Regulated in Vitro Synthesis of Escherichia coli Tryptophan Operon Messenger Ribonucleic Acid and Enzymes

Cell-free protein synthesis system: A new frontier for sustainable biotechnology-based products

Cell-free protein synthesis (CFPS) system is an innovative technology with a wide range of potential applications that could challenge current thinking and provide solutions to environmental and health issues. CFPS system has been demonstrated to be a successful way of producing biomolecules in a variety of applications, including the biomedical industry. Although there are still obstacles to overcome, its ease of use, versatility, and capacity for integration with other technologies open the door for it to continue serving as a vital instrument in synthetic biology research and industry. In this review, we mainly focus on the cell-free based platform for various product productions. Moreover, the challenges in the bio-therapeutic aspect using cell-free systems and their future prospective for the improvement and sustainability of the cell free systems.

Cell-Free Escherichia coli Synthesis System Based on Crude Cell Extracts: Acquisition of Crude Extracts and Energy Regeneration

Cell-free synthetic biology is advancing with unprecedented control and design. The development of cell-free biosynthesis involves both pure enzyme and crude enzyme systems. The relatively cheap crude enzyme system is more suitable for the scientific research needs of ordinary laboratories. The key factor in giving full play to the advantages of the system is to obtain high-quality cell crude extract and its energy regeneration system, but there is no systematic report on the development history of these two aspects. Therefore, in this paper, the development history of the process of obtaining crude extract from cell-free biosynthesis was carried out based on Escherichia coli, which is widely used at present, and the energy regeneration system was briefly introduced. Finally, the challenges of current cell-free synthetic systems are discussed.

Cell-free protein synthesis: advances on production process for biopharmaceuticals and immunobiological products

Biopharmaceutical products are of great importance in the treatment or prevention of many diseases and represent a growing share of the global pharmaceutical market. The usual technology for protein synthesis (cell-based expression) faces certain obstacles, especially with 'difficult-to-express' proteins. Cell-free protein synthesis (CFPS) can overcome the main bottlenecks of cell-based expression. This review aims to present recent advances in the production process of biologic products by CFPS. First, key aspects of CFPS systems are summarized. A description of several biologic products that have been successfully produced using the CFPS system is provided. Finally, the CFPS system's ability to scale up and scale down, its main limitations and its application for biologics production are discussed.

Cell-Free Synthetic Biology: Engineering Beyond the Cell

Cell-free protein synthesis (CFPS) technologies have enabled inexpensive and rapid recombinant protein expression. Numerous highly active CFPS platforms are now available and have recently been used for synthetic biology applications. In this review, we focus on the ability of CFPS to expand our understanding of biological systems and its applications in the synthetic biology field. First, we outline a variety of CFPS platforms that provide alternative and complementary methods for expressing proteins from different organisms, compared with in vivo approaches. Next, we review the types of proteins, protein complexes, and protein modifications that have been achieved using CFPS systems. Finally, we introduce recent work on genetic networks in cell-free systems and the use of cell-free systems for rapid prototyping of in vivo networks. Given the flexibility of cell-free systems, CFPS holds promise to be a powerful tool for synthetic biology as well as a protein production technology in years to come.

Effect of different conformations of galactose messenger RNA on gene expression and messenger half-life in vitro

From a DNA-directed cell-free system, functional gal mRNA is obtained which directs the cell-free synthesis of the three galactose enzymes of Escherichia coli. A substantial fraction of this gal mRNA has the properties of a polycistronic messenger. Exposure to elevated temperatures in the presence or absence of magnesium ion results in pronounced changes of the capacity of this mRNA to give rise to the synthesis of the three enzymes. Depending on the conditions of the pre-treatment, the absolute amounts as well as the ratio of the three gene products synthesized can be changed. The different forms of gal messenger so obtained also exhibit different susceptibilities towards functional inactivation during the enzyme synthesis reaction. As the changes in template activity are reversible, it is concluded that the different treatments cause reversible transitions between different conformations of the gal mRNA.

In vitro insertion of leader peptidase into Escherichia coli membrane vesicles

Leader peptidase is an integral protein of the Escherichia coli cytoplasmic membrane whose topology is known. We have taken advantage of this knowledge and available mutants of this enzyme to develop a genetic test for a cell-free protein translocation reaction. We report that leader peptidase inserted into inverted plasma membrane vesicles in its correct transmembrane orientation. We have examined the in vitro membrane assembly characteristics of a variety of leader peptidase mutants and found that domains required for insertion in vivo are also necessary for insertion in vitro. These data demonstrate the physiological validity of the in vitro insertion reaction and strengthen the use of this in vitro protein translocation reaction for the dissection of this complex sorting pathway.

Specificity of the attenuation response of the threonine operon of Escherichia coli is determined by the threonine and isoleucine codons in the leader transcript

Expression of the threonine (thr) operon enzymes of Escherichia coli is regulated by an attenuation mechanism. The regulatory portion of the operon contains a region coding for a leader peptide that contains consecutive threonine and isoleucine codons. It is thought that translation of the leader peptide controls the frequency of transcription termination at the attenuator site. Using oligonucleotide-directed site-specific mutagenesis we have altered the putative control codons of the leader peptide coding region. In two of the mutants the threonine and isoleucine codons were changed to produce peptides containing histidine and tyrosine codons. Both mutants showed loss of regulation by threonine and isoleucine. A hisT mutation, which leads to an undermodification of tRNA(His), increased thr operon expression in the mutants threefold but did not affect expression of the wild-type thr operon. Two other mutants were constructed that contained two histidine codons early in the leader peptide. Expression in both of these mutants was unaltered by the presence of the hisT allele or by the addition of threonine and isoleucine to the growth medium. In addition, a wild-type strain containing a temperature-sensitive threonyl-tRNA synthetase mutation showed increased thr operon expression at the non-permissive temperature, whereas none of the mutants showed any change. Taken together these data indicate that the specificity of the attenuation response is effected by specific control codons within the thr leader peptide coding region. We have also directly demonstrated thr leader peptide synthesis in vitro using a plasmid encoding the wild-type thr leader region to direct the synthesis of a peptide of the appropriate molecular weight when labeled with [3H]threonine but not with [3H]histidine or [3H]tyrosine. Conversely, when extracts were incubated with templates containing the mutated DNAs, peptides were labeled that showed patterns consistent with the expected amino acid compositions. These data indicate that the thr leader RNA is translated into the predicted leader peptide.

Regulation of expression of the cloned repE gene from the F plasmid of Escherichia coli

The repE gene of the Escherichia coli F plasmid has been fused to an N-terminal fragment of the Salmonella typhimurium araB gene in the plasmid expression vector pING1. A fusion protein is expressed at high levels upon addition of arabinose to E. coli hosts containing the recombinant plasmid and has been purified to homogeneity. Antibodies prepared against the fusion protein react with both araB' and repE-coded proteins and can be used to detect their synthesis by immunoblotting methods. In vitro as well as in vivo expression of the repE gene from chimeric plasmids indicate a very tight control of the expression of this replication initiator protein.

The cytoplasmic carboxy terminus of M13 procoat is required for the membrane insertion of its central domain

The M13 coat protein spans the Escherichia coli plasma membrane with its amino-terminus facing the periplasm. It is made as a precursor--the procoat--with a typical leader peptide. Mutations which destroy the basic character of the carboxy-terminal domain of procoat, a domain which is oriented towards the cytoplasm, block membrane assembly, while insertion of three lysyl residues near the carboxy terminus partially restores assembly. Thus the information specifying membrane insertion of M13 procoat protein is found in its mature region as well as the leader and is not simply decoded in an amino to carboxy direction.

Prokaryotic gene expression in vitro: transcription-translation coupled systems

Transcription-translation coupled systems have been developed to study prokaryotic gene expression. Several types of expression system have been described. The original system consists of a crude unfractionated Escherichia coli extract, which supports protein synthesis directed by a template DNA. Control of gene expression at the transcriptional stage has been studied using this unfractionated system. In this respect, two examples of particular interest, lactose and tryptophan operons, are described. Other systems are either partially reconstituted or highly defined, containing up to 30 purified factors necessary for transcription (RNA polymerase) and translation (aminoacyl-tRNA synthetases, initiation, elongation and release factors). Additional differences between the various systems relate to the analysis of the gene products. Whereas most methods involve analysis of the totally synthesized protein, a particular system implies the formation of only the N-terminal di- or tripeptide of the gene product. Reconstituted systems have proved useful in studies on transcriptional, e.g., discovery and role of L factor, as well as translational regulation of gene expression, e.g., autogenous control of ribosomal protein synthesis.

Transcription of the Escherichia coli fumarate reductase genes (frdABCD) and their coordinate regulation by oxygen, nitrate, and fumarate

The fumarate reductase enzyme complex allows Escherichia coli to grow anaerobically with fumarate as a terminal electron acceptor for oxidative phosphorylation when the preferred compounds oxygen and nitrate are not available. We used the pKO promoter test vectors to identify a single promoter for the frdABCD genes which encode fumarate reductase. Expression of galactokinase from the frd promoter-galK operon fusion plasmid was repressed by oxygen and by nitrate and was induced by fumarate, indicating that frd gene expression is regulated at the transcriptional level by these terminal electron acceptors. S1 nuclease analysis, using a single-stranded DNA probe from the frd promoter region and mRNA isolated from a fumarate reductase-induced culture, revealed that the frd mRNA transcript initiates with an adenine residue 93 bases prior to the start of frdA translation. No promoters internal to the frd genes were revealed with the plasmid promoter screening system. S1 nuclease analysis revealed that the frd mRNA terminates in a uridine-rich region centered at 46 bases after the last codon of frdD. A stem and loop structure previously described as the growth rate-dependent attenuator for the linked ampC gene precedes the frd mRNA terminus. This result confirms the proposal that the stem and loop structure serves the dual role of a frd terminator anaerobically and an ampC attenuator aerobically. The four frd genes encoding the subunits of the fumarate reductase complex thus comprise an operon which is regulated at the transcriptional level in response to the cellular availability of the alternate electron acceptors oxygen, nitrate, and fumarate.

Phosphate-specific transport system of Escherichia coli: nucleotide sequence and gene-polypeptide relationships

The DNA nucleotide sequence of four genes for the phosphate-specific transport system of Escherichia coli is reported. Along with the DNA sequence for the phoS gene reported previously (Surin et al., J. Bacteriol. 157:772-778, 1984; Magota et al., J. Bacteriol. 157:909-917, 1984), this study completes the nucleotide sequence of the phosphate-specific transport region. The complete sequence (including phoS) contains five open reading frames oriented in the same direction, each preceded by a putative ribosome-binding site near the presumed translation initiation codon ATG. The complete sequence is transcribed counterclockwise, in the order phoS pstC pstA pstB phoU. Genetic complementation shows that of the four open reading frames in the new sequence, three correspond to known mutant alleles; the fourth, which was designated pstC, has not been described before and could not be related to any known mutant allele. We have confirmed that pstA was allelic to phoT32. The pstC, pstB, and phoU gene products were identified as peripheral membrane proteins. The pstA gene product appears to be an integral membrane protein.

In vivo 5' terminus and length of the mRNA for the proton-translocating ATPase (unc) operon of Escherichia coli

The promoter for the proton-translocating ATPase (unc) operon of Escherichia coli was localized by using a plasmid promoter-screening vector system. S1 nuclease analysis, using the appropriate single-stranded DNA probe from this promoter region and in vivo mRNA, revealed that the 5' end of the in vivo unc mRNA initiates with a guanine residue 73 bases before the start of the proposed gene 1 or 474 bases before uncB. An in vivo unc mRNA species of approximately 7,000 nucleotides in length which initiates in the unc promoter region was shown to exist by RNA-DNA hybridization analysis. This unc mRNA species (based on DNA sequence analysis) is sufficient in length to contain all nine genes, gene 1 and uncBEFHAGDC. That gene 1 is cotranscribed with the unc genes was confirmed by using hybridization probes containing the promoter-proximal (gene 1) or -distal gene (uncC). No strong internal promoters within the unc operon were revealed with either the promoter-screening vector system or the RNA-DNA hybridization analysis. The 5' terminus and the length of the unc mRNA were found to be identical in cells grown either aerobically or anaerobically. The level of unc operon expression, as assayed with the unc promoter plasmid, did not significantly differ when cells bearing the plasmid were grown either aerobically or anaerobically.

Characterization of the Escherichia coli gene for serine hydroxymethyltransferase

Plasmid pGS1 carries the Escherichia coli glyA gene and its neighboring regions on a 13-kb EcoRI insert. In a cell-free transcription-translation system, the insert directs the synthesis of two polypeptides with Mr values of about 46 500 and 45 500. When the glyA gene is inactivated with the transposable element Tn5, the Mr 46 500 polypeptide is not observed, identifying it as the glyA gene product. The Mr 45 500 polypeptide is the product of an unknown gene designated gene X. When plasmids with random insertions of the Tn5 element in either the glyA gene or gene X are used as templates in the cell-free transcription-translation system, the polypeptides observed are smaller than the glyA or X gene products. A comparison of the site of each Tn5 insertion within the glyA gene or within gene X and the size of the polypeptide observed in the cell-free system enabled us to determine the direction of transcription and translation of both genes. The glyA gene is transcribed and translated in a direction opposite to that of gene X. Nucleotide sequencing confirmed the location and orientation of the two genes in the insert. DNase I footprinting experiments defined the glyA gene and gene X control regions recognized by RNA polymerase, and S1 nuclease mapping experiments located the transcription start point for each gene. The transcription start points for the two genes are 216 bp apart, and the translation start sites are 327 bp apart. Less than 90 bp separate the two RNA polymerase molecules bound to the two promoters.

Role of primary structure and disulfide bond formation in beta-lactamase secretion

Plasmid pBR322-encoded beta-lactamase was shown to contain a single disulfide bond, which caused the protein to migrate faster in sodium dodecyl sulfate-polyacrylamide gels than the fully reduced form. A similar difference in mobility of the in vitro synthesized precursor before and after reduction indicates that it also contained a disulfide bond. Formation of the disulfide bond in vivo, however, occurred concomitant with processing. In vivo accumulation of the precursor by inhibition of secretion did not allow disulfide bond formation to occur. This result is consistent with post-translational translocation of the precursor. Synthesis of a fragment of beta-lactamase lacking the carboxy terminus was obtained by insertion of a foreign DNA segment into the PstI site of bla. Processing and secretion of the protein did not appear to be greatly affected, indicating that the carboxy terminus is not required for secretion.

Differential polypeptide synthesis of the proton-translocating ATPase of Escherichia coli

We investigated the regulation of the synthesis of the eight polypeptides of the Escherichia coli proton-translocating ATPase. A plasmid carrying the eight genes of the unc operon was used to direct in vivo and in vitro protein synthesis of the eight polypeptides. Analysis of these data indicates that the ATPase polypeptides are synthesized in unequal amounts both in vitro and in vivo. We identified several regions within the unc operon at which expression of a gene is either increased or decreased from that of the preceding gene. Since genetic information indicates a single polycistronic mRNA for all eight genes of this operon, the observed differential synthesis of the polypeptides is most likely the result of translational regulation. The effect of varying the temperature suggests that the secondary structure in the mRNA may affect the rate of translation initiation in the region between uncE and uncF.

Cloning of small DNA fragments containing the Escherichia coli tryptophan operon promoter and operator

A41-bp AluI restriction fragment from the trp promoter-operator region has been cloned into the PvuII site of pBR322, regenerating PvuII sites. Transformants were selected on media that allowed the selection of trp-operator-bearing plasmids. The cloned 41-bp fragment can be released from the vector by PvuII digestion, and it possesses a functional promoter and operator as demonstrated by in vivo tests. The 41-bp fragment contains several restriction sites: HincII, TaqI, RsaI, and a HpaI site that is located at the center of the operator sequence. Two new operator derivatives, symmetrical about the HpaI site, were prepared from the 41-bp fragment by joining two right-side, or two left-side PvuII-HpaI pieces together at the HpaI site. These derivatives showed in vivo operator activity. Plasmids containing up to five copies of the 41-bp trp-promoter-operator fragment have been constructed. These plasmids should be useful in preparing large amounts of the 41-bp fragment.

Speed-accuracy relationships during in vitro and in vivo protein biosynthesis

Poly U-directed incorporation of phenylalanine and leucine into polypeptide has been described in at least 50 papers since 1961. In general, high translation activities are associated with high accuracies, and vice-versa. Moreover, a vast body of independent experimental data (effect of ethanol, temperature, urea, aminoglycosides, etc... on protein synthesis) put together here suggests that, in many circumstances, speed and accuracy of elongation are correlated. This result is to be contrasted with the view that the speed and the fidelity of protein synthesis are two opposing parameters. In this report, recent experimental data on the nature and effect of ribosomal ambiguity (ram) and streptomycin resistance (Strr) mutations are reexamined. Models on the action of streptomycin and other misreading-inducing antibiotics, as well as long-standing ideas on the control of misreading in mammalian systems are critically evaluated. An explanation is provided for the long-befuddling data on the action of gentamicin.

Subunits of the adenosine triphosphatase complex translated in vitro from the Escherichia coli unc operon

The unc operon of Escherichia coli was split into two fragments by the restriction endonuclease HindIII. The operator-proximal portion was cloned into plasmid pACYC184, forming plasmid pAN51, which included the genes uncB, uncE, and uncA. When plasmid pAN51 was used as template in an in vitro transcription/translation system, the alpha subunit (from the uncA gene) and delta subunit of the F(1) adenosine triphosphatase (ATPase) were formed. In addition, three polypeptides of molecular weights 18,000, 17,000, and 14,000 were formed, and the significance of these polypeptides is discussed. The operator-distal portion of the unc operon was also cloned into plasmid pACYC184, forming plasmid pAN36, which included the uncD and uncC genes. When this plasmid was used as template in an in vitro transcription/translation system, the beta subunit (from the uncD gene) and the epsilon subunit (from the uncC gene) of the F(1) ATPase were formed. A polypeptide of a molecular weight similar to the epsilon subunit but of different net charge was also formed. Plasmid pAN45, carrying the complete unc operon, was isolated after digestion of a mixture of plasmids pAN51 and pAN36 with the restriction endonuclease HindIII and then religation with T4 deoxyribonucleic acid ligase. It was concluded that a HindIII restriction site occurred within the newly described uncG gene, which was shown, by complementation studies with Mu-induced mutants, to be located between the uncA and uncD genes to give the gene order uncBEAGDC. The uncG gene appears to code for the gamma subunit of the F(1) ATPase.

The in vitro synthesis and processing of the branched-chain amino acid binding proteins

The synthesis of the leucine-specific and LIV-binding proteins was examined in vitro in a coupled transcription/translation system using the hybrid plasmids pOX7 and pOX13 as templates. Plasmid pOX7 contains the livK gene coding for the leucine-specific binding protein and pOX13 contains the livJ gene coding for the LIV-binding protein. Both binding proteins were synthesized in vitro as precursor forms with molecular weights approximately 2,500 greater than their respective mature forms. Conversion of the precursor forms to their mature forms occurred during post-translational incubation following synthesis in the presence of membrane. The precursor of the LIV-binding protein was processed more rapidly than the leucine-specific binding protein precursor. Processing activity could be removed from the in vitro synthesis system by centrifugation, suggesting that the processing activity was membrane associated. Restoration of post-translational processing activity was achieved by adding inside-out membrane vesicles to membrane-depleted reaction mixtures.

Structural and functional analysis of cloned deoxyribonucleic acid containing the trpR-thr region of the Escherichia coli chromosome

Specialized transducing phages containing the thr-trpR region of the Escherichia coli chromosome were derived from a strain with lambda prophage inserted in thr. Cloning of segments of the chromosomal deoxyribonucleic acid of one such lambda thr + trpR+ phage in various plasmid vectors established that a 1.3-kilobase BamHI fragment carried trpR+ intact. Strains with a multicopy plasmid vector containing the BamHI insert produced 20-fold-higher levels of trp aporepressor than did the wild-type strain of Escherichia coli. Similarly, induction of lambda thr + trpR+ lysogens resulted in increased aporepressor levels. The 1.3-kilobase trpR+ BamHI fragment was inserted in either orientation downstream from lambda pLN in a plasmid vector in which transcription from lambda pL was under the control of a temperature-sensitive lambda repressor. Induction established the orientation of transcription of trpR and led to the production of 100-fold-increased levels of trp aporepressor. A presumptive 23,500-dalton trpR+ polypeptide was detected by using lambda pLNtrpR+ plasmid deoxyribonucleic acid in a cell-free transcription-translation system.

Translational fidelity and specificity of ribosomes cleaved by cloacin DF13

The effect of cloacin DF13 cleavage on several functional properties of the ribosome has been studied in a translational system in vitro. Cleaved ribosomes synthesize relatively shorter polypeptide chains on synthetic and natural templates. Their translational specificity is, however, unchanged as judged by the read-out of MS2 RNA. Here, cleaved as well as control ribosomes start translation only on the coat cistron of the phage RNA. Cloacin cleavage of ribosomes increases their fidelity of translation. Differential inhibition of translation of synthetic and natural template was not observed.

Translation of the leader region of the Escherichia coli tryptophan operon

When the trp operon of Escherichia coli contains either of two deletions that fuse the initial portion of the leader region to the distal segments of the trpE gene, novel fusion polypeptides are produced. The new polypeptides are synthesized efficiently both in vivo and in vitro, and their synthesis is subject to repression by trp repressor. Fingerprint analyses of tryptic and chymotryptic digests of the new polypeptides show that both contain trpE polypeptide sequences and, despite their different sizes, share the same N-terminal sequence. Our results suggest that synthesis of the new polypeptides is initiated at the AUG-centered ribosome-binding site in the leader region and proceeds in phase to the region coding for the C-terminal end of the trpE polypeptide.

Transcription of the argF and argI genes of the arginine biosynthetic regulon of Escherichia coli K12, performed in vitro

The cell-free transcription of the argF and argI genes of the arginine biosynthetic regions is described using an S-30 system capable of coupled in vitro transcription-translation. Template DNA isolated from two independently isolated arginine transducing phages was used in this work. Steady state mRNA synthesis was observed which was attributed to RNAase degradation. Regulation of argF mRNA synthesis, directed by the argF gene carried on the specialized transducing phage phi80dargF is effected to the extent of at least 95% by the arginine holorepressor at the transcriptional stage and at least 80% of the regulation of the expression of the argI gene is mediated at the transcriptional stage. Evidence is presented which indicates that the arginine holorepressor prevents RNA polymerase from binding to the arginine promoter and suggests that the operator and promoter sites may overlap.

E. coli phosphofructokinase synthesized in vitro from a ColE1 hybrid plasmid

A hybrid plasmid, pLC 16-4, from the ColE1-DNA (E. coli) bank of Clarke and Carbon (1976) carrying pfkA was used to program an in vitro protein synthesis system from E. coli. Phosphofructokinase was the main product, as determined by enzyme assay, immunoprecipitation and gel electrophoresis. The enzyme was synthesized in vitro without added cAMP at a rate (enzyme/genome/h) ca. 30% the in vivo value, a higher efficiency than usually found in cell free systems. The plasmic molecular weight is ca. 16.10(6) daltons.

Mitomycin C-induced expression of trpA of Salmonella typhimurium inserted into the plasmid ColE1

EcoRI endonuclease digestion of the deoxyribonucleic acid of a phi80 transducing phage carrying the entire tryptophan (trp) operon of Salmonella typhimurium (phi80 S.t.trpE-A) yielded a 4.3 X 10(6)-dalton fragment containing intact trpE, trpD, and trpC and a 3.35 X 10(6)-dalton fragment containing intact trpA. The trpA fragment inserted into EcoRI-cleaved plasmids ColE1 and CR1 was expressed regardless of its orientation of insertion. Mitomycin C, a compound that induces colicin E1 production in ColE1-containing bacteria, stimulated tryptophan synthetase alpha production in cells containing ColE1-TRPA plasmids with the trpA fragment inserted in one orientation but not the other. We conclude that in the inducible plasmids trpA can be expressed from the colicin E1 promoter.

The use of specialised transducing phages in the amplification of enzyme production

Two types of lambdatrp phages have been used as model systems to investigate ways of optimising the expression of bacterial genes from transducing phage genomes. Excellent yields of trp enzymes were achieved by infecting a trpR- host with Q- or Q-S- derivatives of lambdatrpAM1, which expresses its trp genese exclusively from the trp promoter. The five trp geneproducts constituted more than 50% of the total soluble protein of infected cells under these conditions, and an even higher proportion of the protein synthesized after infection. In a trpR+ host, phage DNA replication was easily able to override tryptophan-mediated repression by titration of the trp promoter were equally productive, while having the advantage of being much simpler to construct and propagate. lambdatrp phages lacking the trp promoter were used to investigate ways of optimising gene expression initiated at the phage promoter, PL. Though very powerful, the latter promoter is more difficult to harness then the trp promoter. Derepression of transcription from PL by the use of cro- mutations is accompanied by poor replication of transducing phage DNA. Attempts to circumvent this difficulty using virulent of cro,cII double mutants have not been successful. Nevertheless, cells infected with a lambdatrp phage expressing its trp genes exclusively from PL made up to 16 per cent of their protein as trp gene-products.

In vitro transcription of the tryptophan operon in isolated bacterial nucleoids

In vitro transcription of the trp operon in isolated nucleoids from Escherichia coli was studied. RNA synthesis in this system occurred primarily as a continuation of transcription which had been initiated in vivo; little or no initiation of new RNA chains was observed. Transcription of the trp operon in nucleoids by endogenous RNA polymerase procedded efficiently and ceases sequentially in the order of the gene sequence within the operon. Under these conditions, no appreciable exonuccleolytic digestion of nascent 3H-RNA was found, though some endonucleolytic cleavage was generally seen. Little or no incorporation of 14C-leucine into polypeptides was observed, inspite of tha fact that considerable number of ribosomes and nascent RNA chains were found attached to the isolated nucleoids. The synthesis of trp mRNA continued in the presence of chloramphenicol or fusidic acid, or under conditions where the rebosomal translocation factor G was inactivated. From these and other kinetic studies of trp mRNA synthesis in nucleoids obtained from nonsense strong polar mutants of the trp operon, it was shown that transcription in nucleoids was not connected functionally with transloational processes and thus unable to exhibit polarity effected by a nonsense mutation or by general translational blockage. In studies employing nucleoids from nonsense strong polar mutants of the trp operon, it was demonstrated that RNA polymerase are scantily distributed over the region downstream from the nonsense mutation site of the operon, thereby supporting a notion that in vivo transcription is eventually terminated near the nonsense mutation.

Initial trp operon sequence in Escherichia coli is transcribed without coupling to translation

The transcription of the "leader" region (Bronson et al., 1973) of the trp operon in Escherichia coli was studied in normal mutants which delete most of the operator-distal region of the operon [a deletion strain (trp OAEG) retaining only about one third of the "leader" region and two deletion strains (trpOAE14 and trpOAE2) retaining the whole "leader" region and an initial portion of the trpE], as well as in a strain with an intact trp operon, but with a temperature-sensitive lesion in ribosomal protein factor EFTs (strain HAK88). In these deletion mutants, mRNA molecules corresponding to the "leader" region were detected as most of the trp-specific mRNA. Less inhibition of transcription, of the promoter-proximal portion of the trp "leader" region than that of more distal genes of the operon, was found in chloramphenicol-treated cells of strain trpOAE14. It was also observed that transcription of the initial one third portion of the "leader" region was not repressed by tryptophan in strains trpOAE6 and trp OAE14. A similar effect of a translation block on transcription of the distal part of the "leader" region was observed with strain HAK88 at the nonpermissive temperature. In sedimentation analysis of polyribosomes containing the trp mRNA molecules from the deletion mutants, trp mRNA from strain trpOAE14 was found in monosomes and small polyribosomes, whereas the majority of the trp mRNA from strain trpOAE6 was found joined to a single ribosome or ribosomal subunit. These results suggest that ribosomes bind in vivo to a site(s) located in the middle of the "leader" mRNA sequence, and that the initial transcription of the trp operon does not require any connection to functional translational machinery, while continuation of RNA synthesis beyond a first ribosome binding site seems indispensably coupled to ribosome function.

The construction in vitro of transducing derivatives of phage lambda

Methods are described for the construction of plaque-forming, transducing derivatives of phage lambda, using appropirate receptor genomes and fragments of DNA generated by the restriction enzymes endo R.EcoRI and endo R.HindIII. The general properties of the transducing derivatives are described and discussed. Plaque-forming phages carrying the E. coli trp, his, cysB, thyA, supD, supE, sup F, hsd, tna and lig genes have been isolated.

Stimulation in trans of synthesis of E. coli gal operon enzymes by lambdoid phages during low catabolite repression

The infection of E. coli cells with different lambdoïd prophages triggers a stimulation of galactokinase synthesis when cells are grown in a medium giving rise to a mild catabolite repression (tryptone broth) with an inducer of the gal operon (fucose). These results show that during phage infection (or induction) some factor acting in trans is produced which is able to overcome efficiently catabolite repression of the kinase cistron. Using different strains of lambdapbio252 (pam, qam, "hl), lambdapbio256Hl and lambdaNNS7 we have concluded that the factor is the N gene product which is known for its anti- p(rho) action. Studies of the whole gal operon in the same conditions show that epimerase unlike transferase and galactokinase is practically insensitive to catabolite repression by tryptone broth and that viral development has a low effect on it. This indicates that there is an internal modulation of gal operon expression. A mRNA termination site sensitive to the p factor is known in the gal operon between galE and galT. Another site weaker than this one might exist between galE and operator-promoter region.

Regulated in vitro synthesis of the enzymes of the deo operon of Escerichia coli. properties of the DNA directed system

The four enzymes deoxyriboaldolase, thymidine phosporylase, deoxyribomutase, and purine nucleoside phosphorylase have been synthesized in substantial amounts in a DNA-dependent in vitro system programmed with DNA containing the deo operon. The synthesis is greatly stimulated by deoxyribose-5-phosphate and cyclic AMP indicating that the deoR repressor and the catabolite activating protein (CAP) are highly active under our cell-free conditions. In contrast it has not yet been possible to observe a reproducible effect of the cytR repressor in vitro. The sequential appearance of active enzymes has confirmed the direction of transcription as being dra-tpp-drm-pup and has indicated that the four genes are transcribed into a single tetracistronic message.