substitution mutations changed a consensus base pair recognized by E sigma 70 RNA polymerase in the -10 or -35 hexamer. Decreased his expression caused by the 14 different his promoter mutations was measured in vivo. Relative to the wild-type promoter, the mutations resulted in as little as a 4-fold decrease to as much as a 357-fold decrease in his expression, with the largest decreases resulting from changes in the most highly conserved features of E sigma 70 promoters.

Cyclic-AMP-dependent switch in initiation of transcription from the two promoters of the Escherichia coli gal operon: identification and assay of 5'-triphosphate ends of mRNA by GTP:RNA guanyltransferase

We have studied the initiation of transcription of the gal operon in Escherichia coli (i) by analyzing the 5'-triphosphate ends and (ii) by measuring the level of promoter-proximal gal mRNA made in vivo. The 5' termini were identified and quantified by capping with GTP:mRNA guanyltransferase, and the mRNA levels were determined by hybridization of pulse-labeled [32P]RNA with a specific DNA probe. Our results conclusively demonstrate the in vivo activities of two promoters, P1 and P2, with separate initiation sites (S1 and S2) as suggested before from in vitro and in vivo experiments (S. Adhya and W. Miller, Nature [London] 279:492-494, 1979; R. E. Musso, R. DiLauro, S. Adhya, and B. de Crombrugghe, Cell 12:847-854, 1977). We have also studied the effect of cyclic AMP (cAMP) on in vivo gal transcription and found that whereas total gal transcription remains largely unchanged, the relative proportions of the S1 and S2 mRNAs are influenced by the level of cAMP in the cell. In strains devoid of cAMP (cya), transcription initiates equally at S1 and S2; in cAMP-proficient cells (cya+), the S1 initiation increases twofold with a concomitant decrease in S2 initiation. Addition of a saturating amount of exogenous cAMP to cya mutant cells results in a relatively larger switch from S2 to S1. Our results clearly show that while cAMP is an inhibitor of S2, it is not an absolute requirement for transcription initiation at S1, but only acts to increase low-level transcription from the P1 promoter. Using these approaches, we have also studied gal promoter mutants (P211, P18, and P35) which show altered behavior in transcription initiations and in response to cAMP. On the basis of these results, we have discussed models by which transcription initiates at the two overlapping gal promoters (P1 and P2) and discussed how cAMP level modulates the switch between them.

Cloning and nucleotide sequence of a gene for Actinomyces naeslundii WVU45 type 2 fimbriae

A genomic library of Actinomyces naeslundii WVU45 DNA in Escherichia coli was screened for antigen expression with rabbit antibody against A. naeslundii fimbriae. Western blotting (immunoblotting) of one recombinant clone carrying a 13.8-kilobase-pair insert revealed a 59-kilodalton (kDa) immunoreactive protein. A protein of similar electrophoretic mobility was detected from the isolated fimbrial antigen. Expression of the 59-kDa cloned protein in E. coli was directed by a promoter from the insert. The DNA sequence of the subunit gene was determined, and an open reading frame of 1,605 nucleotides was identified which was preceded by a putative ribosome-binding site and followed by two inverted repeats of 14 and 17 nucleotides, respectively. The reading frame encoded a protein of 534 amino acids (calculated molecular weight, 57,074), and the N-terminal sequence resembled that of a signal peptide. The presence of a 32-amino-acid signal peptide was indicated by amino-terminal sequencing of the fimbriae from A. naeslundii. The sequence, as determined by Edman degradation, was identical to that deduced from the DNA sequence beginning at predicted residue 33 of the latter sequence. Moreover, the amino acid composition of the predicted mature protein was similar to that of the isolated fimbriae from A. naeslundii. Thus, the cloned gene encodes a subunit of A. naeslundii fimbriae.

Mutations in the gene for EF-G reduce the requirement for 4.5S RNA in the growth of E. coli

A general strategy is described for the isolation of suppressors of essential genes whose functions are unknown. This strategy was used to analyze the role of 4.5S RNA, an essential RNA of E. coli. In this strategy, the structural gene for 4.5S RNA is fused to the Ptac promoter in such a way that the strain becomes dependent upon inducers of lac for growth. Mutants mapping to fus, the structural gene for protein synthesis elongation factor G, appear as spontaneous, inducer-independent revertants. These mutants alter the intracellular distribution of 4.5S RNA such that it sediments at 70S or greater. Furthermore, the increased sedimentation velocity is sensitive to the antibiotic puromycin. These results show that 4.5S RNA physically associates with the ribosome in performing its essential function, and that this association is mediated by elongation factor G.

Mutation that affects pepN translation initiation in Escherichia coli

Mutants altered in their expression of the hybrid pepN-lacZ gene have been selected for resistance to p-nitrophenyl-beta-D-thiogalactopyranoside (a bacteriostatic compound that enters the cells via lac permease). A unique mutation decreasing the level of pepN expression to 9% of that of the wild type has been studied in detail. This mutation controls in cis the expression of the pepN gene. The pepN region from a pepN-lacZ gene fusion has been cloned and sequenced. Comparison of the mutant and wild type sequences indicates that the mutation lies between the Shine-Dalgarno sequence (AGGT) and the initiation codon (AUG). This mutation is a T----C transition which might allow the formation of a stable secondary structure in the region of translation initiation thus decreasing the level of pepN expression.

Deletion analysis of RNA polymerase interaction sites in the Escherichia coli lactose operon regulatory region

Two sets of deletions produced in vitro by S1 nuclease were used to study the structure and function of promoters lacPUV5 and lacP115. The upstream boundary of the RNA polymerase binding site in lacPUV5 was determined by comparing the levels of beta-galactoside expression in vivo programmed from a set of deletions progressively extending into the -35 region of the lacPUV5 promoter. Sequences upstream from base-pair -37 are not necessary for the full functioning of lacPUV5. A deletion that removes base-pair -37 retains only half of the promoter activity. Deletion of the first T X A base-pair of the consensus -35 region sequence, 5' T-T-T-A-C-A 3', leads to a sixfold reduction of promoter activity. Deletion of the whole -35 region of lacPUV5 leads to at least a 20-fold reduction of its promoter activity. Abortive initiation assays were performed on the fully functional lacPUV5 and two lacPUV5 deletions, which removed part of the -35 consensus sequence, to study their effect on the kinetics of RNA polymerase-promoter open complex formation. These two deletions show a 3.5 to 7-fold reduction in KB. Analysis in vivo of lacP115 showed that sequence information upstream from the -35 region is important for the full functioning of lacP115. A deletion removing sequences upstream from -41 caused a three- to fourfold reduction in promoter activity, apparently due to reduced transcription initiation. lacP115 has a much lower k2 value than lacPUV5; its KB value is about threefold higher than that of lacPUV5.

Analysis of the occurrence of promoter-sites in DNA

We show that the occurrence and homology score (1) of promoter-sites in DNA depends upon the base composition of the DNA. We used simple probability theory to calculate the mean homology score expected for all promoter-sites that had a specific match in the canonical hexamers. By using the square root of this mean score as a measure of significance, we objectively classify all promoter-sites which are reported. We tested the theoretical approach in two ways. First, we used the program (PROMSEARCH) to analyze approximately 150,000 base pairs of random sequence DNA with different base compositions and we found excellent agreement with the theoretical predictions. Our second test was the analysis of a number of sequences drawn from the GENBANK DNA sequence database. We have analyzed 20 bacterial and bacteriophage sequences, which consisted of at least one operon, for promoter-sites. We found no absolute preference for promoter-sites within noncoding regions. We show the results of analyzing the phages lambda, T7 and fd, and the E. coli lac operon. The major known promoters in these sequences were all found correctly. We discuss the question of the location of a number of minor promoter-sites and show how PROMSEARCH can be used to help identify the correct location of the promoter. This approach can be applied to the search for any DNA site and should allow greater objectivity when comparing DNA sequences for meaningful subsequences.

lac Up-promoter mutants with increased homology to the consensus promoter sequence

Four lac promoter mutants were constructed. The mutations increased the homology between the lac promoter and the consensus promoter sequences by introducing the consensus -10 and -35 regions and the consensus spacing of 17 residues between these two regions. The promoter mutants were cloned into a pBR322-derivatized vector upstream from the lacZ gene, and levels of beta-galactosidase were an indication of promoter activity. All mutants exhibited higher activity than did the wild-type promoter.

Properties of lac P2 in vivo and in vitro. An overlapping RNA polymerase binding site within the lactose promoter

The Escherichia coli lac promoter has been shown to contain an RNA polymerase binding site (P2) that overlaps with, and is shifted 22 base-pairs upstream from the normal lac promoter (P1). In this paper, we provide RNA polymerase protection data obtained in vitro that show that, in the absence of CAP-cAMP, in vitro P2 is the preferred polymerase binding site on the P+ template. In the presence of CAP-cAMP, polymerase binding to P2 is reduced and more polymerase is bound at P1. Two lac P1 "-35 region" mutations, L157 and 4, which increase the homology between this region and the consensus "-10 region" sequence, are both shown to have an increased affinity for polymerase binding at P2. CAP-cAMP is also able to decrease the amount of polymerase bound to P2 and to increase the amount bound to P1 on these mutant promoter fragments. P2 does not initiate transcription efficiently in vivo. Nuclease S1 mapping experiments detect only a low level of transcription from one of the P2 "up" mutations, but no beta-galactosidase synthesis is directed by this mutant. Mutations such as L157 and 4, which alter the P2-10 region, also alter lac P sensitivity to CAP-cAMP in vivo, suggesting that the P2 sequence plays a role in CAP-cAMP regulation of lac P. Possible roles for P2 in vivo are discussed.

Lactose promoter mutation Pr115 activates an overlapping promoter within the lactose control region

The Escherichia coli lac promoter mutation Pr115, an A X T to T X A transversion at +1 (the transcription initiation site of the lac wild-type and lac UV5 promoters), creates a new "-10 region"-like sequence starting at +1. We show that this mutation activates a new RNA polymerase binding site (P115) that overlaps with, and is shifted 12 base-pairs downstream from, the wild-type RNA polymerase binding site (P1). Nuclease S1 mapping studies and RNA polymerase protection experiments in vitro indicate that, in the absence of CAP-cAMP, this new site is used preferentially over the P1 site. In vivo, beta-galactosidase assays of the Pr115 mutation in combination with mutations of the P1 "-35 region" demonstrate that the P1 -35 region sequences are not involved in the interaction between RNA polymerase and P115 in the absence of CAP-cAMP; therefore P115 is an independent binding site. The presence of CAP-cAMP in vivo stimulates polymerase binding and initiation at P1, which serves to block polymerase from binding at P115.

Dual promoter control of the Escherichia coli lactose operon

The control of transcription initiation at the lactose operon promoter was investigated in vitro. We found that an upstream promoter (termed lac P2) interfered with RNA polymerase binding at the principal promoter (termed lac P1). The start site for lac P2 was located at base pair position -22 relative to the P1 start site. The addition of cAMP receptor protein and cAMP was shown to repress lac P2 and to activate lac P1. Abortive initiation reactions for both promoters were used to investigate the coordinate repression-activation elicited by CRP-cAMP. The effects of lac promoter mutations (L8, Ps, and UV5) were consistent with an important RNA polymerase positioning role for CRP-cAMP in the activation of lac operon expression.

Mutations that alter the DNA sequence specificity of the catabolite gene activator protein of E. coli

Three mutations that alter the DNA sequence specificity of the catabolite gene activator protein (CAP) from AA-TGTGA--T---TCA-ATW to AA-TGTAA--T---TCA-ATW have been isolated. All three mutations affect the same amino acid of CAP, glutamic acid 181. We propose that it is this amino acid of CAP that makes contacts with base pairs 7 and 16 of the symmetrical recognition site.

Point mutations that reduce the expression of malPQ, a positively controlled operon of Escherichia coli

malPQ is one of three operons controlled by the positive regulator gene malT. With the objective of defining DNA sequences essential for malPQ transcription, we looked for cis-dominant mutations that reduced the level of expression of this operon. We first constructed malP-lac fusion strains, selected from one of them a series of mutants resistant to p-nitrophenyl-beta-D-thiogalactopyranoside (a bacteriostatic compound that enters the cells via lac permease), and retained the clones that contained a mutation reducing the expression of the hybrid operon in a cis-dominant fashion. Nineteen such mutations were sequenced, and their effect on an otherwise wild type malPQ operon was studied. Three of them mapped in a transcribed portion of the operon, and are believed to exert their effect at the translation level. The others map upstream from the transcription startpoint (co-ordinate +1) and help define three DNA segments that must play a predominant role in transcription initiation: the Pribnow box (from positions -7 to -12); and two inverted repeats, extending from position -32 to -36, and -59 to -63, respectively, which are proposed to constitute part of the binding site for MalT protein.

Cyclic AMP receptor protein: role in transcription activation

The structure of this pleiotropic activator of gene transcription in bacteria and its interaction sites at promoter DNA's as well as the role of this protein in the RNA polymerase-promoter interactions are reviewed.

Analysis of the cya locus of Escherichia coli

A 9500-bp DNA segment containing the adenylate cyclase gene (cya) of Escherichia coli has been isolated and analyzed. Four large proteins are encoded within this fragment - the adenylate cyclase protein (92 kDal), two proteins of unknown function (37 and 32 kDal), and a part of the uvrD-coded protein. Various truncated adenylate cyclase proteins, made from cya genes having as much as 60% of their carboxy-terminal end deleted, are sufficient to complement cya- hosts. When these truncated cya genes are present on a multicopy plasmid in a cya- host, the synthesis of beta-galactosidase is still regulated by glucose. The "maxicell" technique was used to visualize the four proteins encoded by this region and some of the truncated adenylate cyclase proteins.

CAP and RNA polymerase interactions with the lac promoter: binding stoichiometry and long range effects

The binding stoichiometries of the complexes formed when the E. coli cyclic AMP receptor protein (CAP) binds to 203 bp lac promoter-operator restriction fragments have been determined. Under quantitative binding conditions, a single dimer of CAP occupies each of two sites in the promoter. Different electrophoretic mobilities are observed for 1:1 complexes formed with L8-UV5 mutant, L305 mutant, and wild type promoter fragments, indicating sequence-specific structural differences between the complexes. The differences in gel mobility between L8-UV5 and wild type complexes disappear when the promoter fragments are cleaved with Hpa II restriction endonuclease. Models in which CAP alters DNA conformation or in which CAP forms a transient intramolecular bridge between two domains of a DNA molecule could account for these observations. The selective binding of RNA polymerase to CAP-promoter complexes is demonstrated: the binding of a single CAP dimer to the promoter is sufficient to stimulate subsequent polymerase binding. Functional CAP molecules are not released from the promoter on polymerase binding.

Fusion of the lac genes to the promoter for the aminopeptidase N gene of Escherichia coli

Strains of Escherichia coli K12 were isolated in which the lac structural genes were fused to the promoter for the aminopeptidasee N structural gene (pepN). Although this enzyme is constitutively produced, the differential rate of synthesis is increased about 4-fold upon phosphate starvation. The pepN-lac fusions were shown to respond to phosphate specific regulatory signals. A plaque forming lambda transducing phage bearing the pepN-lac fusion was isolated. This phage was used to prove genetically the fusion of lac genes to the promoter for the aminopeptidase. These results demonstrate a control at the transcriptional level of aminopeptidase synthesis.

In vitro construction of the tufB-lacZ fusion: analysis of the regulatory mechanism of tufB promoter

To investigate the regulatory mechanism of the tufB operon, we have constructed plasmids in which the lac structural genes have been fused to the regulatory region and the 5'-coding sequence of the tufB gene. The fusion was performed by incorporating the 6.6 kb EcoRI-HpaI fragment of plasmid pTUB1, which carried the tufB gene (Miyajima et al. 1979), into the EcoRI and SmaI sites of pMC1403 lac fusion vector (Casadaban et al. 1980). This gene fusion resulted in the production of a hybrid protein consisting of the N-terminal portion (12 amino acid residues) of EF-TuB and the enzymatically active C-terminal half of beta-galactosidase. Bacteria harboring the recombinant plasmid showed a strong Lac+ phenotype. In such a fusion, the lac gene expression was under the control of the tufB promoter. This was evidenced by the following observations; (i) the tufB-lacZ hybrid protein was synthesized constitutively; (ii) its production augmented in parallel with the increase in growth rate; and (iii) on carbon-source upshift, the hybrid protein was produced at a rate 2.5-fold higher than that of the mass increase. Several derivatives of this recombinant plasmid harboring deletions and/or inversions in the tufB regulatory region have been constructed and their properties are described.

In vivo role of the relA+ gene in regulation of the lac operon

Under conditions of amino acid limitation, beta-galactosidase was produced at a 70-fold higher rate in a relA+ strain than in an isogenic relA strain of Escherichia coli K-12. Under identical conditions with the relA+ and relA strains carrying various lac promoter mutations, rates of beta-galactosidase synthesis in relA+ (relative to relA) ranged from 26-fold higher (promoter mutant Pr 13) to only 5-fold higher (promoter mutant PrL8uv5). This promoter specificity was independent of strain background and the means of eliciting amino acid limitation. Addition of cyclic AMP to the growth medium altered the relA+/relA difference for beta-galactosidase synthesis from the wild-type lac promoter. The experiments suggest that the relA+/relA difference in lac expression arises primarily at the point of transcription initiation. The results are discussed in relation to recent in vitro data showing a promoter-specific guanosine 5'-diphosphate 3'-diphosphate stimulation of lac transcription (P. Primakoff and S. W. Artz, Proc. Natl. Acad. Sci. U.S.A. 76:1726-1730).

Alterations in two conserved regions of promoter sequence lead to altered rates of polymerase binding and levels of gene expression

Characterization of recombinant lac promoters highlights the importance of two regions of sequence conservation in promoters. The "Pribnow box" sequences are necessary for specific transcription in this system. This specificity is maintained when a mutated upstream sequence is introduced. However, changing the upstream DNA sequences influences both the rate of RNA polymerase binding in vitro and levels of expression in vivo.

Integration of specialized transducing bacteriophage lambda cI857 St68 h80 dgnd his by an unusual pathway promotes formation of deletions and generates a new translocatable element

Molecular and genetic studies have revealed that several illegitimate recombinational events are associated with integration of the specialized transducing bacteriophage lambda cI57 St68 h80 dgnd his into either the Escherichia coli chromosome or into a plasmid. Most Gnd+ His+ transductants did not carry the prophage at att phi-80, and 10% were not immune to lambda, i.e., "nonlysogenic." Integration of the phage was independent of the phage Int and Red gene products and of the host's general recombination (Rec) system. In further studies, bacterial strains were selected which carried the phage integrated into an R-factor, pSC50. Restriction endonuclease analysis of plasmid deoxyribonucleic acid (DNA) purified from these strains showed that formation of the hybrid plasmids resulted from recombination between a single region of pSC50 and one of several sites within the lambda-phi 80 portion of the phage. Furthermore the his-gnd region of the phage, present in the chromosome of one nonlysogenic transductant, was shown to be able to translocate to pSC50. Concomitant deletion of phage DNA sequences or pSC50 DNA was frequently observed in conjunction with these integration or translocation events. In supplemental studies, a 22- to 24-megadalton segment of the his-gnd region of the chromosome of a prototrophic recA E. coli strain was shown to translocate to pSC50. One terminus of this translocatable segment was near gnd and was the same as a terminus of the his-gnd segment of the phage which translocated from the chromosome of the nonlysogenic transductant. These data suggest that integration of lambda cI857 St 68 h80 dgnd his may be directed by a recombinationally active sequence on another replicon and that the resulting cointegrate structure is subject to the formation of deletions which extend from the recombinationally active sequence. Translocation of the his-gnd portion of the phage probably requires prior replicon fusion, whereas the his-gnd region of the normal E. coli chromosome may comprise a discrete, transposable element.

Interaction between mutant alleles of araC of the Escherichia coli B/r L-arabinose operon

Strains were constructed that contain mutational alterations affecting two distinct functional domains within the araC gene protein. The araCi (catabolite repression insensitivity) and araCh (catabolite repression hypersensitivity) mutations were used to alter the catabolite repression sensitivity domain, and mutation to D-fucose resistance was used to alter the inducer binding domain. araCh, D-fucose-resistant double mutants never exhibited constitutive ara operon expression, whereas all of the araCi, D-fucose-resistant double mutants did exhibit constitutivity. When L-arabinose was used as an inducer, most of the double mutants exhibited the sensitivity to catabolite repression associated with the araCi or araCh mutation. However, when D-fucose was used as an inducer, changes in sensitivity to catabolite repression were observed that were attributed to interactions between the two protein domains. The roles of catabolite activator protein and araC gene protein in the induction of the araBAD operon were discussed.

Promoter-like mutants with increased expression of the Escherichia coli uridine phosphorylase structural gene

From an Escherichia coli K-12 strain lacking adenylate cyclase (cya) and cyclic AMP receptor protein (crp), two mutants were isolated that synthesize uridine phosphorylase constitutively. The mutations differ from one another and also from a wild type in the maximum rate of uridine phosphorylase synthesis. They have constitutive expression of the uridine phosphorylase gene (udp) in the presence of repressor protein coded by the cytR regulatory gene and decrease the sensitivity of the udp gene simultaneously with catabolite repression. Both mutations cause a high level of udp expression whether they are in a cya crp or in a cya+ crp+ background. Another mutation (udpP1) isolated previously alters the response of udp gene to the ctyR repressor and produces a higher constitutive level of uridine phosphorylase in a cytR+ than in a cytR background when bacteria are grown in glucose. The synthesis of uridine phosphorylase in this mutant is dependent on an intact cyclic AMP-cyclic AMP receptor protein complex. All mutations studied are cis-acting and extremely closely linked to the udp structural gene, and appear to affect the uridine phosphorylase promoter-operator region. The data obtained are in accordance with a suggestion that the cytR repressor protein normally asserts its function by preventing the positive action of cyclic AMP-cyclic AMP receptor protein complex.

Reduced expression of a distal gene of the prn gene cluster in deletion mutants of Aspergillus nidulans: genetic evidence for a dicistronic messenger in an eukaryote

The prn gene cluster involved in L-proline catabolism in Aspergillus nidulans, has the gene order prnA-prnD-regulatory region-prnB-prnC. prnB, prnD, and prnC specify proline permease, proline oxidase, and delta1-pyrroline-5-carboxylate (P5C) dehydrogenase, respectively. prnA is probably a positive regulatory gene whose product is necessary for expression of the prn activities. Proline induces proline permease and P5C dehydrogenase in prnD- mutants which lack proline oxidase, showing that proline does not have to be converted to P5C to act as inducer. Deletion mutations extending from within prnD to within prnB result in considerably reduced expression of prnC, whereas a prnD- prnB- double mutant shows normal prnC expression. This strongly suggests that the deletion mutations eliminate a promotor/initiator site for transcription of a dicistronic messenger for prnB and prnC. The fact that the deletions do not eliminate prnC expression altogether indicates that at least one other species of prnC transcript (monocistronic, tricistronic, or tetracistronic) can be made.

Mutations in the L-arabinose operon of Escherichia coli B/r with reduced initiator function

Partial reversion mutants derived from a strain containing a strongly polar initiator-defective mutation (araI1036) in the L-arabinose operon were found to have several characteristics expected of mutants with reduced initiator function. These reversion mutations are cotransduced with the ara region and are probably within the araI region. Furthermore, they permit induction of the L-arabinose operon to a level only one-third of the normal wild-type level. These partially functional initiator regions reduce the expression of structural genes in the cis position only; they function quite independently of wild-type or defective initiator regions in the trans position. These mutants exhibit a two- to threefold increase in the rate of expression of ara operon genes within one-tenth of a generation after a shift of the growth temperature from 28 to 42 degrees C. This suggests that the temperature optimum for initiation of operon expression is higher for the partial revertant strains than it is for strains containing a wild-type initiator region.

The mechanism of inhibition of bacteriophage T7 RNA synthesis by acridines, diacridines and actinomycin D

A homologous series of diacridines, as well as 9-amino acridine, were assayed for their ability to interfere with the synthesis of RNA (bands U-VI) by bacteriophage T7 DNA-dependent RNA polymerase transcribing T7 DNA in vitro; their action was compared to that of actinomycin D. It was found that, in contrast to actinomycin D which inhibits chain elongation, the acridines tested inhibited chain initiation only; no evidence for inhibition of chain elongation was noted. No clear-cut differentiation between single and double intercalators on the mechanism of inhibition of RNA synthesis could be determined, except that the latter are more potent inhibitors. However, it appears that diacridines connected with a diethyldiamine and a butyldiamine chain are less inhibitory to the synthesis of the RNA of Bands III and IV. The results furthermore indicate that the estimation of the number average molecular weight alone, without identification of the product RNA, is a potentially misleading method of determining the mode of action of these drugs.

Isolation of specialized transducing bacteriophages carrying deletions of the regulatory region of the Escherichia coli K-12 tryptophan operon

A lysogen of a wild-type strain of Escherichia coli K-12 carrying a heat-inducible lambda-phi80 hybrid prophage was induced to yield transducing phages carrying all of the structural genes of the tryptophan operon. The presence or absence of elements of the trp regulatory region was determined by examining the effects of lambda genes N and cI on trp gene expression. The phages were further characterized by transduction studies and by examining anthranilate synthetase (EC 4.1.3.27) (TRYPE+D) synthesis in the presence of the lambda cI product. A number of phages deleted for the trp promoter were found. Recombination studies between trpOc bacteria and the transducing phages have yielded information that can be used to order the trp end points of some phages and to provide an estimate of the size of the trp promoter region.