Transcription termination: nucleotide sequence at 3' end of tryptophan operon in Escherichia coli

Rhizosphere frame system enables nondestructive live-imaging of legume-rhizobium interactions in the soil

Most plants interact with various soil microorganisms as they grow through the soil. Root nodule symbiosis by legumes and rhizobia is a well-known phenomenon of plant-microbe interactions in the soil. Although microscopic observations are useful for understanding the infection processes of rhizobia, nondestructive observation methods have not been established for monitoring interactions between rhizobia and soil-grown roots. In this study, we constructed Bradyrhizobium diazoefficiens strains that constitutively express different fluorescent proteins, which allows identification of tagged rhizobia by the type of fluorophores. In addition, we constructed a plant cultivation device, Rhizosphere Frame (RhizoFrame), which is a soil-filled container made of transparent acrylic plates that allows observation of roots growing along the acrylic plates. Combining fluorescent rhizobia with RhizoFrame, we established a live imaging system, RhizoFrame system, that enabled us to track the nodulation processes with fluorescence stereomicroscope while retaining spatial information about roots, rhizobia, and soil. Mixed inoculation with different fluorescent rhizobia using RhizoFrame enabled the visualization of mixed infection of a single nodule with two strains. In addition, observation of transgenic Lotus japonicus expressing auxin-responsive reporter genes indicated that RhizoFrame system could be used for a real-time and nondestructive reporter assay. Thus, the use of RhizoFrame system is expected to enhance the study of the spatiotemporal dynamics of plant-microbe interactions in the soil.

Taking phage integration to the next level as a genetic tool for mycobacteria

Genes must be stably integrated into bacterial chromosomes for complementation of gene deletion mutants in animal infection experiments or to express antigens in vaccine strains. However, with currently available vectors it is cumbersome to create multiple, stable, unmarked chromosomal integrations in mycobacteria. Here, we have constructed a novel integration vector for mycobacteria that enables expression of genes from a cassette protected from transcriptional interference by bi-directional transcriptional terminators proven to be highly efficient in in vitro transcription termination assays. Removal of the integrase gene by a site-specific recombinase, easily identifiable by loss of a backbone reporter gene, stabilizes the integration cassette and makes this vector ideally suitable for infection experiments. This integration vector can be easily adapted to different mycobacteriophage attachment sites (attB) due to its modular design. Integration of a gfp expression cassette at the L5, Giles and Ms6 attB sites in the chromosomes of Mycobacterium smegmatis and Mycobacterium tuberculosis yielded identical gfp expression levels, indicating that none of these sites are compromised for gene expression. The copy number of pAL5000-based extrachromosomal plasmids is 23 in M. smegmatis as determined by quantitative real-time PCR and accounts for the previously observed drastic reduction of gene expression upon integration of plasmids into the chromosome of mycobacteria. Gfp expression and fluorescence of M. smegmatis and M. tuberculosis strains with multiple integrations of gfp increased concomitantly with the copy number demonstrating that these vectors can be used to generate stronger phenotypes and/or to analyze several genes simultaneously in vivo.

Rho-dependent termination and ATPases in transcript termination

Transcription factor Rho is a ring-shaped, homohexameric protein that causes transcript termination through actions on nascent RNAs that are coupled to ATP hydrolysis. The Rho polypeptide has a distinct RNA-binding domain (RNA-BD) of known structure as well as an ATP-binding domain (ATP-BD) for which a structure has been proposed based on homology modeling. A model is proposed in which Rho first makes an interaction with a nascent RNA on a C-rich, primarily single-stranded rut region of the transcript as that region emerges from the exit site of RNA polymerase. A subsequent step involves a temporary release of one subunit of the hexamer to allow the 3' segment of the nascent transcript to enter the central channel of the Rho ring. Actions of the Rho structure in the channel on the 3' segment that are coupled to ATP hydrolysis pull the RNA from its contacts with the template and RNA polymerase, thus causing termination of its synthesis.

CsrA regulates glycogen biosynthesis by preventing translation of glgC in Escherichia coli

The carbon storage regulatory system of Escherichia coli controls the expression of genes involved in carbohydrate metabolism and cell motility. CsrA binding to glgCAP transcripts inhibits glycogen metabolism by promoting glgCAP mRNA decay. CsrB RNA functions as an antagonist of CsrA by sequestering this protein and preventing its action. In this paper, we elucidate further the mechanism of CsrA-mediated glgC regulation. Results from gel shift assays demonstrate that several molecules of CsrA can bind to each glgC transcript. RNA footprinting studies indicate that CsrA binds to the glgCAP leader transcript at two positions. One of these sites overlaps the glgC Shine-Dalgarno sequence, whereas the other CsrA target is located further upstream in an RNA hairpin. Results from toeprint and cell-free translation experiments indicate that bound CsrA prevents ribosome binding to the glgC Shine-Dalgarno sequence and that this reduces GlgC synthesis. The effect of two deletions in the upstream binding site was examined. Both of these deletions reduced, but did not eliminate, CsrA binding in vitro and CsrA-dependent regulation in vivo. Our findings establish that bound CsrA inhibits initiation of glgC translation, thereby reducing glycogen biosynthesis. This inhibition of translation probably contributes to destabilization of the glgC transcript that was observed previously.

Expression of lacZ from the promoter of the Escherichia coli spc operon cloned into vectors carrying the W205 trp-lac fusion

The expression of lacZ has been analyzed and compared in a series of promoter cloning vectors by measuring the amount of lacZ mRNA by hybridization and the amount of beta-galactosidase by standard enzymatic assay. Expression was driven by the promoter, Pspc, of the spc ribosomal protein operon. The vectors contained either the standard W205 trp-lac fusion with the trp operon transcription terminator, trpt, located in the lacZ leader sequence, or a deletion derivative that functionally inactivates trpt. In the presence of trpt, lacZ expression was temperature dependent so that increasing the growth temperature reduced the accumulation of lacZ mRNA and beta-galactosidase activity. The frequency of transcript termination at trpt was estimated to be near zero at 20 degreesC and at about 45% at 37 degreesC. The amount of Pspc-derived lacZ mRNA and the amount of beta-galactosidase produced per lacZ mRNA varied, depending on the mRNA 5' leader sequence between Pspc and lacZ. These results demonstrate that the quantitative assessment of promoter activities with promoter cloning vectors requires careful analysis and interpretation. One particular construct without trpt did not seem to contain fortuitous transcription or translation signals generated at the fusion junction. In this strain, lacZ expression from Pspc was compared at the enzyme activity and mRNA levels with a previously constructed strain in which lacZ was linked to the tandem P1 and P2 promoters of the rrnB operon. At any given growth rate, the different activities of beta-galactosidase in these two strains were found to reflect the same differences in their amounts of lacZ mRNA. Assuming that the promoter-lacZ fusions in these strains reflect the properties of the promoters in their normal chromosomal setting, it was possible to estimate the absolute transcription activity of Pspc and the relative translation efficiency of Pspc-lacZ mRNA at different growth rates. Transcription from the spc promoter was found to increase from about 10 transcripts per min at a growth rate of 1.0 doublings/h to a maximum plateau of about 23 transcripts per min at growth rates above 1.5 doublings/h. The translation frequency of lacZ mRNA expressed from Pspc was unaffected by growth rates.

Transcriptional slippage occurs during elongation at runs of adenine or thymine in Escherichia coli

A run of 11 adenine or thymine residues at the 5' end of an out-of-frame lacZ gene causes a high level of beta-galactosidase expression in E. coli. This effect was not observed for a run of guanine residues. Reverse transcription of mRNA isolated from E. coli containing the run of 11 A's reveals heterogeneity of transcript length while reverse transcription of mRNA isolated from S. cerevisiae containing the same gene shows no heterogeneity. Protein sequencing of the beta-galactosidase molecules derived from the out-of-frame construct containing a run of adenines reveals the addition of a lysine at the run. A new method was developed where messages small enough to allow resolution of single nucleotide differences on an acrylamide gel are electrophoresed, electroblotted onto nylon and probed. This confirmed the reverse transcription results and showed that additional residues can be added to transcripts derived from DNA containing 10 or 11 thymine residues. A mechanism for slippage is discussed where the A-U rich RNA-DNA hybrid can denature during elongation and rehybridize in an offset position, causing the addition of extra residues to the transcript.

Localisation and characterization of a new rho-dependent transcription terminator from bacteriophage T5

Relatively few rho-dependent terminators have been described in the literature. This manuscript describes another such terminator, isolated from phage T5. Functional analysis, involving the generation of deletion subclones, has permitted the localization of the terminator on a 413 bp fragment. Attempts to further reduce the size of this fragment resulted in loss of terminator activity. DNA sequence analysis of the terminator region supports the model whereby a rho-dependent terminator is composed of a long region of non-translated unstructured DNA, which permits rho binding, followed by RNA polymerase pausing sites where termination (in the presence of rho) may occur. The results agree with the currently held hypothesis that, despite the many similarities found between various rho dependent termination sequences, no consensus can be defined for either the rho binding or the rho termination sites (1,2).

Complete nucleotide sequence of macrolide-lincosamide-streptogramin B-resistance transposon Tn917 in Streptococcus faecalis

Streptococcus faecalis transposon Tn917 was cloned in Escherichia coli on plasmid vector pBR325. The erythromycin resistance determinant of Tn917 was not expressed in the E. coli background. The nucleotide sequence of Tn917 was determined and found to be 5,257 base pairs in length. Six open reading frames (ORFs) were identified and designated 1 through 6 (5' to 3'); all were on the same DNA strand. A region exhibiting strong homology with known promoters was identified upstream from ORF1. ORFs 1 to 3 were virtually identical to the previously sequenced erythromycin resistance determinant on Streptococcus sanguis plasmid pAM77. At the 3' point, where the homology between Tn917 and pAM77 ends, was a 20-base-pair region about 80% homologous with a component of the res site of Tn3. The amino acid sequence of ORF4 showed homology with other site-specific recombination enzymes, including approximately 30% homology with the resolvase of Tn3. Contained within Tn917 was a directly oriented 73-base-pair duplication of the left terminus. The Tn917 sequence revealed that antibiotic-enhanced transposition might be due to extension of transcription from the resistance-related genes (in ORFs 1 to 3) into transposition genes (in ORFs 4 to 6). Transcription analyses resulted in data consistent with this interpretation.

Maturation of Escherichia coli tryptophan operon mRNA: evidence for 3' exonucleolytic processing after rho-dependent termination

The mature 3' end of Escherichia coli tryptophan operon mRNA in vivo coincides with a site (trp t) having features commonly associated with rho-independent terminators in bacteria. Efficient generation of this 3' end in vivo is nevertheless affected by a distal rho-dependent site (trP-t'), though these two sites behave independently in vitro. We have cloned these sites upstream of the galactokinase gene (galK), and galactokinase levels in vivo indicate that, as terminators per se, their efficiencies (37% for trp t, and 79% for trp t') do not differ significantly from those observed in vitro. However, when the trp t hairpin is placed between galK and a downstream copy of trp t', galactokinase levels are enhanced 2- to 3-fold. This suggests the involvement of a post-transcriptional event, such as RNA processing, in determining the level of gene activity. Indeed, in the presence of the 3' exonuclease RNase II, mRNA terminated by rho factor in vitro at the trp t' site is processed back to the trp t site. The remote trp t' region appears to be the major termination site for trp mRNA, and the trp t hairpin serves a dual function-as a minor terminator, and as a protective barrier to 3' exonucleolytic degradation. We infer that the tandem terminators, rho factor, and RNA processing are all required to generate the mature 3' end of this bacterial mRNA.

RNA sequence and secondary structure requirements for rho-dependent transcription termination

The interaction of E. coli termination factor rho with the nascent RNA transcript appears to be a central feature of the rho-dependent transcription termination process. Based on in vitro studies of the rho-dependent termination of the transcript initiated at the PR promoter of bacteriophage lambda, and on earlier studies, Morgan, Bear and von Hippel (J. Biol. Chem. 258, 9565-9574, 1983) proposed a model defining the features of a potential binding site for rho protein on transcripts subject to rho-dependent termination. This model suggested that an effective rho binding site on a nascent RNA transcript should be: (i) greater than 70-80 nucleotide residues in length; (ii) essentially unencumbered with stable secondary structure; (iii) relatively sequence non-specific; and (iv) located within a few hundred nucleotide residues upstream of the potential rho-dependent terminus. In this paper we examine the sequences and secondary structures of several transcripts that exhibit rho-dependent termination to test this hypothesis further. Unstructured regions of approximately the expected size and location were found on all the transcripts examined. Though several short specific sequence elements were found to occur in a very similar arrangement on the lambda PR- and lambda PL-initiated transcripts of lambda phage, no such elements of sequence regularity were found on any of the other rho-dependent transcripts. The results of the sequence comparisons reported here strongly support the generality of the "unstructured binding site" hypothesis for rho-dependent termination.

Analysis of regulatory sequences upstream of the E. coli uvrB gene; involvement of the DnaA protein

A region located upstream of the uvrB promoters P1 and P2 was found to cause high plasmid loss when cloned in multicopy vectors. Two sequence elements responsible for this phenomenon were identified by mapping of spontaneous mutations that restore plasmid maintenance: a sequence known to have in vitro promoter activity and a partially overlapping sequence that shows extensive homology to recognition sites for the DnaA protein. Accordingly alterations in the level of DnaA protein in vivo were found to affect the extent of plasmid loss. A possible role for interaction of the DnaA protein with the region of interest is discussed in relation to regulation of uvrB expression.

Rho-dependence of the terminator active at the end of the I region of transcription of bacteriophage f1

Infection of rho- Escherichia coli cells with deletion mutant PII of bacteriophage f1 results in a miniphage RNA population composed of transcripts longer than those synthesized in the infection of rho+ cells. This indicates a Rho dependence of the terminator active at the end of the I region of transcription of bacteriophage f1. An estimate of the length of a transcript, which represents a good fraction of the RNA that passes beyond the terminator, indicates that the hairpin structure where synthesis of complementary strand DNA initiates also acts as a fairly efficient Rho-independent terminator.

Cloning and determination of the transcription termination site of ribosomal RNA gene of the mouse

A Eco RI 6.6 kb DNA fragment containing the 3'-end of 28S ribosomal RNA gene of the mouse was detected by Southern blot hybridization, and cloned in a lambda-phage vector. The site of transcription termination and the processed 3'-end of 28S RNA were determined on the cloned fragment and the surrounding nucleotide sequence determined. The 3'-terminal nucleotides of mouse 28S RNA are similar to those of yeast, Drosophila and Xenopus although the homology was lost drastically beyond the 3'-end of 28S RNA. 45S precursor RNA terminated at 30 nucleotides downstream from the 3'-end of 28S RNA gene. A structure of a dyad symmetry with a loop was found immediately prior to the termination site of 45S RNA. The rDNA termination site thus shares some common features with termination sites recognized by other RNA polymerases.

The complete nucleotide sequence of the tryptophan operon of Escherichia coli

The tryptophan (trp) operon of Escherichia coli has become the basic reference structure for studies on tryptophan metabolism. Within the past five years the application of recombinant DNA and sequencing methodologies has permitted the characterization of the structural and functional elements in this gene cluster at the molecular level. In this summary report we present the complete nucleotide sequence for the five structural genes of the trp operon of E. coli together with the internal and flanking regions of regulatory information.

Tandem termination sites in the tryptophan operon of Escherichia coli

In vivo, transcription of tryptophan (trp) operon mRNA appears to terminate at a site (trp t) 36 nucleotides after the last structural gene, and efficient function at this site requires the protein factor rho. However, distal nucleotide sequences also seem to play a role in modulating termination at trp t. We report here our in vitro studies of DNA fragments carrying portions of the trp termination region. Transcription of these DNA fragments in a purified system demonstrates that RNA polymerase actually recognizes two different termination sites. Termination at the previously characterized site, trp t, is only 25% efficient, and it is unaffected by the presence of rho factor in vitro. However, addition of rho to the transcription reaction mixture reveals that termination also occurs within a region that we have designated trp t', located about 250 bases past trp t. These two sites behave independently in vitro, whether in the tandem configuration or cloned separately, and their structural features and functional characteristics are quite different. This contrasts with the observation that termination of transcription at the end of the trp operon in vivo appears to require a rho-mediated interaction between trp t and trp t'. The possible involvement of other factors and the significance of multiple termination sites is discussed.

Comparison of the nucleoside sequence of trpA and sequences immediately beyond the trp operon of Klebsiella aerogenes. Salmonella typhimurium and Escherichia coli

The nucleotide sequence of trpA of Klebsiella aerogenes is presented and compared with the trpA sequences of Salmonella typhimurium and Escherichia coli. The majority of the approximately 200 differences between each pair of trpA's are single nucleotide pair changes that do not alter the amino acid sequence. Codon usage conforms to the general patterns revealed by examination of other prokaryotic gene sequences. However, codon usage in K. aerogenes trpA reflects the high G+C content of the genome of this organism. The DNA sequences just beyond trpA, the presumed transcription termination region, are also compared for the three species. Perusal of these sequences indicates that the secondary structure of the transcript segment just beyond trpA has been preserved, while the primary sequence has diverged appreciably.

Rho-independent termination: dyad symmetry in DNA causes RNA polymerase to pause during transcription in vitro

Termination of transcription by RNA polymerase at rho-independent sites appears to depend primarily upon two structural features, a region of GC-rich dyad symmetry in the DNA preceding the stop point and a stretch of uridines at the 3' end of the transcript. The possibility that the former might be responsible for slowing elongation prompted us to perform a kinetic analysis of transcription across the leader and terminator regions of the E. coli tryptophan (trp) operon. Regions where the elongation rate is dramatically slowed or stopped are identifiable because they generate discrete transcript hands on a gel. Species derived from pause sites, unlike those resulting from termination sites, are transient and detectable only within the first two minutes of transcription, since polymerase eventually resumes elongation. At two mutant trp attenuator sites (trp a135 and trp a1419), where termination is incomplete or absent in vitro, a substantial pause is nevertheless observed. Likewise, a significant pause occurs at trp t, the termination site at the end of the operon. Our experiments also reveal a major pause site at about position 90 in the trp leader sequence, just past a region of dyad symmetry. The RNA hairpin corresponding to this site is U-rich, and pausing is strongly enhanced by incorporation of BrUTP. In contrast, this analog does not affect pausing at the attenuator or terminator sites with hairpins that are GC-rich. These results strongly support the hypothesis that pausing of the polymerase is an obligatory prelude to rho-independent termination. Moreover, the termination event evidently results from consecutive but discrete responses to separate structural features of these sites.

Nucleotide sequence and expression of Escherichia coli trpR, the structural gene for the trp aporepressor

The nucleotide sequence of trpR of Escherichia coli was determined. This gene codes for a polypeptide (Mr 12,356) that is 108 amino acid residues in length. NH2-terminal, COOH-terminal, and total amino acid analyses of purified aporepressor agree with the deduced amino acid sequence and establish the translation start and stop codons of the structural gene. The transcription start site for trpR mRNA synthesis in vitro was shown to be 56 base pairs prior to the translation start site. The nucleotide sequence on either side of the transcription start site is homologous to the trp operon operator. Purified trp aporepressor, when activated by L-tryptophan, protects restriction sites in this region, the presumed trpR operator, from cleavage by the respective restriction endonucleases. Bound RNA polymerase protects the same restriction sites. These findings and the additional observation that trp repressor inhibits transcription initiation in vitro establish that there is a functional overlap of operator and promoter sequences in the regulatory region of the trpR operon. These findings indicate that expression of trpR is autoregulatory.

Studies of RNA release reaction catalyzed by E. coli transcription termination factor rho using isolated ternary transcription complexes

Protein factor rho catalyzes site-specific termination of transcription in a reaction requiring hydrolysis of nucleoside triphosphate with eventual release of RNA from RNA polymerase and DNA template. We have characterized the rho-catalyzed RNA release reaction using isolated transcription complexes. Transcription complexes containing T7 D111 DNA, RNA polymerase, and 3H-labeled nascent RNA were formed and isolated by gel filtration on an Agarose 5M column. When the ternary complexes were incubated with rho factor in the presence of ATP, or dATP, significant amounts of nascet RNA were released from the complexes as determined in a membrane filtration assay. Gel electrophoretic analysis of RNA has revealed that rho releases selected species of discrete-sized RNA from among those originally present in the ternary complexes. These results show that rho essentially acts to release RNA from those ternary complexes which have come to pause, and that this reaction proceeds in a discrete step separately from the pausing of RNA synthesis. Under the conditions used, the extent of RNA release widely varied at individual pausing sites and thus the action of rho exhibited certain site-selectivity.

Sequence analysis of mutations that prevent export of lambda receptor, an Escherichia coli outer membrane protein

The amino-terminal signal sequence is required for initiation of transmembrane protein transfer of the Escherichia coli lambda receptor protein. Mutations leading to insertion of charged amino acids into or deletion of amino acids from the hydrophobic segment of this sequence prevent export of this outer membrane protein.

Comparative studies on the regulation of tryptophan synthesis

In vitro DNA recombination techniques have revolutionized the study of genetic control of biosynthetic pathways. Using examples drawn from the pathway of tryptophan synthesis, approaches to the deciphering of regulatory signals and response mechanisms through transposition of DNA segments and DNA sequence analysis will be presented. After reviewing the known chromosomal arrangements and regulatory patterns of trp genes in the bacterial groups studied so far, and describing the results of transferring all or part of the pathway's genes from one organism to a distantly related one, the use of this technique to analyze new organisms will be described. Along with some advantages over the conventional methods there are some pitfalls. Finally, since it is likely that events analogous to recombinant DNA experiments take place readily in nature, their consequences in studies of bacterial evolution will be conjectured.

Model for regulation of the histidine operon of Salmonella

A model is proposed that accounts for regulation of the histidine operon by a mechanism involving alternative configuration of mRNA secondary structure (the alternative stem model). New evidence for the model includes sequence data on three regulatory mutations. The first (hisO1242) is a mutation that deletes sequences needed to form the attenuator mRNA stem and causes constitutive operon expression. The second mutation (hisO9654) is a His- ochre (UAA) mutation in the leader peptide gene; the existence of this mutation constitutes evidence that the leader peptide gene is translated. The third mutation (hisO9663) is remarkable. It neither generates a nonsense codon nor affects a translated sequence; yet, it is suppressible by amber suppressors. We believe this mutation causes a His- phenotype by interfering with mRNA secondary structure. The suppressibility of the mutation is probably due to disruption of the attenuator stem by ribosomes that read through the terminator codon of the leader peptide gene. This explanation is supported by the observation of derepression of a wild-type control region in the presence of an amber suppressor. Evidence is presented that hisT mutants (which lack pseudouridine in the anticodon arm of histidine tRNA) may cause derepression of the his operon by slowing protein synthesis in the leader peptide gene.

Control features within the rplJL-rpoBC transcription unit of Escherichia coli

Gene fusions constructed in vitro have been used to examine transcription regulatory signals from the operon which encodes ribosomal proteins L10 and L7/12 and the RNA polymerase beta and beta' subunits (the rplJL-rpoBC operon). Portions of this operon, which were obtained by in vitro deletions, have been placed between the ara promoter and the lacZ gene in the gene-fusion plasmid pMC81 developed by M. Casadaban and S. Cohen. The effect of the inserted DNA segment on the expression of the lacZ gene (in the presence and absence of arabinose) permits the localization of regulatory signals to discrete regions of the rplJL-rpoBC operon. An element that reduces the level of distal gene expression to one-sixth is located on a fragment which spans the rplL-rpoB intercistronic region. This strongly supports the idea that there is an attenuator in this region. The terminator for the operon is located on a fragment which spans the 3' end of the rpoC gene. The major promoter for the operon precedes the rplJ gene [Yamamoto, M. & Nomura, M. (1978) Proc. Natl. Acad. Sci. USA 75, 3891-3895 and Linn, T. & Scaife, J. (1978) Nature (London) 276, 33-37] and was not examined in this study. However, a weak promoter is observed on the fragment that spans the rplJ-rplL intercistronic region. Other regions of the operon may also contain weak promoters. The contribution of these elements to the regulation of this complex operon is discussed.

Nucleotide sequences of trpA of Salmonella typhimurium and Escherichia coli: an evolutionary comparison

The complete nucleotide sequences of trpA of Salmonella typhimurium and Escherichia coli were determined. The nucleotide sequences are 24.8% divergent, compared with amino acid sequence divergence of 14.9%. Over half of the codons of each gene contain synonymous nucleotide changes. The pattern of synonymous nucleotide changes is consistent with the interpretation that such changes result from random mutational events. We do not find any evidence indicating that codon selection or RNA structure is of major selective value. We conclude that polypeptide function is the primary basis of selection in trpA and that most synonymous codon changes are selectively neutral.