Sequences within ribosome binding site affecting messenger RNA translatability and method to direct ribosomes to single messenger RNA species

StartLink and StartLink+: Prediction of Gene Starts in Prokaryotic Genomes

State-of-the-art algorithms of ab initio gene prediction for prokaryotic genomes were shown to be sufficiently accurate. A pair of algorithms would agree on predictions of gene 3'ends. Nonetheless, predictions of gene starts would not match for 15-25% of genes in a genome. This discrepancy is a serious issue that is difficult to be resolved due to the absence of sufficiently large sets of genes with experimentally verified starts. We have introduced StartLink that infers gene starts from conservation patterns revealed by multiple alignments of homologous nucleotide sequences. We also have introduced StartLink+ combining both ab initio and alignment-based methods. The ability of StartLink to predict the start of a given gene is restricted by the availability of homologs in a database. We observed that StartLink made predictions for 85% of genes per genome on average. The StartLink+ accuracy was shown to be 98-99% on the sets of genes with experimentally verified starts. In comparison with database annotations, we observed that the annotated gene starts deviated from the StartLink+ predictions for ∼5% of genes in AT-rich genomes and for 10-15% of genes in GC-rich genomes on average. The use of StartLink+ has a potential to significantly improve gene start annotation in genomic databases.

MetaPGN: a pipeline for construction and graphical visualization of annotated pangenome networks

Pangenome analyses facilitate the interpretation of genetic diversity and evolutionary history of a taxon. However, there is an urgent and unmet need to develop new tools for advanced pangenome construction and visualization, especially for metagenomic data. Here, we present an integrated pipeline, named MetaPGN, for construction and graphical visualization of pangenome networks from either microbial genomes or metagenomes. Given either isolated genomes or metagenomic assemblies coupled with a reference genome of the targeted taxon, MetaPGN generates a pangenome in a topological network, consisting of genes (nodes) and gene-gene genomic adjacencies (edges) of which biological information can be easily updated and retrieved. MetaPGN also includes a self-developed Cytoscape plugin for layout of and interaction with the resulting pangenome network, providing an intuitive and interactive interface for full exploration of genetic diversity. We demonstrate the utility of MetaPGN by constructing Escherichia coli pangenome networks from five E. coli pathogenic strains and 760 human gut microbiomes,revealing extensive genetic diversity of E. coli within both isolates and gut microbial populations. With the ability to extract and visualize gene contents and gene-gene physical adjacencies of a specific taxon from large-scale metagenomic data, MetaPGN provides advantages in expanding pangenome analysis to uncultured microbial taxa.

Bicistronic mRNAs to enhance membrane protein overexpression

Functional overexpression of membrane proteins is essential for their structural and functional characterization. However, functional overexpression is often difficult to achieve, and frequently either no expression or expression as misfolded aggregates is observed. We present an approach for improving the functional overexpression of membrane proteins in Escherichia coli using transcriptional fusions. The method involves the use of a small additional RNA sequence upstream to the RNA sequence of the target membrane protein and results in the production of a bicistronic mRNA. In contrast to the common approach of translational fusions to enhance protein expression, transcriptional fusions do not require protease treatment and subsequent removal of the fusion protein. Using this strategy, we observed improvements in the quantity and/or the quality of the produced material for several membrane proteins to levels compatible with structural studies. Our analysis revealed that translation of the upstream RNA sequence was not essential for increased expression. Rather, the sequence itself had a large impact on protein yields, suggesting that alternative folding of the transcript was responsible for the observed effect.

Enhanced production of coenzyme Q10 by self-regulating the engineered MEP pathway in Rhodobacter sphaeroides

Fine-tuning the expression level of an engineered pathway is crucial for the metabolic engineering of a host toward a desired phenotype. However, most engineered hosts suffer from nonfunctional protein expression, metabolic imbalance, cellular burden or toxicity from intermediates when an engineered pathway is first introduced, which can decrease production of the desired product. To circumvent these obstacles, we developed a self-regulation system utilizing the trc/tac promoter, LacI(q) protein and ribosomal binding sites (RBS). With the purpose of improving coenzyme Q10 (CoQ10 ) production by increasing the decaprenyl diphosphate supplement, enzymes DXS, DXR, IDI, and IspD were constitutively overexpressed under the control of the trc promoter in Rhodobacter sphaeroides. Then, a self-regulation system combining a set of RBSs for adjusting the expression of the LacI(q) protein was applied to tune the expression of the four genes, resulting in improved CoQ10 production. Finally, another copy of the tac promoter with the UbiG gene (involved in the ubiquinone pathway of CoQ10 biosynthesis) was introduced into the engineered pathway. By optimizing the expression level of both the upstream and downstream pathway, CoQ10 production in the mutants was improved up to 93.34 mg/L (7.16 mg/g DCW), about twofold of the wild-type (48.25 mg/L, 3.24 mg/g DCW).

Selection of Escherichia coli expression systems

This unit lists the most useful expression strains of E. coli for fermentation processes. Standard procedures are provided for several expression systems, namely, temperature induction via the p(L) promoter and chemical induction via the trp promoter, lac or tac promoters, and the T7 promoter. These protocols require that the gene encoding the protein of interest has been identified and cloned into an appropriate expression vector using standard molecular biology techniques. Transformation of a suitable host strain (e.g., by electroporation) is also described and is a prerequisite. Protocols for the analysis of plasmid stability and subsequent storage are provided. Support protocols describe how to prepare samples for electrophoresis, how to analyze the solubility of the expressed proteins, and how to make samples of periplasmic extracts and extracellular media (using TCA precipitation). Many of the support protocols are small-scale analysis procedures that are used to guide subsequent purification strategies and determine the suitability of the expression system for further development and scale-up.

Computational design of orthogonal ribosomes

Orthogonal ribosomes (o-ribosomes), also known as specialized ribosomes, are able to selectively translate mRNA not recognized by host ribosomes. As a result, they are powerful tools for investigating translational regulation and probing ribosome structure. To date, efforts directed towards engineering o-ribosomes have involved random mutagenesis-based approaches. As an alternative, we present here a computational method for rationally designing o-ribosomes in bacteria. Working under the assumption that base-pair interactions between the 16S rRNA and mRNA serve as the primary mode for ribosome binding and translational initiation, the algorithm enumerates all possible extended recognition sequences for 16S rRNA and then chooses those candidates that: (i) have a similar binding strength to their target mRNA as the canonical, wild-type ribosome/mRNA pair; (ii) do not bind mRNA with the wild-type, canonical Shine-Dalgarno (SD) sequence and (iii) minimally interact with host mRNA irrespective of whether a recognizable SD sequence is present. In order to test the algorithm, we experimentally characterized a number of computationally designed o-ribosomes in Escherichia coli.

Identification of an AU-rich translational enhancer within the Escherichia coli fepB leader RNA

The fepB gene encodes a periplasmic binding protein that is essential for the uptake of ferric enterobactin by Escherichia coli. Its transcription is regulated in response to iron levels by the Fur repressor. The fepB transcript includes a 217-nucleotide leader sequence with several features suggestive of posttranscriptional regulation. To investigate the fepB leader for its contribution to fepB expression, defined deletions and substitution mutations in the leader were characterized using fepB-phoA translational fusions. The fepB leader was found to be necessary for maximal fepB expression, primarily due to the influence of an AU-rich translational enhancer (TE) located 5' to the Shine-Dalgarno sequence. Deletions or substitutions within the TE sequence decreased fepB-phoA expression fivefold. RNase protection and in vitro transcription-translation assays demonstrated that the TE augmented translational efficiency, as well as RNA levels. Moreover, primer extension inhibition assays showed that the TE increases ribosome binding. In contrast to the enhancing effect of the TE, the natural fepB GUG start codon decreased ribosome binding and reduced fepB expression 2.5-fold compared with the results obtained with leaders bearing an AUG initiation codon. Thus, the TE-GUG organization in fepB results in an intermediate level of expression compared to the level with AUG, with or without the TE. Furthermore, we found that the TE-GUG sequence is conserved among the eight gram-negative strains examined that have fepB genes, suggesting that this organization may provide a selective advantage.

Forceful large-scale expression of "problematic" membrane proteins

We developed an Escherichia coli expression system for overproduction of a highly toxic membrane protein that is impossible to overexpress by traditionally used approaches. The method is based on combination of the genetic modifications of a bicistronic expression plasmid, stabilization of a synthesized protein, and selection of a compatible expression host. This enabled us to enhance the expression level of a toxic membrane protein 30-50 times compared with expression in the native state and to obtain 3-5mg of a highly purified functionally active protein per liter of culture. We describe the method for the amplified expression of membrane proteins, using the Pseudomonas aeruginosa multidrug resistance protein, MexY, as an example. The amplified MexY was correctly folded in the cytoplasmic membrane of the E. coli without forming inclusion bodies. This method can be applicable to the large-scale expression of the other problematic membrane proteins that are otherwise extremely difficult to overproduce.

Investigating and Engineering Enzymes by Genetic Selection

Natural enzymes have arisen over millions of years by the gradual process of Darwinian evolution. The fundamental steps of evolution-mutation, selection, and amplification-can also be exploited in the laboratory to create and characterize protein catalysts on a human timescale. In vivo genetic selection strategies enable the exhaustive analysis of protein libraries with 10(10) different members, and even larger ensembles can be studied with in vitro methods. Evolutionary approaches can consequently yield statistically meaningful insight into the complex and often subtle interactions that influence protein folding, structure, and catalytic mechanism. Such methods are also being used increasingly as an adjunct to design, thus providing access to novel proteins with tailored catalytic activities and selectivities.

Expression and stabilization of galactose oxidase in Escherichia coli by directed evolution

We have used directed evolution methods to express a fungal enzyme, galactose oxidase (GOase), in functional form in Escherichia coli. The evolved enzymes retain the activity and substrate specificity of the native fungal oxidase, but are more thermostable, are expressed at a much higher level (up to 10.8 mg/l of purified GOase), and have reduced negative charge compared to wild type, all properties which are expected to facilitate applications and further evolution of the enzyme. Spectroscopic characterization of the recombinant enzymes reveals a tyrosyl radical of comparable stability to the native GOase from Fusarium.

Differential interaction of maize root ferredoxin:NADP(+) oxidoreductase with photosynthetic and non-photosynthetic ferredoxin isoproteins

In higher plants ferredoxin (Fd):NADP(+) oxidoreductase (FNR) and Fd are each distributed in photosynthetic and non-photosynthetic organs as distinct isoproteins. We have cloned cDNAs for leaf FNR (L-FNR I and L-FNR II) and root FNR (R-FNR) from maize (Zea mays L.), and produced recombinant L-FNR I and R-FNR to study their enzymatic functions through kinetic and Fd-binding analyses. The K(m) value obtained by assay for a diaphorase activity indicated that R-FNR had a 10-fold higher affinity for NADPH than L-FNR I. When we assayed for NADPH-cytochrome c reductase activity using maize photosynthetic Fd (Fd I) and non-photosynthetic Fd (Fd III), the R-FNR showed a marked difference in affinity between these two Fd isoproteins; the K(m) for Fd III was 3.0 microM and that for Fd I was 29 microM. Consistent with this, the dissociation constant for the R-FNR:Fd III complex was 10-fold smaller than that of the R-FNR:Fd I complex. This differential binding capacity was confirmed by an affinity chromatography of R-FNR on Fd-sepharose with stronger binding to Fd III. L-FNR I showed no such differential interaction with Fd I and Fd III. These data demonstrated that R-FNR has the ability to discriminate between these two types of Fds. We propose that the stronger interaction of R-FNR with Fd III is crucial for an efficient electron flux of NADPH-FNR-Fd cascade, thus supporting Fd-dependent metabolism in non-photosynthetic organs.

Molecular cloning and high-level expression of human polymerase beta cDNA and comparison of the purified recombinant human and rat enzymes

The cDNA encoding the human polymerase beta from HeLa cells was PCR amplified and cloned, and its nucleotide sequence determined. The DNA sequence is identical to the polymerase beta cDNA sequence from Tera-2 cells. Three expression strategies were employed that were designed to maximize translation initiation of the polymerase beta mRNA in Escherichia coli and all yielded a high level of human polymerase beta. The recombinant protein was purified and its properties were compared with those of the recombinant rat enzyme. The domain structure and kinetic parameters (k(cat) and K(m)) were nearly identical. A mouse IgG monoclonal antibody to the rat enzyme (mAb-10S) was approximately 10-fold less reactive with the human enzyme than with the rat enzyme as determined by ELISA.

Complementary DNA cloning and characterization of ferredoxin localized in bundle-sheath cells of maize leaves

In maize (Zea mays L.) two leaf-specific ferredoxin (Fd) isoproteins, Fd I and Fd II, are distributed differentially in mesophyll and bundle-sheath cells. A novel cDNA encoding the precursor of Fd II (pFD2) was isolated by heterologous hybridization using a cDNA for Fd I (pFD1) as a probe. The assignment of the cDNAs to the Fds was verified by capillary liquid-chromatography/electrospray ionization-mass spectrometry. RNA-blot analysis demonstrated that transcripts for Fd I and Fd II accumulated specifically in mesophyll and bundle-sheath cells, respectively. The mature regions of pFD1 and pFD2 were expressed in Escherichia coli as functional Fds. Fd I and Fd II had similar redox potentials of -423 and -406 mV, respectively, but the Km value of Fd-NADP+ reductase for Fd II was about 3-fold larger than that for Fd I. Asparagine at position 65 of Fd II is a unique residue compared with Fd I and other Fds from various plants, which have aspartic acid or glutamic acid at the corresponding position as an electrostatic interaction site with Fd-NADP+ reductase. Substitution of asparagine-65 with aspartic acid increased the affinity of Fd II with Fd-NADP+ reductase to a level comparable to that of Fd I. These structural and functional differences of Fd I and Fd II may be related to their cell-specific expression in the leaves of a C4 plant.

Increased production of low molecular weight recombinant proteins in Escherichia coli

A general method for obtaining high-level production of low molecular weight proteins in Escherichia coli is described. This method is based on the use of a novel Met-Xaa-protein construction which is formed by insertion of a single amino acid residue (preferably Arginine or Lysine) between the N-terminal methionine and the protein of interest. The utility of this method is illustrated by examples for achieving high-level production of human insulin-like growth factor-1, human proinsulin, and their analogs. Furthermore, highly produced insulin-like growth factor-1 derivatives and human proinsulin analogs are converted to their natural sequences by removal of dipeptides with cathepsin C.

Productive interactions between the two domains of pig heart CoA transferase during folding and assembly

The enzyme CoA transferase from porcine heart (EC 2.8.3.5) is a homodimer; each subunit consists of two domains linked by a hydrophilic "hinge" region. We have prepared separate DNA segments encoding each of these domains. Incorporation of these two DNA segments within an operon or within two separate transcription units does not preclude the synthesis and assembly of CoA transferase in Escherichia coli. When the two domain fragments are produced and purified individually from separate cultures and subsequently mixed, enzyme activity accumulates to near wild-type levels only after a lengthy incubation. Each domain is more susceptible to aggregation than wild-type CoA transferase. Circular dichroism shows that, prior to mixing, the domains possess a different secondary structural profile compared to their counterparts in the native enzyme. However, mixing and incubation of the domains produces a complex with far-UV CD, fluorescence, and ultracentrifugation properties similar to those of wild-type CoA transferase. Finally, we show that the intact hydrophilic peptide which links the two domains is essential for the recovery of activity observed upon refolding of the denatured enzyme in vitro. These results indicate that the folding and assembly of pig heart CoA transferase require a productive interaction between its two domains, involving a substantial conformational rearrangement.

Purification and characterization of human and mouse recombinant alpha-fetoproteins expressed in Escherichia coli

Alpha-fetoprotein (AFP) is a tumor-associated embryonic molecule whose precise biological function(s) remains unclear. A more complete analysis of the physiological activities of this oncofetal protein has, until now, been severely limited by the lack of an appropriate source from which to obtain pure AFP in any sizeable quantity. In the present investigation, we obviate this problem by cloning and efficiently overexpressing mature mouse and human AFP cDNA's in Escherichia coli. For recombinant mouse AFP (rMoAFP), large segments of the coding region were excised from the preexisting plasmids pAFP1 and pAFP2, which together encompass 90% of the AFP sequence. The mouse cDNA was made complete by the addition of N- and C-terminal encoding oligonucleotides. Mouse AFP cDNA was expressed directly as a full-length molecule in vector pTrp4 or as fusion proteins in plasmids pMALc and pRX1 under the transcriptional control of trp or tac promoters. Accumulation of rMoAFP was significantly increased in protease-deficient E. coli strains over nonprotease-deficient strains, > or = 10% of total cell protein. Of the gene fusion proteins examined, none offered significant advantage over the direct expression product in terms of recombinant protein stability, overall levels of synthesis, or facilitated purification. Recombinant AFP polypeptides expressed by pTrp4 were as expected, deposited in bacterial inclusion bodies. Subsequent to resolubilization/refolding, rMoAFP was first enriched by passage over Q-Sepharose resin followed by final purification using immobilized copper-chelate affinity chromatography. Protein sequencing of the N-terminus revealed that purified rMoAFP had a deletion of the first nine amino acids coded for by the full-length mouse AFP cDNA. Similar N-terminal deletions are observed with AFP isolates originating from natural sources. A complete human AFP cDNA was generated from a fetal liver cDNA library and was cloned into vector pTrp4. Recombinant human AFP (rHuAFP) was expressed under the identical conditions employed for rMoAFP but purification had to be modified to include preparative Mono Q anion exchange chromatography. N-terminal sequencing, amino acid compositional analysis, and electrospray mass spectrometry revealed that purified rHuAFP was intact and unaltered and that the initiator methionine was completely removed. The biological activity of recombinant AFP, as judged by its inhibitory effects on in vitro lymphocyte proliferation, was equivalent to that of the native protein. The availability of large quantities of mouse and human recombinant AFP molecules should now permit detailed structure-function analyses of this important oncofetal protein to proceed in a manner unimpeded by previous limitations in both quantity and quality of the native proteins.

Analysis of the structural gene encoding a hemolysin in Vibrio mimicus

An environmental isolate of V. mimicus, strain E-33, has been reported to produce and secrete a hemolysin of 63 kDa. The hemolysin is enterotoxic in test animals. The nucleotide sequence of the structural gene of the hemolysin was determined. We found a 2,232 bp open reading frame, which codes a peptide of 744 amino acids, with a calculated molecular weight of 83,903 Da. The sequence for the structural gene was closely related to the V. cholerae el tor hlyA gene, coding an exocellular hemolysin. The amino terminal amino-acid sequence of the 63 kDa hemolysin, purified from V. mimicus, was determined by the Edman degradation method and found to be NH2-S-V-S-A-N-N-V-T-N-N-N-E-T. This sequence is identified from S-152 to T-164 predicted from the nucleotide sequence. So, it seems that the mature hemolysin in V. mimicus is processed upon deleting the first 151 amino acids, and the molecular mass is 65,972 Da. Analyzing the deduced amino-acid sequence, we also found a potential signal sequence of 24 amino acids at the amino terminal. Our results suggest that, like V. cholerae hemolysin, two-step processing also exists in V. Mimicus hemolysin.

Translation is enhanced after silent nucleotide substitutions in A+T- rich sequences of the coding region of CD46 cDNA

Specific sequences in the coding region of CD46 (membrane cofactor protein) transcripts have been shown to have a marked effect on translation. Two A+T-rich regions of CD46 cDNA were altered by mutation without changing the CD46 amino acid sequence (silent nucleotide substitution). In one region, the A+T content was reduced from 78% to 55% and in the other a putative polyadenylation addition sequence was disrupted. In each example, mutated sequences transfected into COS-7 cells produced significantly more soluble or cell surface protein (up to a 20-fold increase) than wild-type sequences. The amount of cellular plasmid DNA and CD46 mRNA was not increased, suggesting that the effect was not due to increased transfection efficiency, or transcript synthesis or stability. Biosynthetically labelled transfected cells showed an increase in translation rate but cell-free in vitro translation studies demonstrated that wild-type and mutated transcripts were translated with similar efficiency. The data show that translation of CD46 is affected by specific mRNA coding sequences, 400-540 bases from the initiation codon, and suggest that these sequences require the structural integrity of the cell to exert their effect.

Optimization of recombinant gene expression in Escherichia coli

The major targets for improvement of recombinant expression efficiency in Escherichia coli are gene dosage, transcription and, to some extent, translation. In order to evaluate the relative importance of these factors, the kinetics of specific mRNA compared to product formation was studied for different widely used expression systems, producing recombinant human superoxide dismutase. For a system employing phage T7 RNA polymerase, where a high level of recombinant protein expression puts a high metabolic burden on the cells, it was shown that transcription is not the limiting factor. To improve the translation rate of a common vector based on the tac promoter, the Shine-Dalgarno (SD) sequence was mutated towards stronger homology to the anti-SD sequence of the E. coli 16S rRNA. A 12.2-fold increase in protein yield was accompanied by a 4.3-fold increase in specific mRNA, indicating that transcription of the recombinant gene is coupled to translation. As this coupling amplifies the detrimental effect of a low-efficiency ribosomal binding site, much attention should be paid to translation initiation when optimizing a recombinant protein production system. Finally, reasons for the high expression level before induction are discussed, and first results towards reducing it are presented.

Optimized bacterial production of nonglycosylated human transferrin and its half-molecules

Transferrin is a glycoprotein functioning in iron transport in higher eukaryotes, and consists of two highly homologous domains. To study the function of the glycan residues attached exclusively to the C-terminal domain, we have constructed a plasmid allowing production of nonglycosylated human transferrin in Escherichia coli. By molecular biological and genetic techniques, production was stepped up to 60 mg/l. Similar plasmids were constructed for production of the two half-transferrins. The recombinant proteins accumulate in inclusion-body-like aggregates, where they appear to bind iron without causing bacteriostasis. Proteins active in iron binding have been purified from these inclusion bodies.

Mechanism of post-segregational killing by hok-homologue pnd of plasmid R483: two translational control elements in the pnd mRNA

The pnd system of plasmid R483 mediates plasmid stabilization by killing of plasmid-free cells. The pnd mRNA is very stable and can be translated into PndA protein, a cell toxin which kills the cells from within by damaging the cell membrane. Translation of the pnd mRNA is inhibited by the PndB antisense, a small labile RNA of 63 nt. The rapid decay of the PndB antidote leads to onset of PndA synthesis in plasmid-free segregants or after addition of rifampicin. Surprisingly however, the full-length pnd mRNA was found to be translationally inactive whereas a 3'-end truncated version of it was found to be active. We have therefore suggested previously, that the 3'-end of the full-length pnd mRNA encodes a fold-back inhibitory sequence (fbi), which prevents its translation. Here we present an analysis of the metabolism of the pnd mRNAs. A mutational analysis shows that single point mutations in the fbi motif results in more rapid truncation. The fbi mutations could not be complemented by second-site mutations in either of the pndA or pndC Shine-Dalgarno (SD) elements. Surprisingly, mutations in the pndC SD element also lead to a more rapid truncation. The effect of these latter mutations was, however, complemented by mutations in a proposed anti-SD element upstream of the pndC SD. Mutations in the anti-SD element were lethal. These results show, that the pnd mRNA contains two negative control elements, one located in its very 3'-end (fbi), and one located just upstream of the pndC SD region (the anti-SD element). These observations add to the complexity of the induction scheme previously proposed to explain activation of pndA expression in plasmid-free cells: In addition to its negative effect of translation, the fbi structure also maintains a reduced processing rate in the 3'-end of the mRNA. This permits the accumulation of a reservoir of pnd mRNA, which can be activated by 3'-end processing in plasmid-free cells. The anti-SD may prevent translation of the pnd mRNA during transcription, thus preventing detrimental synthesis of toxin.

Vitamin B12 repression of the cob operon in Salmonella typhimurium: translational control of the cbiA gene

Expression of the cob operon is repressed by B12 via a post-transcriptional control mechanism which requires sequence elements within the leader region of the mRNA and the first gene of the operon, the cbiA gene. Here we show that B12 repression of cbiA gene expression occurs at the level of translation initiation through sequestration of the ribosomal binding site (rbs) in an RNA hairpin. Analysis of mutations that destabilize or restabilize the secondary structure demonstrates that folding of the hairpin is essential for repression. The existence of the hairpin was confirmed by a secondary structure analysis of RNA from the wild type and three mutants. Deletions that remove the upstream part of the leader confer a drastic reduction in translation efficiency. This low-level translation is caused by the hairpin, as indicated by the finding that suppressor mutations that destabilize the hairpin restore efficient translation. Thus, the native upstream RNA functions as a translation enhancer and acts to relieve the hairpin's inhibitory effect on translation initiation. The inhibitory effect of the hairpin was confirmed by a ribosomal toeprinting analysis. We propose that the translational control of the cbiA gene mediates repression of the entire cob operon.

Translational initiation on structured messengers. Another role for the Shine-Dalgarno interaction

Translational efficiency in Escherichia coli is in part determined by the Shine-Dalgarno (SD) interaction, i.e. the base-pairing of the 3' end of 16S ribosomal RNA to a stretch of complementary nucleotides in the messenger, located just upstream of the initiation codon. Although a large number of mutations in SD sequences have been produced and analysed, it has so far not been possible to find a clear-cut quantitative relationship between the extent of the complementarity to the rRNA and translational efficiency. This is presumably due to a lack of information about the secondary structures of the messengers used, before and after mutagenesis. Such information is crucial, because intrastrand base-pairing of a ribosome binding site can have a profound influence on its translational efficiency. By site-directed mutagenesis, we have varied the extent of the SD complementarity in the coat-protein gene of bacteriophage MS2. The ribosome binding site of this gene is known to adopt a simple hairpin structure. Substitutions in the SD region were combined with other mutations, which altered the stability of the structure in a predictable way. We find that mutations reducing the SD complementarity by one or two nucleotides diminish translational efficiency only if ribosome binding is impaired by the structure of the messenger. In the absence of an inhibitory structure, these mutations have no effect. In other words, a strong SD interaction can compensate for a structured initiation region. This can be understood by considering translational initiation on a structured ribosome binding site as a competition between intramolecular base-pairing of the messenger and binding to a 30 S ribosomal subunit. A good SD complementarity provides the ribosome with an increased affinity for its binding site, and thereby enhances its ability to compete against the secondary structure. This function of the SD interaction closely parallels the RNA-unfolding capacity of ribosomal protein S1. By comparing the expression data from mutant and wild-type SD sequences, we have estimated the relative contribution of the SD base-pairs to ribosome-mRNA affinity. Quantitatively, this contribution corresponds quite well with the theoretical base-pairing stabilities of the wild-type and mutant SD interactions.

Translational initiation at the coat-protein gene of phage MS2: native upstream RNA relieves inhibition by local secondary structure

Maximal translation of the coat-protein gene from RNA bacteriophage MS2 requires a contiguous stretch of native MS2 RNA that extends hundreds of nucleotides upstream from the translational start site. Deletion of these upstream sequences from MS2 cDNA plasmids results in a 30-fold reduction of translational efficiency. By site-directed mutagenesis, we show that this low level of expression is caused by a hairpin structure centred around the initiation codon. When this hairpin is destabilized by the introduction of mismatches, expression from the truncated messenger increases 20-fold to almost the level of the full-length construct. Thus, the translational effect of hundreds of upstream nucleotides can be mimicked by a single substitution that destabilizes the structure. The same hairpin is also present in full-length MS2 RNA, but there it does not impair ribosome binding. Apparently, the upstream RNA somehow reduces the inhibitory effect of the structure on translational initiation. The upstream MS2 sequence does not stimulate translation when cloned in front of another gene, nor can unrelated RNA segments activate the coat-protein gene. Several possible mechanisms for the activation are discussed and a function in gene regulation of the phage is suggested.

A pink bacterium as a reporter system signaling expression of a recombinant protein

We describe a set of expression vectors, pEX-PINK/0-3, for high-level production of (un)fused target proteins. The vectors incorporate a 'pink' reporter element, which signals in vivo the expression status of a target gene. A target sequence is cloned between the lambda PL promoter and the downstream mammalian cytochrome b5 gene. Thermo-induction drives transcription of a dicistronic mRNA from which the target protein and cytochrome b5 are independently and concurrently synthesized. Positive expression is indicated by visual transformation of bacteria from a grey/translucent to a bright pink color derived from tandemly expressed holocytochrome b5. The signal can be monitored in vivo spectrophotometrically.

Nucleotide sequence of dcrA, a Desulfovibrio vulgaris Hildenborough chemoreceptor gene, and its expression in Escherichia coli

The amino acid sequence of DcrA (Mr = 73,000), deduced from the nucleotide sequence of the dcrA gene from the anaerobic, sulfate-reducing bacterium Desulfovibrio vulgaris Hildenborough, indicates a structure similar to the methyl-accepting chemotaxis proteins from Escherichia coli, including a periplasmic NH2-terminal domain (Mr = 20,700) separated from the cytoplasmic COOH-terminal domain (Mr = 50,300) by a hydrophobic, membrane-spanning sequence of 20 amino acid residues. The sequence homology of DcrA and these methyl-accepting chemotaxis proteins is limited to the COOH-terminal domain. Analysis of dcrA-lacZ fusions in E. coli by Western blotting (immunoblotting) and activity measurements indicated a low-level synthesis of a membrane-bound fusion protein of the expected size (Mr = approximately 137,000). Expression of the dcrA gene under the control of the Desulfovibrio cytochrome c3 gene promoter and ribosome binding site allowed the identification of both full-length DcrA and its NH2-terminal domain in E. coli maxicells.