DNA sequence of the E. coli trpR gene and prediction of the amino acid sequence of Trp repressor

Advancing our knowledge in biochemistry, genetics, and microbiology through studies on tryptophan metabolism

I was fortunate to practice science during the last half of the previous century, when many basic biological and biochemical concepts could be experimentally addressed for the first time. My introduction to research involved isolating and identifying intermediates in the niacin biosynthetic pathway. These studies were followed by investigations focused on determining the properties of genes and enzymes essential to metabolism and examining how they were alterable by mutation. The most challenging problem I initially attacked was establishing the colinear relationship between gene and protein. Subsequent research emphasized identification and characterization of regulatory mechanisms that microorganisms use to control gene expression. An elaborate regulatory strategy, transcription attenuation, was discovered that is often based on selection between alternative RNA structures. Throughout my career I enjoyed the excitement of solving basic scientific problems. Most rewarding, however, was the feeling that I was helping young scientists experience the pleasure of performing creative research.

Linkage map of Escherichia coli K-12, edition 10: the traditional map

This map is an update of the edition 9 map by Berlyn et al. (M. K. B. Berlyn, K. B. Low, and K. E. Rudd, p. 1715-1902, in F. C. Neidhardt et al., ed., Escherichia coli and Salmonella: cellular and molecular biology, 2nd ed., vol. 2, 1996). It uses coordinates established by the completed sequence, expressed as 100 minutes for the entire circular map, and adds new genes discovered and established since 1996 and eliminates those shown to correspond to other known genes. The latter are included as synonyms. An alphabetical list of genes showing map location, synonyms, the protein or RNA product of the gene, phenotypes of mutants, and reference citations is provided. In addition to genes known to correspond to gene sequences, other genes, often older, that are described by phenotype and older mapping techniques and that have not been correlated with sequences are included.

Molecular cloning and sequence analysis of the lysR gene from the extremely thermophilic eubacterium, Thermus thermophilus HB27

We have isolated a lysine-auxotrophic and kanamycin-resistant mutant from an extreme thermophile, Thermus thermophilus HB27. This mutant showed the lysA- or lysR- genotype since it could not grow on the minimal plate which contained diaminopimelic acid. Sequence analysis of the clones which could rescue the Lys- mutant indicated the lysR gene. The lysR gene overlapped with the rimK gene for the modification enzyme of ribosomal protein S6. In the Lys- mutant, the lysR gene was disrupted and the C-terminus region of the RimK protein was different from that of the wild-type, which contributed to the Lys- and kanamycin-resistant phenotype. The deduced amino acid sequence of the lysR gene showed 20.9% identity with the LysR protein of Escherichia coli. The percentage of use of cytosine or guanine in the third letter of the codons in the lysR gene was only 67.4%. We also determined that the argC gene encoding N-acetyl-gamma-glutamyl phosphate reductase and the argB gene encoding acetylglutamate kinase were located immediately upstream of the lysR gene.

The tryptophan repressor sequence is highly conserved among the Enterobacteriaceae

Tryptophan biosynthesis in Escherichia coli is regulated by the product of the trpR gene, the tryptophan (Trp) repressor. Trp aporepressor binds the corepressor, L-tryptophan, to form a holorepressor complex, which binds trp operator DNA tightly, and inhibits transcription of the tryptophan biosynthetic operon. The conservation of trp operator sequences among enteric Gram-negative bacteria suggests that trpR genes from other bacterial species can be cloned by complementation in E. coli. To clone trpR homologues, a deletion of the E. coli trpR gene, delta trpR504, was made on a plasmid by site-directed mutagenesis, then crossed onto the E. coli genome. Plasmid clones of the trpR genes of Enterobacter aerogenes and Enterobacter cloacae were isolated by complementation of the delta trpR504 allele, scored as the ability to repress beta-galactosidase synthesis from a prophage-borne trpE-lacZ gene fusion. The predicted amino acid sequences of four enteric TrpR proteins show differences, clustered on the backside of the folded repressor, opposite the DNA-binding helix-turn-helix substructures. These differences are predicted to have little effect on the interactions of the aporepressor with tryptophan, holorepressor with operator DNA, or tandemly bound holorepressor dimers with one another. Although there is some variation observed at the dimer interface, interactions predicted to stabilize the interface are conserved. The phylogenetic relationships revealed by the TrpR amino acid sequence alignment agree with the results of others.

Thermodynamic studies of the interaction of trp aporepressor with tryptophan analogs

The association of L-tryptophan and some of its analogs, including three conformationally restricted analogs, with trp aporepressor (apo trpR) was studied by isothermal titration microcalorimetry. Contributions of the functional groups of a ligand to the free energy change, delta G degrees', and enthalpy change, delta H degree', of the interaction were evaluated on a molecular basis. Analogs without the alpha-amino group (i.e. desamino analogs) bind with a slightly higher affinity to the protein. On the other hand, descarboxy analogs show weaker binding to the apo trpR. In addition, it is found that there exists enthalpy-entropy compensation for the association of the congener series of ligands with the protein. The entropy change, delta S degree', appears to play a more important role in the binding of the conformationally restricted analogs than in the binding of L-tryptophan and the unlocked ligands.

Electrostatic forces contribute to interactions between trp repressor dimers

The trp repressor of Escherichia coli (TR), although generally considered to be dimeric, has been shown by fluorescence anisotropy of extrinsically labeled protein to undergo oligomerization in solution at protein concentrations in the micromolar range (Fernando, T., and C. A. Royer 1992. Biochemistry. 31:3429-3441). Providing evidence that oligomerization is an intrinsic property of TR, the present studies using chemical cross-linking, analytical ultracentrifugation, and molecular sieve chromatography demonstrate that unmodified TR dimers form higher order aggregates. Tetramers and higher order species were observed in chemical cross-linking experiments at concentrations between 1 and 40 microM. Results from analytical ultracentrifugation and gel filtration chromatography were consistent with average molecular weight values between tetramer and dimer, although no plateaus in the association were evident over the concentration ranges studied, indicating that higher order species are populated. Analytical ultracentrifugation data in presence of corepressor imply that corepressor binding destabilizes the higher order aggregates, an observation that is consistent with the earlier fluorescence work. Through the investigation of the salt and pH dependence of oligomerization, the present studies have revealed an electrostatic component to the interactions between TR dimers.

Nucleotide sequence of the Salmonella typhimurium trpR gene

The sequence of the Salmonella typhimurium trpR gene and flanking DNA was determined on both strands. The DNA sequence predicts a polypeptide product of 108 amino acids with a molecular weight of 12,274 daltons. The TrpR protein of S. typhimurium differs by three amino acid residues from that of E. coli. The promoter/operator region of trpR is completely conserved between E. coli and S. typhimurium. The nucleotide sequence of the trpR sector of the S. typhimurium genome was 87.4% identical to the corresponding region of the E. coli genome. Within the protein coding segments of the two organisms, 94.4% of the amino acid residues were identical. In S. typhimurium, as in E. coli, there is a Palindromic Unit element (PU) between the translation termination triplet of trpR and that of a divergently oriented unidentified reading frame (URF-143). However, the PU segment of S. typhimurium is 85 nucleotides shorter than its E. coli counterpart.

Murein-metabolizing enzymes from Escherichia coli: sequence analysis and controlled overexpression of the slt gene, which encodes the soluble lytic transglycosylase

The complete nucleotide sequence of the slt gene encoding the soluble lytic transglycosylase (Slt; EC 3.2.1.-) from Escherichia coli has been determined. The largest open reading frame identified on a 2.5-kb PvuII-SalI fragment indicates that the enzyme is translated as a preprotein of either 654 or 645 amino acids, depending on which of two potential start codons is used. The two possible translation products differ only in the lengths of their predicted signal peptides, 36 or 27 amino acids, respectively. In both cases, processing results in a soluble mature protein of 618 amino acids (Mr = 70,468). The deduced primary structure of the mature protein was confirmed by N-terminal sequencing and determination of the amino acid composition of the isolated transglycosylase. The slt gene contains a high percentage of rare codons, comparable to other low-expressed genes. A hairpin structure that could serve as a transcriptional terminator is located downstream of the slt coding region and precedes the trpR open reading frame at 99.7 min on the E. coli chromosomal map. A computer-assisted search did not reveal any significant sequence similarity to other known carbohydrate-degrading enzymes, including lysozymes. Interestingly, a stretch of 151 amino acids at the C terminus of the transglycosylase shows similarity to the N-terminal portion of the internal virion protein D from bacteriophage T7. Overexpression of the slt gene, under the control of the temperature-inducible phage lambda pR promoter, results in a 250-fold overproduction of the mature transglycosylase, whereas after deletion of the signal peptide a 100-fold overproduction of the enzyme is observed in the cytoplasm.

trp repressor interactions with the trp aroH and trpR operators. Comparison of repressor binding in vitro and repression in vivo

Interaction of the Escherichia coli trp repressor with the promoter-operator regions of the trp, aroH and trpR operons was studied in vivo and in vitro. The three operators have similar, but non-identical, sequences; each operator is located in a different segment of its respective promoter. In vivo repression of the three operons was measured using single-copy gene fusions to lacZ. The extent of repression varied from 300-fold for the trp operon, to sixfold for the aroH operon and threefold for the trpR operon. To determine whether differential binding of repressor to the three operators was responsible for the differences in repression observed in vivo, three in vitro binding assays were employed. Restriction-site protection, gel retardation and DNase footprinting analyses revealed that repressor binds to the three operators with almost equal affinity. It was also shown in an in vivo competition assay that repressor binds approximately equally well to each of the three operators. It is proposed that the differential regulation observed in vivo may be due to the different relative locations of the three operators within their respective promoters.

Signals determining translational start-site recognition in eukaryotes and their role in prediction of genetic reading frames

A special methionyl-tRNA (RNAi) is universally required to initiate translation. The conversation of this reactant throughout evolution, as well as its unusual decoding properties, suggested an alternate mechanism for tRNA-mRNA interactions at initiation. We have reported that the sequence of bases neighboring the start codons of many eubacterial genes are complementary not only to the 16S rRNA 3' end and to the anticodon of tRNAi, but, also, have the potential to base-pair the D, T or extended anticodon loops of this tRNAi. The coding properties of tRNAi and mutations that affect translation suggest that these signals may function. This hypothesis explains the observation that unusual triplets can start prokaryotic and mitochondrial genes and predicts the occurrence of other reading frames. Furthermore, it suggests a unifying model of chain initiation based on RNA-RNA contacts and displacements. Here we examine the start domain of 290 eukaryotic genes for their ability to base-pair the tRNAi loops and the 18S rRNA. We observe that both methionine start, and methionine coding regions have the potential to pair with the 18S rRNA, but that the nucleotide distribution about start codons strongly favoured such pairings over that near internal AUGs. The 5' extended anticodon of tRNAi is methylated, and was not represented in the mRNA with high frequency. However, the tetramer AUGg did occur with high frequency in the start domain. A modification of the tRNAi T loop also decreases its base-pairing potential. Interestingly, complementarity to the T loop did not occur with high frequency in the start sites. The early coding region, 10 to 34 nucleotides 3' to the initiator AUG, is complementary to the tRNAi D loop in many cases, while no such affinity is found near internal AUGs. The nucleotides around initiator AUGs were heavily biassed toward the sequence gccaccAUGgcg. No such tendency was noted around internal AUGs. Although the role of this sequence bias is unclear, the sequence gccaccAUGg has been shown by Kozak to promote initiation. Another distinguishing feature was a C-rich tract 7 to 34 nucleotides 5' to the initiator AUGs. Ability to pair with more than eight bases of the start consensus sequence, matching of 6 or 7 nucleotides to the D loop on the 3' side, an C-richness on the 5' side were used as criteria for distinguishing start AUGs.(ABSTRACT TRUNCATED AT 400 WORDS)

Molecular cloning of the wild-type phoM operon in Escherichia coli K-12

A metastable bacterial alkaline phosphatase (Bap) phenotype is seen in phoR mutants, which alternately express a Bap-constitutive or -negative phenotype. The alteration is affected by mutations in the phoM region near 0 min. By molecular cloning of the wild-type phoM operon onto a multicopy plasmid and recombining onto the plasmid the pho-510 mutation that abolishes variation, the phoM operon, rather than some nearby gene, was shown to control variation. Complementation tests indicated that the wild-type phoM allele is dominant to the pho-510 mutation when both are in single copy, but whichever allele is present in higher copy appears as dominant when multicopy plasmids are examined. The alternating phenotypic variation of BAP synthesis was not seen in phoR+ cells with multicopy wild-type phoM plasmids, thus showing that the variation is associated with phoM-dependent Bap expression. The alternation acted at the level of phoA transcription; it was also recA independent. BAP clonal variation is phenotypically similar to Salmonella phase variation, which is controlled by a DNA rearrangement. No evidence was found for a DNA change near the phoM operon that might be responsible for the variable Bap phenotype.

Escherichia coli tryptophan repressor binds multiple sites within the aroH and trp operators

DNase I footprinting and methylation protection studies have been used to analyze the binding of Escherichia coli Trp repressor to the trpR, aroH, and trp operators. The methylation protection assay shows that Trp repressor binds in two successive major grooves of the trpR operator, three successive major grooves of the aroH operator, and four successive major grooves of the trp operator. The simplest model that explains the difference in Trp repressor interaction at the three operators is that the aroH and trp operators are composed of multiple, helically stacked binding sites. When viewed in three dimensions, each site is positioned on a different face of the DNA, and together process up the surface of the DNA helix. Analysis of a deletion derivative of the trp operator supports this model.

Potential secondary structure at translation-initiation sites

Since translational start codons also occur internally, more-complex features within mRNA must determine initiation. We compare the potential secondary structure of 123 prokaryotic mRNA start regions to that of regions coding for internal methionines. The latter display an unexpectedly-uniform, almost-periodic pattern of pairing potential. In contrast, sequences 5' to start codons have little self-pairing, and do not pair extensively with the proximal coding region. Pairing potential surrounding start codons was found to be less than half of that found near internal AUGs. In groups of random sequences where the distribution of nucleotides at each position, or of trinucleotides at each in-frame codon position, matched the observed natural distribution, there was no periodicity in the pairing potential of the internal sequences. Randomized internal sequences had less pairing: the ratio of pairing intensity between internals and starts was reduced from 2.0 to 1.6 by randomization. We propose that the transition from the relatively-unstructured start domains to the highly-structured internal sequences may be an important determinant of translational start-site recognition.

crp genes of Shigella flexneri, Salmonella typhimurium, and Escherichia coli

The complete nucleotide sequences of the Salmonella typhimurium LT2 and Shigella flexneri 2B crp genes were determined and compared with those of the Escherichia coli K-12 crp gene. The Shigella flexneri gene was almost like the E. coli crp gene, with only four silent base pair changes. The S. typhimurium and E. coli crp genes presented a higher degree of divergence in their nucleotide sequence with 77 changes, but the corresponding amino acid sequences presented only one amino acid difference. The nucleotide sequences of the crp genes diverged to the same extent as in the other genes, trp, ompA, metJ, and araC, which are structural or regulatory genes. An analysis of the amino acid divergence, however, revealed that the catabolite gene activator protein, the crp gene product, is the most conserved protein observed so far. Comparison of codon usage in S. typhimurium and E. coli for all genes sequenced in both organisms showed that their patterns were similar. Comparison of the regulatory regions of the S. typhimurium and E. coli crp genes showed that the most conserved sequences were those known to be essential for the expression of E. coli crp.

Intermediates in the synthesis of TolC protein include an incomplete peptide stalled at a rare Arg codon

TolC is a minor outer membrane protein of Escherichia coli K 12 and is initially synthesized as a precursor. A distinct intermediate polypeptide of Mr about 46 000 was consistently observed at the initial stages of biosynthesis. The further elongation of this peptide can be blocked by chloramphenicol. We have investigated the cause of the temporary accumulation of the 46 000-Mr intermediate and we postulate that the presence of a rare codon AGA (Arg) at codon 402 of the tolC mRNA halts translating ribosomes owing to a limiting amount of the tRNAArg (AGA) species in the cell. The translation of tolC mRNA can be increased by providing T4 tRNAArg (AGA), encoded on a plasmid.

DNA methylation influences trpR promoter activity in Escherichia coli K-12

Methylation of adenine in the GATC-sequence of the -35 region of the trpR promoter decreases activity by 2-3 fold.

Analysis of the codon bias in E. coli sequences

Fifty-three gene sequences from E. coli containing 18,288 reading frame triplets have been characterized according to the nature and level of average codon preference. The distribution of average preferences is bimodal, with approximately half the genes using an average of only 36 codons, and the remainder just 42 codons. There is a high correlation between the level of codon bias, the tRNA population and the abundance of protein product, indicating biased patterns are exploited by the cell for the production of widely different levels of gene product. This relationship is especially striking in genes involved in the production of components for transcription and translation. Overall, the genes for these processes generate some five-fold more protein than the average in the genome, and use about five fewer codons. The very high codon bias found in the RNA polymerase gene thus provides a simple, autogenous mechanism for the coordinate synthesis of these components and RNA polymerase. A surprisingly high level of codon probability is also found in triplets of the complement of coding sequences. This is apparently due to the evolutionary dispersion of coding sequences and/or the requirement for increased levels of secondary structure in messenger RNAs.

Repetitive extragenic palindromic sequences: a major component of the bacterial genome

We describe a remarkably conserved nucleotide sequence, the many copies of which may occupy up to 1% of the genomes of E. coli and S. typhimurium. This sequence, the REP (repetitive extragenic palindromic) sequence, is about 35 nucleotides long, includes an inverted repeat, and can occur singly or in multiple adjacent copies. A possible role for the REP sequences in regulation of gene expression has been thoroughly investigated. While the REP sequences do not appear to modulate differential gene expression within an operon, they can affect the expression of both upstream and downstream genes to a small extent, probably by affecting the rate of mRNA degradation. Possible roles for the REP sequence in mRNA degradation, chromosome structure, and recombination are discussed.

Repression is relieved before attenuation in the trp operon of Escherichia coli as tryptophan starvation becomes increasingly severe

Expression of the tryptophan operon of Escherichia coli is regulated over about a 500- to 600-fold range by the combined action of repression and attenuation. Repression regulates transcription initiation in response to variation in the intracellular concentration of tryptophan. Attenuation regulates transcription termination at a site in the leader region of the operon in response to changes in the extent of charging of tRNATrp. We measured repression independently of attenuation to ascertain whether these regulatory mechanisms were used differentially by the bacterium as the severity of tryptophan starvation was increased. We found that repression regulated transcription of the operon over the range from growth with excess tryptophan to growth under moderate tryptophan starvation. By contrast, attenuation (termination control) was not relaxed until tryptophan starvation was in the moderate-to-severe range. Thus, attenuation and repression were used to regulate transcription in response to different degrees of tryptophan deprivation. Consistent with this conclusion is the observation that when tryptophan starvation was sufficient to relieve repression 50 to 60%, 65% of the tRNATrp of the bacterium was charged. These findings provide a possible explanation for the existence of only two tryptophan codons in the coding region for the trp leader peptide of Enterobacteriaceae.

Transcription of the trpR gene of Escherichia coli: an autogeneously regulated system studied by direct measurements of mRNA levels in vivo

The expression of the trpR gene of Escherichia coli was investigated by measuring trpR messenger RNA levels in vivo under various physiological conditions. Trp repressor, when present, led to significant decreases in the amount of trpR message produced; this effect was enhanced by providing excess L-tryptophan to the system. In the absence of Trp repressor, no changes in trpR message levels were observed under any of the conditions employed. Sedimentation profiles of trpR mRNA revealed a single species under all circumstances. These results suggest that autogenous repression alone acts to regulate transcription of the trpR gene. The activity of the trpR promoter in vivo was evaluated using a trpR-lacZ operon fusion. Very good agreement was found between relative promoter activity and trpR message levels under all experimental conditions.

Analysis in vivo of factors affecting the control of transcription initiation at promoters containing target sites for trp repressor

An investigation of repression in the trp system of Escherichia coli was undertaken using operon fusions and plasmids constructed via recombinant DNA technology. The promoters of the trp operon and the trpR gene were fused to lacZ, enabling the activity of these promoters to be evaluated under various conditions through measurements of beta-galactosidase production. In confirmation of earlier studies, the trpR gene was shown to be regulated autogenously. This control feature of the trp system was found to maintain intracellular Trp repressor protein at essentially invariant levels under most conditions studied. Increasing the trpR+ gene dosage did not significantly elevate Trp repressor protein levels, nor did the introduction of additional operator "sinks" result in significantly decreased levels of Trp repressor protein. Definite alterations in intracellular Trp repressor protein levels were achieved only by subverting the normal trpR regulatory elements. The placement of the lacUV5 or the lambda PL promoters upstream of the trpR gene resulted in significant increases in repression of the trp system. Substituting the primary trp promoter/operator for the native trpR promoter/operator resulted in an altered regulatory response of the trp system to tryptophan limitation or excess. The regulation of the trpR gene effectively imparts a broad range of expression to the trp operon in a manner finely attuned to fluctuations in intracellular tryptophan levels.

Studies on the interaction of Trp holorepressor with several operators. Evidence that the target need not be palindromic

The interaction of Trp repressor protein with partial trp operators was studied in vitro and in vivo. At high ratios of protein to DNA, Trp holorepressor formed stable complexes with DNA molecules containing half operators. When plasmids conferring the capacity to hyperproduce Trp repressor were present in trpOc strains of Escherichia coli, repression of downstream tryptophan synthase occurred. Palindromicity of the trp operator may facilitate stable interaction with Trp repressor, but this attribute need not be regarded as a critically essential structural feature. Sufficient information for the recognition by Trp repressor protein of an appropriate target resides within a DNA sequence of approximately ten base-pairs.

Nucleotide sequence of thrC and of the transcription termination region of the threonine operon in Escherichia coli K12

The entire threonine operon (thrABC) of Escherichia coli K12 was cloned, and the nucleotide sequence of the thrC gene and its 3' flanking region was determined. The translation initiation codon was identified by sequencing the N-terminal part of threonine synthase, the thrC gene product. Analysis of the deduced protein sequence (428 amino acid residues) revealed a region of homology, 35 amino acids long, between the three enzymes encoded by the threonine operon. During examination of the nucleotide sequence of the 1045 base pair fragments following the thrC gene, we detected some potential rho-independent and rho-dependent transcription termination signals.

Evidence that repression mechanisms can exert control over the thr, leu, and ilv operons of Escherichia coli K-12

Mutants of Escherichia coli K-12 resistant to either the threonine analog DL-alpha-amino-beta-hydroxyvaleric acid or the leucine analog 5',5',5'-trifluoro-DL-leucine were isolated. One DL-alpha-amino-beta-hydroxyvaleric acid-resistant mutant strain, designated SP572, constitutively expressed the thr and ilv operons. The mutant allele, avr-16, was localized between trpR and the thr operon at min 0. The wildtype allele of avr-16, designated ileR, is trans dominant. One 5',5',5'-trifluoro-DL-leucine-resistant mutant strain, designated FLR9, expressed the leu and ilv operons constitutively. The mutant allele, flr-9, is linked to entA at min 13. The constitutive expression of the thr, leu, and ilv operons in mutants avr-16 and flr-9 was partly reversed in cells harboring a plasmid, which leads to elevated levels of the trpR gene product, the Trp aporepressor protein. Operator-like sequences situated upstream from the transcription startpoints of the thr, leu, and ilv operons are plausible candidates for targets of systems of repressor-operator control functioning in parallel with attenuation.

Trp repressor protein is capable of intruding into other amino acid biosynthetic systems

Escherichia coli strains with elevated intracellular levels of Trp repressor protein displayed complete growth inhibition on minimal media which contained high levels of tryptophan. The inhibition was attributable to the acquisition of a compound nutritional requirement, which could be satisfied by a combination of isoleucine, leucine, valine, threonine, serine, phenylalanine, and tyrosine. It is proposed that Trp repressor protein, at elevated levels, represses the transcription of those genes which encode enzymes for the biosynthesis of these particular amino acids. Data which support this model are presented, together with a discussion of its regulatory implications.

Compilation and analysis of Escherichia coli promoter DNA sequences

The DNA sequence of 168 promoter regions (-50 to +10) for Escherichia coli RNA polymerase were compiled. The complete listing was divided into two groups depending upon whether or not the promoter had been defined by genetic (promoter mutations) or biochemical (5' end determination) criteria. A consensus promoter sequence based on homologies among 112 well-defined promoters was determined that was in substantial agreement with previous compilations. In addition, we have tabulated 98 promoter mutations. Nearly all of the altered base pairs in the mutants conform to the following general rule: down-mutations decrease homology and up-mutations increase homology to the consensus sequence.

Complete nucleotide sequence of the E. coli glyA gene

The nucleotide sequence of the Escherichia coli glyA gene has been determined. The amino acid sequence predicted from the DNA sequence consists of 417 residues. After the coding region there is a 185 nucleotide sequence preceding the proposed transcription termination region for the glyA gene. This region is preceded by a G-C rich sequence that could form a stable stem-loop structure once transcribed, followed by an A-T rich sequence within which transcription appears to terminate. There is a long region of dyad symmetry and numerous smaller symmetrical regions between the site of translation termination and the proposed transcription termination region. These stem-loop structures show remarkable homology with intercistronic elements of other prokaryotic operons and may play a role in the regulation of glyA gene expression.

Molecular cloning of pheR in Escherichia coli K-12

The regulator gene pheR, which in Escherichia coli controls the expression of pheA, the structural gene for chorismate mutase P-prephenate dehydratase, was cloned on to multicopy plasmids directly from the E. coli chromosome; this was achieved with the aid of the tetracycline resistance transposon, Tn10, that had been inserted very close to the pheR gene. Subsequently, pheR was subcloned on a 1.1-kilobase-pair fragment on the plasmid vector pBR322; its position on the plasmid was localized by the method of gamma delta-mediated transpositional inactivation. The pheR gene product was identified in maxicells and found to be a protein of subunit molecular weight 19,000, suggesting that the coding segment of the gene is about 500 nucleotide pairs long.

Recognition of protein coding regions in DNA sequences

We give a test for protein coding regions which is based on simple and universal differences between protein-coding and noncoding DNA. The test is simple enough to use without a computer and is completely objective. The test has been thoroughly proven on 400,000 bases of sequence data: it misclassifies 5% of the regions tested and gives an answer of "No Opinion" one fifth of the time. We predict some new coding and noncoding regions in published sequences.

Use of in vitro gene fusions to study the uxuR regulatory gene in Escherichia coli K-12: direction of transcription and regulation of its expression

The uxuAB operon is composed of two genes coding for enzymes involved in hexuronate degradation. This operon is negatively controlled by the uxuR and exuR regulatory gene products. Fusions that brought lac gene expression under the control of transcriptional and translational signals within the uxuR gene were used to study uxuR regulation. These fusions were formed on plasmid cloning vectors constructed by Casadaban et al. (J. Bacteriol. 143:971-980, 1980). The transcriptional direction of the uxuR gene was deduced from the restriction pattern and the phenotypic properties of the new plasmids. The gene is transcribed counterclockwise on the standard Escherichia coli map, as is the uxuAB operon. Introduction in trans of a compatible plasmid carrying a wild-type uxuR gene in the lac fusion plasmid containing strain resulted in a decrease of beta-galactosidase synthesis. It was concluded that expression of the uxuR gene itself is repressed by its own product. The two other types of regulation found in the uxuAB operon, i.e., induction by fructuronate and catabolite control, also apply to the uxuR gene, whereas repression by the exuR repressor does not seem to occur for the uxuR gene.

Preferential codon usage in prokaryotic genes: the optimal codon-anticodon interaction energy and the selective codon usage in efficiently expressed genes

By considering the nucleotide sequence of several highly expressed coding regions in bacteriophage MS2 and mRNAs from Escherichia coli, it is possible to deduce some rules which govern the selection of the most appropriate synonymous codons NNU or NNC read by tRNAs having GNN, QNN or INN as anticodon. The rules fit with the general hypothesis that an efficient in-phase translation is facilitated by proper choice of degenerate codewords promoting a codon-anticodon interaction with intermediate strength (optimal energy) over those with very strong or very weak interaction energy. Moreover, codons corresponding to minor tRNAs are clearly avoided in these efficiently expressed genes. These correlations are clearcut in the normal reading frame but not in the corresponding frameshift sequences +1 and +2. We hypothesize that both the optimization of codon-anticodon interaction energy and the adaptation of the population to codon frequency or vice versa in highly expressed mRNAs of E. coli are part of a strategy that optimizes the efficiency of translation. Conversely, codon usage in weakly expressed genes such as repressor genes follows exactly the opposite rules. It may be concluded that, in addition to the need for coding an amino acid sequence, the energetic consideration for codon-anticodon pairing, as well as the adaptation of codons to the tRNA population, may have been important evolutionary constraints on the selection of the optimal nucleotide sequence.

Characterization of translational initiation sites in E. coli

We characterize the Shine and Dalgarno sequence of 124 known gene beginnings. This information is used to make "rules" which help distinguish gene beginning from other sites in a library of over 78,000 bases of mRNA. Gene beginnings are found to have information besides the initiation codon and Shine and Dalgarno sequence which can be used to make better "rules".

Autoregulation of the tyrR gene

Strains of Escherichia coli K-12 in which the transcription of lacZ is initiated from the tyrR promoter have been constructed by use of the Mu d (Apr lac) phage of Casadaban and Cohen (Proc. Natl. Acad. Sci. U.S.A. 76:4530-4533, 1979). These strains have been used to examine the regulation of expression from the tyrR promoter, with the synthesis of beta-galactosidase used as an index of expression. The specific activity of beta-galactosidase fell to 51% upon introduction of lambda (Tn10) tyrR+; to 39% upon introduction of F123, an F-prime carrying tyrR+; to 29% upon introduction of pMU309, a derivative of the plasmid RP4 carrying tyrR+; and to 13.6% upon introduction of pMU352, a derivative of the multicopy plasmid pBR322 carrying tyrR+. These results indicate that the tyrR gene product interacts with its own promoter-operator region, decreasing synthesis of beta galactosidase in the tyrR::Mu d (Apr lac) strains. The increasing extent of repression of beta-galactosidase synthesis with increasing tyrR+ gene dosage was accompanied by increasing repression of the synthesis of tyrosine- and phenylalanine-repressible 3-deoxy-D-arabinoheptulosonic acid-7-phosphate synthetases. The interaction of the repressor with tyrRo appears unusual in the sense that aporepressor alone is probably one of the repressing species. The levels of beta-galactosidase synthesized in the tyrR::Mu d (Apr lac) strains indicate that tyrR has a relatively efficient promoter, the maximum levels representing on the order of a relatively efficient promoter, the maximum levels representing on the order of 1,000 monomers of beta-galactosidase per cell in the tyrR strain and about 500 monomers in the tyrR+ haploid strain.

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.

Identification of the tetracycline resistance promoter and repressor in transposon Tn10

The structural and regulatory functions encoding tetracycline resistance in transposon Tn10 lie within a 2,700-base pair region. Using recombinant plasmids with different deoxyribonucleic acid sequences adjacent to a HincII site in this region, we located the promoter controlling the expression of tetracycline resistance. These various sequences conferred altered levels of tetracycline resistance. Plasmids containing deletions of a 695-base pair HincII fragment were constitutive and showed the loss of a 23,000-dalton tetracycline-inducible polypeptide, thus identifying the repressor and the location of its gene.

Attenuation in the control of expression of bacterial operons

Bacterial operons concerned with the biosynthesis of amino acids are often controlled by a process of attenuation. The translation product of the initial segment of the transcript of each operon is a peptide rich in the amino acid that the particular operon controls. If the amino acid is in short supply translation is stalled at the relevant codons of the transcript long enough for the succeeding segment of the transcript to form secondary structures that allow the transcribing RNA polymerase molecule to proceed through a site that otherwise dictates termination of transcription. This site is the attenuator; the process is attenuation.

UGA suppression by normal tRNA Trp in Escherichia coli: codon context effects

The nucleotide sequences at the 3' side of in-phase UGA termination codons in mRNAs of various prokaryotic genes were re-examined. An adenine (A) residue is found to be adjacent to the 3' side of UGA in mRNAs which code for readthrough proteins by the suppression of UGA by normal Escherichia coli tRNA Trp. It is suggested that the nature of the nucleotide following a UGA codon determines whether the UGA signals inefficiently or efficiently the termination of polypeptide chain synthesis: an A residue at this position permits the UGA readthrough process.