Analysis in vivo of translational mutants of the rIIB cistron of bacteriophage T4

Translation enhancement by a Dictyostelium gene sequence in Escherichia coli

Methods for heterologous protein production in Escherichia coli have revolutionized biotechnology and the bioindustry. It is ultimately important to increase the amount of protein product from bacteria. To this end, a variety of tools, such as effective promoters, have been developed. Here, we present a versatile molecular tool based on a phenomenon termed "translation enhancement by a Dictyostelium gene sequence" ("TED") in E. coli. We found that protein expression was increased when a gene sequence of Dictyostelium discoideum was placed upstream of the Shine-Dalgarno sequence located between the promoter and the initiation codon of a target gene. The most effective sequence among the genes examined was mlcR, which encodes the myosin regulatory light chain, a subunit of myosin II. Serial deletion analysis revealed that at least 10 bases of the 3' end of the mlcR gene enhanced the production of green fluorescent protein in cells. We applied this tool to a T7 expression system and found that the expression level of the proteins tested was increased when compared with the conventional method. Thus, current protein production systems can be improved by combination with TED.

Twenty Years of Delila and Molecular Information Theory: The Altenberg-Austin Workshop in Theoretical Biology Biological Information, Beyond Metaphor: Causality, Explanation, and Unification Altenberg, Austria, 11-14 July 2002

A brief personal history is given about how information theory can be applied to binding sites of genetic control molecules on nucleic acids. The primary example used is ribosome binding sites in Escherichia coli. Once the sites are aligned, the information needed to describe the sites can be computed using Claude Shannon's method. This is displayed by a computer graphic called a sequence logo. The logo represents an average binding site, and the mathematics easily allows one to determine the components of this average. That is, given a set of binding sites, the information for individual binding sites can also be computed. One can go further and predict the information of sites that are not in the original data set. Information theory also allows one to model the flexibility of ribosome binding sites, and this led us to a simple model for ribosome translational initiation in which the molecular components fit together only when the ribosome is at a good ribosome binding site. Since information theory is general, the same mathematics applies to human splice junctions, where we can predict the effect of sequence changes that cause human genetic diseases and cancer. The second example given is the Pribnow 'box' which, when viewed by the information theory method, reveals a mechanism for initiation of both transcription and DNA replication. Replication, transcription, splicing, and translation into protein represent the central dogma, so these examples show how molecular information theory is contributing to our knowledge of basic biology.

Organization around the dnaA gene of Streptococcus pneumoniae

The dnaA gene region of Streptococcus pneumoniae was cloned and sequenced. A tRNA gene, seven ORFs and three DnaA box clusters were identified. The order of the genes and intergene regions found was tRNA(Arg)-orf1-DnaA box cluster 3-htrA-spoOJ-DnaA box cluster 2-dnaA-DnaA box cluster 1-dnaN-orfX-orfY. Five ORFs are homologous to known bacterial genes. The tRNA(Arg) gene and orf1, also called orfL, have already been described in pneumococci and have been reported to be preceded by the competence regulation locus comCDE. In Escherichia coli, htrA encodes a serine protease. In Bacillus subtilis, spoOJ plays a role in sporulation and partition. dnaA encodes an initiator replication protein, very well conserved in several bacteria and dnaN encodes the beta subunit of DNA polymerase III in E. coli. The function of orfX is unknown. The N-terminal part of another reading frame, orfY, revealed high homology with a GTP-binding protein, DnaA box clusters were found upstream and downstream from dnaA. The presence of two such clusters suggests that the chromosomal origin of S. pneumoniae is located within this region. The position of dnaA, and therefore the putative origin of replication, were localized on the physical map of S. pneumoniae.

Inhibition of Escherichia coli protein synthesis by abortive translation of phage lambda minigenes

Escherichia coli mutants defective in peptidyl-tRNA hydrolase activity are unable to maintain bacteriophage lambda vegetative growth. Phage mutants, named bar, overcome the host limitation to support viral growth. Multicopy expression of lambda wild-type bar regions is deleterious to hydrolase-defective cells because it provokes arrest of protein synthesis. We noticed that the bar regions include minigenes whose transcripts would contain a Shine-Dalgarno-like sequence appropriately spaced for translation from a two codon open reading frame. To investigate the mechanism of bar inhibition, we asked if transcripts of the barI region function as mRNAs in their ribosomal interactions. We found that bar-containing RNA associates with ribosomes, forms ternary initiation complexes, yields a toeprint signal, and can be removed from ribosomes by run-off translation, as authentic mRNA. Since bar-containing RNA has the properties of a messenger, we propose that its translation leads to drop-off and accumulation of peptidyl-tRNA in pth-defective cells. Starvation of the tRNA(s) sequestered in pepidyl-tRNA(s) eventually causes inhibition of protein synthesis.

Determination of the optimal aligned spacing between the Shine-Dalgarno sequence and the translation initiation codon of Escherichia coli mRNAs

The prokaryotic mRNA ribosome binding site (RBS) usually contains part or all of a polypurine domain UAAGGAGGU known as the Shine-Dalgarno (SD) sequence found just 5' to the translation initiation codon. It is now clear that the SD sequence is important for identification of the translation initiation site on the mRNA by the ribosome, and that as a result, the spacing between the SD and the initiation codon strongly affects translational efficiency (1). It is not as clear, however, whether there is a unique optimal spacing. Complications involving the definition of the spacing as well as secondary structures have obscured matters. We thus undertook a systematic study by inserting two series of synthetic RBSs of varying spacing and SD sequence into a plasmid vector containing the chloramphenicol acetyltransferase gene. Care was taken not to introduce any secondary structure. Measurements of protein expression demonstrated an optimal aligned spacing of 5 nt for both series. Since aligned spacing corresponds naturally to the spacing between the 3'-end of the 16S rRNA and the P-site, we conclude that there is a unique optimal aligned SD-AUG spacing in the absence of other complicating issues.

Controlled expression and structural organization of a Lactococcus lactis bacteriophage lysin encoded by two overlapping genes

The phi vML3 bacteriophage lysin is specific for lactococci and could be used to promote enzyme release during cheese manufacture. The level of lysin expression from the cloned gene using its own upstream sequences is very low. Expression in Escherichia coli by using a synthetic hybrid lysin gene and a series of BAL 31 deletions of the original cloned DNA fragment suggested that the start of the gene had previously been incorrectly assigned. Reevaluation of homology between the lysin and Bacillus subtilis PZA protein 15 led to the identification of a new potential ribosome binding site (RBS). A 0.72-kb PCR-generated fragment including this RBS and the complete lysin gene was expressed and inducibly controlled. The translational start of the lysin gene was identified as an isoleucine codon, and this may lead to a low translation rate. During the analysis of the BAL 31 deletion fragments, two proteins of 20 and 8 kDa were shown to be expressed from the originally defined lysin gene. The DNA sequence has a second open reading frame with a good RBS and two potential start methionines. The smaller lysin protein was isolated, and the N terminus was sequenced, confirming that one methionine codon acted as the start of a second gene. The larger lysin protein has homology with lysozymes. The smaller lysin protein has some features resembling those of a holin. The possible roles of these two proteins in lysis of lactococci are discussed.

Mechanism of expression of DNA repair gene vsr, an Escherichia coli gene that overlaps the DNA cytosine methylase gene, dcm

The DNA cytosine methylase gene of Escherichia coli, dcm, overlaps an open reading frame (ORF) that continues in +1 register past the end of dcm. This ORF codes for a gene, vsr, that is required for a T:G to C:G base mismatch correction process. In this study, mutants that affect the level of expression of the two genes were constructed and characterized. Further, a previously isolated mutant, dcm-6, was cloned and mutations within it were identified. Northern blots were used to identify dcm-specific RNA species in wild type and dcm-6 cells. Based on these studies we conclude that there is a six-codon overlap between vsr and dcm. The two proteins appear to be made from a single RNA transcript and translation of dcm is required for the efficient synthesis of Vsr. Further, Vsr is active by itself and may not be produced as a fusion with Dcm. This is the first example of chromosomal genes that overlap in their coding regions and produce proteins with distinct functions.

The effect of ribosomal protein S1 from Escherichia coli and Micrococcus luteus on protein synthesis in vitro by E. coli and Bacillus subtilis

We have designed a set of nine plasmids containing the Bacillus pumilis cat gene with one of three Shine-Dalgarno (SD) sequences (weak, strong or stronger) and one of three initiation codons (AUG, GUG or UUG). These constructions have been used to determine the effect of ribosomal protein S1, SD and initiation codon sequences and Escherichia coli ribosomal protein S1 on translation in vitro by E. coli and B. subtilis ribosomes. Translation of these nine constructions was determined with three types of ribosomes: E. coli containing ribosomal protein S1, E. coli depleted of S1, and B. subtilis which is naturally free of S1. E. coli ribosomes were able to translate all nine transcripts with variable efficiencies. B. subtilis and S1-depleted E. coli ribosomes were similar to each other and differed from non-depleted E. coli ribosomes in that they required strong or stronger SD sequences and were unable to translate any of the weak transcripts. Addition of S1 from either E. coli or Micrococcus luteus, a Gram-positive bacterium, enabled S1-depleted E. coli ribosomes to translate mRNAs with weak SD sequences but had no effect on B. subtilis ribosomes. AUG was the preferred initiation codon for all ribosome types; however, B. subtilis ribosomes showed greater tolerance for the non-AUG codons than either type of E. coli ribosome. The presence of a strong or stronger SD sequence increased the efficiency by which E. coli ribosomes could utilize non-AUG codons.(ABSTRACT TRUNCATED AT 250 WORDS)

Translation initiation in Escherichia coli: sequences within the ribosome-binding site

The translational roles of the Shine-Dalgarno sequence, the initiation codon, the space between them, and the second codon have been studied. The Shine-Dalgarno sequence UAAGGAGG initiated translation roughly four times more efficiently than did the shorter AAGGA sequence. Each Shine-Dalgarno sequence required a minimum distance to the initiation codon in order to drive translation; spacing, however, could be rather long. Initiation at AUG was more efficient than at GUG or UUG at each spacing examined; initiation at GUG was only slightly better than UUG. Translation was also affected by residues 3' to the initiation codon. The second codon can influence the rate of initiation, with the magnitude depending on the initiation codon. The data are consistent with a simple kinetic model in which a variety of rate constants contribute to the process of translation initiation.

The influence of ribosome-binding-site elements on translational efficiency in Bacillus subtilis and Escherichia coli in vivo

A method is described to determine simultaneously the effect of any changes in the ribosome-binding site (RBS) of mRNA on translational efficiency in Bacillus subtilis and Escherichia coli in vivo. The approach was used to analyse systematically the influence of spacing between the Shine-Dalgarno sequence and the initiation codon, the three different initiation codons, and RBS secondary structure on translational yields in the two organisms. Both B. subtilis and E. coli exhibited similar spacing optima of 7-9 nucleotides. However, B. subtilis translated messages with spacings shorter than optimal much less efficiently than E. coli. In both organisms, AUG was the preferred initiation codon by two- to threefold. In E. coli GUG was slightly better than UUG while in B. subtilis UUG was better than GUG. The degree of emphasis placed on initiation codon type, as measured by translational yield, was dependent on the strength of the Shine-Dalgarno interaction in both organisms. B. subtilis was also much less able to tolerate secondary structure in the RBS than E. coli. While significant differences were found between the two organisms in the effect of specific RBS elements on translation, other mRNA components in addition to those elements tested appear to be responsible, in part, for translational species specificity. The approach described provides a rapid and systematic means of elucidating such additional determinants.

Mutational analysis of an inherently defective translation initiation site

In a reverse of many studies of translational initiation sites, we have explored the basis for the inactivity of an apparently defective initiation site. Gene VII of the filamentous phage f1 has a translational start site with highly unusual functional properties and a sequence dissimilar to a prokaryotic ribosome binding site. The VII site shows no activity in assays of independent initiation, even in a deletion series designed to remove potentially interfering RNA secondary structure. Activity from the VII site is only observed if the site is coupled to a source of translation immediately upstream, but its efficiency is low at a one-nucleotide spacing from the stop codon of the upstream cistron and extremely sensitive to the distance between the stop codon and the gene VII AUG. These and other atypical characteristics of coupling distinguish the VII site from most coupled initiation sites. To identify the pattern of nucleotide substitutions that give the VII site the capacity for independent initiation, a series of designed and random point mutations were introduced in the sequence. Improving the Shine-Dalgarno complementarity from GG to GGAG or GGAGG made activity detectable, but at only low levels. Random substitutions, each increasing activity above background by a small increment, were found at 16 positions throughout the region of ribosome contact. These substitutions lengthened the Shine-Dalgarno complementarity or changed the G and C residues present in the wild-type site to A or T. Significant activity was not observed unless a strong Shine-Dalgarno sequence and a number of the up-mutations were present together. The nature and distribution of the substitutions and their agreement with the known preferences for nucleotides in initiation sites provide evidence that the VII site's major defect is its primary sequence overall. It appears to lack the specialized sequence required to bind free 30 S ribosomes, and thus depends on the translational coupling process to give it limited activity.

Rapid method for altering bacterial ribosome-binding sequences for overexpression of proteins in Escherichia coli

In an Escherichia coli expression system, two genes, one from an anaerobic intestinal bacterium and one from E. coli, were overexpressed following the alteration of ribosome-binding (Shine-Dalgarno) sequences. For both genes, the polymerase chain reaction (PCR) was used to modify the ribosome-binding sequence and, at the same time, provide restriction endonuclease sequences at each end of the gene. These restriction endonuclease sequences were used for inserting the DNA into the E. coli plasmid vector pGEM2, which has the T7 promoter upstream from its multiple cloning sites. Each chimeric plasmid, made by ligating the PCR product into pGEM2, was transformed into E. coli strain HMS174(DE3) which, when induced, produces T7 RNA polymerase for regulated overexpression. The gene isolated from the anaerobic intestinal bacterium, a 27-kDa polypeptide gene from Eubacterium sp. strain 12708, when expressed using this system, produced about one-third of the total cell protein as measured in Coomassie-stained protein gels and confirmed by Western blots with rabbit antibody. The E. coli enzyme, a 28.4-kDa tRNA methylation enzyme, was increased fivefold in activity of cell extracts over that of the best previous strain.

Influence of mRNA determinants on translation initiation in Escherichia coli

We have studied the classic initiation elements of mRNA sequence and structure to better understand their influence on translation initiation rates in Escherichia coli. Changes introduced in the initiation codon, the Shine and Dalgarno sequence, the spacing between those two elements, and in the secondary structures within initiation domains each change the rate of 30 S ternary complex formation. We measured these differences using extension inhibition analysis, a technique we have called "toeprinting". The rate of 30 S initiation complex formation in the absence of initiation factors agrees well with in vivo translation rates in some instances, although in others a regulatory role of initiation factors in 30 S complex formation is likely. Nucleotides 5' to the Shine and Dalgarno domain facilitate ternary complex formation.

Antibacterial activity and inhibition of protein synthesis in Escherichia coli by antisense DNA analogs

Protein synthesis, which takes place within ribosomes, is essential for the survival of any living organism. Ribosomes are composed of both proteins and RNA. Specific interaction between the 3' end CCUCC sequence of prokaryotic 16S rRNA and a partially complementary sequence preceding the initiating codon of mRNA is believed to be a prerequisite for initiation of protein synthesis. Here we report the use of short (three to six nucleotides) synthetic DNA analogs complementary to this sequence to block protein synthesis in vitro and in vivo in Escherichia coli. In the DNA analogs the normal phosphodiester bond in the antisense DNA was replaced by methylcarbamate internucleoside linkages to enhance transport across plasma membranes. Of the analogs tested, those with the sequence AGG and GGA inhibit protein synthesis and colony formation by E. coli strains lacking an outer cell wall. Polyethylene glycol 1000 (PEG 1000) was attached to the 5' end of some of the test methylcarbamate DNAs to enhance solubility. Analogs of AGG and GGAG with PEG 1000 attached inhibited colony formation in normal E. coli. These analogs may be useful food additives to control bacterial spoilage and biomedically as antibiotics.

Binding of the bacteriophage T4 regA protein to mRNA targets: an initiator AUG is required

Bacteriophage T4 regA protein translationally represses the synthesis of a subset of early phage-induced proteins. The protein binds to the translation initiation site of at least two mRNAs and prevents formation of the initiation complex. We show here that the protein binds to the translation initiation sites of other regA-sensitive mRNAs. Analysis of mRNA binding by filtration and nuclease protection assays shows that AUG is necessary but not sufficient for specific binding of regA protein to its mRNA targets. Anticipating the need for large quantities of regA protein for structural studies to further define the regA protein-RNA ligand interaction, we also report cloning the regA gene into a T4 overexpression system. The expression of regA protein in uninfected E. coli is lethal, so in our system regA driven by a strong T7 promoter is sequestered in a T4 phage until 'induction' by phage infection is desired. We have replaced the regA sensitive wild-type ribosome binding site with a strong insensitive ribosome binding site at an optimal distance from the regA initiation codon for maximizing expression. We have obtained large amounts of regA protein.

Amino acid sequence of pheromone-inducible surface protein in Enterococcus faecalis, that is encoded on the conjugative plasmid pPD1

The major pheromone-inducible protein, PD78, believed to contribute to bacterial conjugation, was purified from Enterococcus (formerly Streptococcus) faecalis cells containing the plasmid pPD1. A cloned EcoRI-BglII 3.6-kbp fragment of the plasmid pAM351(pPdl::Tn916) contained an open reading frame corresponding to 467 amino acid residues representing PD78. In a central region of the deduced protein, there is a repeated sequence of X-X-Pro that is repeated 15 times. This is analogous to the Gln-Gln-Pro repeat in the C-terminal region of TraD product encoded on the R100 plasmid in Escherichia coli.

Suppression of the Escherichia coli dnaA46 mutation by a mutation in trxA, the gene for thioredoxin

The dasC mutation, an extragenic suppressor of dnaA46, was mapped by P1 transduction near the rep, trxA, rho region of the Escherichia coli chromosome. The dasC mutation could not be separated from trxA by P1 transduction indicating that dasC and trxA are allelic. Multicopy plasmids containing an intact trxA gene were able to reverse the suppressive effect of the dasC mutation on the dnaA46 mutation. Introduction of a frameshift mutation into the cloned trxA coding region abolished the ability of these recombinant plasmids to reverse the suppressive effect. These results indicate that dasC is allelic with trxA, the gene encoding thioredoxin.

Deletion formation in bacteriophage T4

We have manipulated the dispensable region of the rIIB gene of bacteriophage T4 in order to study the generation of deletions involving direct repeats. We show that recombination between different parental chromosomes is one source of the deletions we have studied. We have also investigated the effects of structure, base composition and distance on deletion formation. We demonstrate that the potential to form structure in single-stranded DNA has variable effects on the frequency of deletion formation and conclude that, in some cases, slipped mispairing during DNA synthesis can make a substantial contribution to deletion frequencies. The G + C richness of the direct repeats involved in deletion formation is an important parameter of the frequency of deletion formation. We have confirmed that increasing the distance between direct repeats decreases deletion frequency.

Expression of recombinant growth hormone in Escherichia coli: effect of the region between the Shine-Dalgarno sequence and the ATG initiation codon

We constructed a synthetic Escherichia coli expression system in which various promoter elements can be changed easily. In this study we investigated the effect of a number of portable Shine-Dalgarno regions (SD regions) on the synthesis of two modified recombinant human growth hormones (hGH). The production of these modified hGH was measured during exponential growth and after the bacteria had reached stationary phase. The results show that the optimal distance between the SD region (AGGAGG) and the ATG start codon is approximately 11 nucleotides. However, the nucleotide sequence in this region also influences expression: 6-10 adenines result in comparable expression levels despite the varying lengths. Two overlapping SD regions reduce expression of the growth hormones considerably, whereas two potential ATG start codons do not affect expression. Having a SD-ATG region partly or totally complementary to the 5' end of the 16S ribosomal RNA does not alter translation efficiency. Estimation of the delta G values for the association between the 16S rRNA and the ribosome-binding region suggests that these are not indicators of expression efficiency.

Search for the optimal sequence of the ribosome binding site by random oligonucleotide-directed mutagenesis

Synthetic DNA duplexes corresponding to the ribosome binding site (RBS) were synthesized through the phosphite method on solid support. The synthetic RBS DNA with partial random sequences was inserted into an appropriate site between the lpp-lac promoter and the beta-galactosidase structural gene in plasmid pMKT2. The level of beta-galactosidase expression was correlated with the color intensity of the recombinant colonies on X-gal plates. The bluest colonies were isolated and characterized with respect to beta-galactosidase enzyme activity and RBS sequence. There was good correlation between color intensity and the level of the enzyme activity, and this provided a reliable phenotypic screening method in the search for the optimal regulatory sequences. Novel RBS sequences obtained here show not only the unique nucleotide distribution, but also strong complemetarity to the 3' end region of 16S rRNA, from which could be deduced a generalized RBS sequence, the position of the SD region, and the 16S rRNA position mediated during translation initiation.

Transcriptional activation of bacteriophage T4 middle promoters by the motA protein

Transcriptional activation of middle genes in bacteriophage T4 requires the phage-encoded motA protein. Many middle genes are involved in deoxyribonucleotide biosynthesis and phage DNA replication. In the absence of motA, the gene products that are required for DNA synthesis are transcribed from other, upstream promoters. Using primer extension sequencing on RNA templates isolated from T4 motA+ and motA- infected cells, we have characterized 14 motA-dependent transcripts. The T4 middle promoters have a consensus sequence of nine base-pairs, (a/t)(a/t)TGCTT(t/c)A, spaced 11 to 13 nucleotides away from the Escherichia coli--10 consensus sequence, TAnnnT. The motA protein also can act as a transcriptional repressor for at least one early gene. Furthermore, the phage-encoded motA protein can activate in trans a middle promoter resident on a plasmid.

Wild-type bacteriophage T4 is restricted by the lambda rex genes

The bacteriophage T4 rII genes and the lambda rex (r exclusion) genes interact; rII mutants are unable to productively infect rex+ lambda lysogens. The relationship between rex and rII has been found to be quantitative, and plasmid clones of rex have excluded not only rII mutants but T4 wild type and most other bacteriophages as well. Mutations in the T4 motA gene substantially reversed exclusion of T4 by rex.

Bacteriophage T4 regA protein binds to mRNAs and prevents translation initiation

The bacteriophage T4 regA protein is a translational repressor of a subset of phage mRNAs. We show here that purified regA protein binds specifically to target mRNAs near the initiating AUG and occludes binding of ribosomes. Translational repression by regA protein diminishes expression of many genes whose mRNA sequences around the initiating AUG codons are different. A comparison of nucleotide sequences from several regA-repressed mRNAs suggests that the initiating AUG is an important, but not sufficient, sequence for regA binding.

A single base change in the Shine-Dalgarno region of 16S rRNA of Escherichia coli affects translation of many proteins

A single base mutation was constructed at position 1538 of Escherichia coli 16S rRNA, changing a cytidine to a uridine. This position is in the Shine-Dalgarno region, thought to be involved in base-pairing to mRNA during initiation of protein synthesis. The mutation was constructed by using a synthetic oligodeoxynucleotide that differs in sequence by one base from the wild-type sequence of 16S rRNA. This oligonucleotide was used as a primer on single-stranded DNA of phage M13, into which was cloned a specific region of DNA encoding 16S rRNA. The mutation is lethal when expressed from the normal promoters of rRNA operons, P1 and P2, in a high-copy-number plasmid. Expression can be repressed by a temperature-sensitive repressor, cI857, in combination with the bacteriophage lambda PL promoter. Induction of transcription by temperature shift yields mutant 16S rRNA that is processed and assembled into functional ribosomal subunits. The presence of mutant ribosomes retards cell growth and dramatically alters incorporation of [35S]methionine into a large proportion of the cellular proteins. The change in level of synthesis of individual proteins correlates with the change in base-pairing between mutant rRNA and the Shine-Dalgarno region of the mRNA.

Specialized ribosome system: preferential translation of a single mRNA species by a subpopulation of mutated ribosomes in Escherichia coli

In Escherichia coli, all mRNAs are translated by one pool of functionally identical ribosomes. Here, we describe a system in which a subpopulation of modified ribosomes are directed to a single mutated mRNA species. This was accomplished by changing the Shine-Dalgarno sequence that precedes the heterologous human growth hormone gene from 5' GGAGG to 5' CCTCC or 5' GTGTG. Translation of these modified mRNAs by wild-type ribosomes is very inefficient. When the anti-Shine-Dalgarno region (i.e., the region complementary to the Shine-Dalgarno sequence) at the 3' end of the gene encoding 16S rRNA (rrnB) was altered from 5' CCTCC to 5' GGAGG or 5' CACAC, thus restoring its potential to base-pair with the mutated human growth hormone mRNA, significant expression of this mRNA occurred. Growth hormone synthesis was dependent on induction of the mutated rrnB operon. Subsequently, these specialized ribosomes were made spectinomycin-resistant by the introduction of a C----U substitution at position 1192 of the 16S rRNA. Thus, host protein synthesis could be shut off by the addition of spectinomycin and the specificity and efficiency of the specialized ribosomes could be assessed. Since the specialized ribosomes represent a nonessential subpopulation in the cell, this system offers an approach to the study of mutations elsewhere in the 16S-rRNA gene that otherwise would be lethal to the cell.

Sequences and studies of bacteriophage T4 rII mutants

We have sequenced more than 80 mutants of the bacteriophage T4 rIIA and rIIB genes. These include deletions about whose origin we have speculated, mutations affecting the rIIB promoters, various pseudo-revertants of the rII- phenotype, including mutations that bring about the reinitiation of translation following termination, mutations that affect regulation of rIIB translation by regA, the toxic minute plaquing mutants FC237 and FC238 and their detoxifiers, and many more of the classic frameshifts from the Cambridge collection. These mutants have been sequenced using dideoxy-mediated chain termination by either Escherichia coli DNA polymerase using single-stranded DNA as a template or by avian retroviral reverse transcriptase using mRNA or DNA as the template molecule. We list the sequence changes of the mutants with pertinent historic and phenotypic data. The mutants that facilitate translation reinitiation are discussed, and we discuss a model that could account for the generation of many of the mutations.

Isolation and characterization of light-regulated phycobilisome linker polypeptide genes and their transcription as a polycistronic mRNA

Several cyanobacteria adjust both the phycobiliprotein and linker protein composition of the phycobilisome, a light-harvesting complex in cyanobacteria and some eucaryotic algae, to maximize absorption of prevalent wavelengths of light. This process is called complementary chromatic adaptation. We sequenced the amino terminus of a linker polypeptide which is associated with phycocyanin and accumulates to high levels during growth of the cyanobacterium Fremyella diplosiphon in red light. A mixed oligonucleotide encoding a region of this amino terminus was synthesized and used to identify a fragment of F. diplosiphon genomic DNA encoding the linker polypeptide. This linker gene was located between two other linker genes and contiguous to the red-light-induced phycocyanin gene set. Sequences of all three linker genes are presented. These genes were transcribed together onto a large polycistronic mRNA which also encoded the red-light-induced phycocyanin subunits. The relationship of this transcript to the biogenesis of the phycobilisome when F. diplosiphon is grown under different conditions of illumination is discussed.

Mutations affecting translation of the bacteriophage T4 rIIB gene cloned in Escherichia coli

Mutant ribosome binding sites of the bacteriophage T4 rIIB gene, resident on an 873 bp DNA fragment, were cloned into a plasmid vector as in-frame fusions to a reporter gene, beta-galactosidase. The collection of mutations included changes in the region 5' to the Shine/Dalgarno sequence, a mutation of the Shine/Dalgarno sequence, the alternate initiation codons GUG, AUA and ACG, and mutants in which several closely spaced initiation codons compete with each other on the same mRNA. The results show that the secondary structure variations we have installed 5' to the Shine/Dalgarno sequence have little effect on translation. GUG is essentially as good an initiator of translation as AUG when they are assayed on separate messages, but is outcompeted at least 50-fold in the sequence AUGUG. AUA and ACG are poor start codons, and are temperature sensitive. The initiation codon pair AUGAUA, in which the AUG is only two nucleotides from the Shine/Dalgarno sequence, displays a novel cold-sensitive phenotype.

Spectrum of spontaneous frameshift mutations. Sequences of bacteriophage T4 rII gene frameshifts

The DNA sequences of 185 independent spontaneous frameshift mutations in the rIIB gene of bacteriophage T4 are described. Approximately half of the frameshifts, including those at hot spot sites, are fully consistent with classical proposals that frameshift mutations are produced by a mechanism involving the misaligned pairing of repeated DNA sequences. However, the remaining frameshifts are inconsistent with this model. Correlations between the positions of two base-pair frameshifts and the bases of DNA hairpins suggest that local DNA topology might influence frameshift mutation. Warm spots for larger deletions share the property of having endpoints adjacent to DNA sequences whose complementarity to sequences a few base-pairs away suggest that non-classical DNA misalignments may participate in deletion mutation. A model for duplication mutation as a consequence of strand displacement synthesis is discussed. In all, 15 frameshifts were complex combinations of frameshifts and base substitutions. Three of these were identical, and have extended homology to a sequence 256 base-pairs away that is likely to participate in the mutational event; the remainder are unique combinations of frameshifts and transversions. The frequency and diversity of complex mutants suggest a challenge to the assumption that the molecular evolution of DNA must depend primarily upon the accumulation of single nucleotide changes.

Mutation that affects pepN translation initiation in Escherichia coli

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

Effects of GUG and AUG initiation codons on the expression of lacZ in Escherichia coli

We have replaced the ribosomal binding site (RBS) of the lacZ gene of E. coli by those of the maturation (A) gene of phage MS2 and that of the tufA gene. Both RBSs contain a GUG initiation codon. The expression with the tufA RBS is at least 25-fold higher than with the phage RBS. Changing the GUG into AUG results in a 3-fold increase in expression in both cases. In general, higher expression is accompanied by an increase of lac-specific mRNA. It is argued that this is a consequence of the more efficient translation of the mRNA.

Gene density over the chromosome of Escherichia coli: frequency distribution, spatial clustering, and symmetry

Published studies of gene density (the number of genetic loci per unit of length on the linkage map) for Escherichia coli report a nonrandom frequency distribution and indicate notable symmetry in spatial clustering of gene density. We reexamined these results and found that gene density is a random variable with a frequency distribution that is lognormal. That is, the logarithm of gene density is a normally distributed random variable. Furthermore, comparison of the observed E. coli map and computer-generated random maps showed that symmetries in the spatial clustering of gene density are not exceptional; these features arise naturally among genes (or loci) whose density has this frequency distribution. These results are discussed along with other related examples that illustrate the emerging importance of statistical inference in molecular genetics.

Primary structure of the hip gene of Escherichia coli and of its product, the beta subunit of integration host factor

We describe the isolation and sequencing of the hip gene of Escherichia coli and show that it encodes the beta subunit of integration host factor (IHF beta). In order to locate the coding region, we constructed a set of deletion mutants by exonucleolytic digestion of a fragment containing hip, determined which mutants were hip+ and which hip- by complementation, and then sequenced the ends of the critical deletions. The 5' end of the coding region was located precisely by comparing the deduced amino acid sequence to the actual N-terminal amino acid sequence of IHF. Our assignment of the coding region was further substantiated by the nucleotide sequences of a hip point mutant and of internal replacement mutations. We found a probable promoter for hip located about 85 base-pairs upstream from the initial AUG codon and about 75 base-pairs downstream from the 3' end of the neighboring gene, rpsA, and we constructed an IHF beta overproducer by fusing the coding sequences to the lambda pL promoter. A survey of known protein sequences revealed a close relationship between IHF beta and the type II prokaryotic DNA binding proteins (the "histone-like" proteins). This relationship is shared to a considerable extent by the other subunit of IHF, IHF alpha. A hip missense mutation that replaces a completely conserved glycine with aspartate has a null phenotype, suggesting that the conserved regions are functionally important.

Construction and properties of a ribosome-binding site mutation in gene E of phi X174 bacteriophage

Oligodeoxyribonucleotide mutagenesis has been used to produce a G----A mutation at nucleotide 557 of the phi X174 genome. This changes the ribosome-binding sequence GAGG of gene E to GAAG without affecting the amino acid, glutamine, encoded by the overlapping gene D. The phi X174rb(E)557 mutant does not lyse infected Escherichia coli C and therefore results in the accumulation of a large number intracellular mature phage particles. Thus, the mutation inactivates production of the gene E lytic product, presumably by blocking translation of gene E, without affecting other phage functions.

The influence of mRNA primary and secondary structure on human IFN-gamma gene expression in E. coli

Parameters influencing the efficiency of expression of the human immune interferon (IFN-gamma) gene in E. coli were studied by comparing a series of eight in vitro-derived gene variants. These contained all possible combinations of silent mutations in the first three codons of the mature IFN-gamma polypeptide coding sequence. Expression levels varied up to 50-fold among the different constructions. Comparison of messenger RNA secondary structure models for each variant suggested that the presence of stem-loop structures blocking the translation initiation signals could drastically decrease the efficiency of IFN-gamma synthesis. With variants displaying no stable mRNA secondary structure in the region, a C----U transition at position +11 after the AUG resulted in a 5-fold increase in expression indicating that RNA primary structure also plays an important role in expression. In addition we demonstrate that, in this system, a spacing of 8 nucleotides between the Shine-Dalgarno region and AUG was optimal for gene expression and that the steady-state production level of IFN-gamma rose exponentially with increasing rate of synthesis.

Recognition of messenger RNA during translational initiation in Escherichia coli

The structural aspects of recognition by E. coli ribosomes of translational initiation regions on homologous messenger RNAs have been reviewed. Also discussed is the location of initiation region on mRNA, its confines, typical nucleotide sequences responsible for initiation signal, and the influence of RNA macrostructure on protein synthesis initiation. Most of the published DNA nucleotide sequences surrounding the start of various E. coli genes and those of its phages have been collected.

A hotspot for transition mutations in the rIIB gene of bacteriophage T4. I. The extent of the hotspot

We have previously demonstrated that the sequence 5'TGGCAA 3' located at codons 32-33 of the rIIB gene of bacteriophage T4 is a hotspot for transition mutations (Nelson et al. 1981). Here I report the properties of the same TGGCAA sequence introduced into the gene at codons 11-12. The sequence is highly mutable in both locations, suggesting that its high mutability is due to features of the TGGCAA itself and is not dependent on the immediate juxtaposition of additional external sequences. Within this sequence, at either location, only the transition at the central G:C pair frequently arises spontaneously or by 2-aminopurine or ethylmethane sulfonate mutagenesis. However, the 3' G:C pair, in addition, is highly mutable after nitrous acid or hydroxylamine treatment. This suggests that, within the TGGCAA sequence, there are two hotspots which are targeted by different mutagens.

Portable Shine-Dalgarno regions: a system for a systematic study of defined alterations of nucleotide sequences within E. coli ribosome binding sites

We have developed a gene expression system in Escherichia coli that contains a portable Shine-Dalgarno region. Transcription of this system is under the direction of a hybrid promoter (tacII) derived from trp and lac-UV5 promoter sequences which is followed by a region that encodes a portable Shine-Dalgarno region (PSDR). Using a series of synthetic PSDRs, we varied the four bases that follow the Shine-Dalgarno (SD) region. We found that the presence of four A residues or four T residues in this position gives the highest translational efficiency. The presence of four C residues reduces the translation efficiency by 50% as compared with PSDRs with A or T residues. The presence of four G residues following the SD region lowers the translational efficiency by at least 75% with respect to PSDRs with A or T residues.

Determination of the amount of homology required for recombination in bacteriophage T4

Homology is an important feature of recombination. We have used the rll cistrons of bacteriophage T4 to determine the extent of homology required for recombination. We varied the amount of homologous DNA available for recombination in both marker rescue experiments and deletion-by-deletion crosses. Our results suggest that the primary pathway for recombination in T4 requires 50 bp of homology. Our finding that recombination is detectable when fewer than 50 bp of homology are available suggests that there is a second, less efficient pathway of recombination in T4. This pathway may be used during the formation of deletions.

Bacteriophage T4 as a generalized DNA-cloning vehicle

We have designed a method for inserting foreign DNA segments into bacteriophage T4. A plasmid containing T4 DNA is opened within the T4 sequence and the foreign DNA is inserted in vitro. Recombination in vivo, between T4 and the doubly chimeric plasmid, results in insertion of the foreign DNA into the genome of viable T4 phage. We have demonstrated the method by inserting a 203-bp DNA fragment from the lactose operon of Escherichia coli, into the dispensable region of the rIIB gene of T4. With minor modifications, the method should make possible the cloning of very large DNAs into any one of a large number of sites on the T4 chromosome.

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".

Increased synthesis in E. coli of fibroblast and leukocyte interferons through alterations in ribosome binding sites

Eleven chimeric plasmids have been constructed which direct the synthesis of mature human fibroblast (IFN-beta 1) or leukocyte interferon (IFN-alpha A) proteins under the control of the E. coli trp promoter. The plasmids differ with respect to the nucleotide spacing between the Shine-Dalgarno sequence of the trp leader and the ATG translation start signal of the interferon genes. By utilizing a unique Xba I endonuclease site located within the spacer region of the expression plasmids, the spacings were altered from 2-10 nucleotides or 7-15 nucleotides for the fibroblast and leukocyte interferon expression plasmids, respectively. The optimal spacing for expression, as determined by interferon assay, is 9 nucleotides for both types of transcripts, despite differences in nucleotide sequence within the spacer region and downstream from the AUG initiator. Yields of IFN-alpha A varied about six-fold, while among the different IFN-beta 1 expression plasmids a range of more than 100-fold in interferon production was observed. The difference in the range of variation between the IFN-alpha A and IFN-beta 1 plasmids is attributed partly to changes in messenger RNA secondary structure within the ribosome binding sites which affect message half-life.