J. van Duin

Secondary structure of the ribosome binding site determines translational efficiency: a quantitative analysis.

We have quantitatively analyzed the relationship between translational efficiency and the mRNA secondary structure in the initiation region. The stability of a defined hairpin structure containing a ribosome binding site was varied over 12 kcal/mol (1 cal = 4.184 J) by site-directed mutagenesis and the effects on protein yields were analyzed in vivo. The results reveal a strict correlation between translational efficiency and the stability of the helix. An increase in its delta G0 of -1.4 kcal/mol (i.e., less than the difference between an A.U and a G.C pair) corresponds to the reduction by a factor of 10 in initiation rate. Accordingly, a single nucleotide substitution led to the decrease by a factor of 500 in expression because it turned a mismatch in the helix into a match. We find no evidence that exposure of only the Shine-Dalgarno region or the start codon preferentially favors recognition. Translational efficiency is strictly correlated with the fraction of mRNA molecules in which the ribosome binding site is unfolded, indicating that initiation is completely dependent on spontaneous unfolding of the entire initiation region. Ribosomes appear not to recognize nucleotides outside the Shine-Dalgarno region and the initiation codon.

Function of Escherichia coli ribosomal protein S1 in translation of natural and synthetic messenger RNA

Abstract The effect of Escherichia coli ribosomal protein S1 on translation has been studied in S1-depleted systems programmed with poly(U), poly(A) and MS2 RNA ‡ . The translation of the phage RNA depends strictly on the presence of S1. Optimum poly(U)-directed polyphenylalanine synthesis and poly(A)-programmed polylysine synthesis also require S1. Excess S1 relative to ribosomes and messenger RNA results in inhibition of translation of MS2 RNA and poly(U), but not of poly (A). In the case of phage RNA translation, this inhibition can be counteracted by increasing the amount of messenger RNA. Three other 30 S ribosomal proteins (S3, S14 and S21) are also shown to inhibit MS2 RNA translation. The effects of S1 on poly(U) translation were studied in detail and shown to be very complex. The concentration of Mg 2+ in the assay mixtures and the ratio of S1 relative to ribosomes and poly(U) are crucial factors determining the response of this translational system towards the addition of S1. The results of this study are discussed in relation to recent developments concerning the function of this protein.

Functional heterogeneity of the 30 s ribosomal subunit of Escherichia coli: III. Requirement of protein s1 for translation

Abstract Poly(U)-dependent polyphenylalanine synthesis is completely dependent on the presence of ribosomal protein S1. Polysomes generated under the direction of poly(U) contain approximately one molecule of S1 per ribosome. Isolation of 30 S ribosomes from poly(U)-generated polysomes by a procedure requiring a low concentration of Mg 2+ (0·25 mM) results in loss of S1. S1 is probably also required for the phage RNA-dependent binding of formylmethionyl-tRNA. The data are discussed in relation to current concepts of the functional aspects of ribosome heterogeneity.

Leeway and constraints in the forced evolution of a regulatory RNA helix.

The start of the coat protein gene of RNA phage MS2 adopts a well‐defined hairpin structure of 12 bp (including one mismatch) in which the start codon occupies the loop position. An earlier expression study using partial MS2 cDNA clones had indicated that the stability of this hairpin is important for gene expression. For every ‐1.4 kcal/mol increase in stability a 10‐fold reduction in coat protein was obtained. Destabilizations beyond the wild‐type value did not affect expression. These results suggested that the hairpin was tuned in the sense that it has the highest stability still compatible with maximal ribosome loading. Employing an infectious MS2 cDNA clone, we have now tested the prediction that the delta G 0 of the coat protein initiator helix is set at a precise value. We have introduced stabilizing and destabilizing mutations into this hairpin in the intact phage and monitored their evolution to viable species. By compensatory mutations, both types of mutants quickly revert along various pathways to wild‐type stability, but not to wild‐type sequence. As a rule the second‐site mutations do not change the encoded amino acids or the Shine‐Dalgarno sequence. The return of too strong hairpins to wild‐type stability can be understood from the need to produce adequate supplies of coat protein. The return of unstable hairpins to wild‐type stability is not self‐evident and is presently not understood. The revertants provide an evolutionary landscape of slightly suboptimal phages, that were stable at least for the duration of the experiment (approximately 20 infection cycles).(ABSTRACT TRUNCATED AT 250 WORDS)

Functional heterogeneity of the 30S ribosomal subunit ofEscherichia coli

SummaryNative 30S ribosomal subunits fromEscherichia coli are deficient in fractional protein S21, which is present on the monosome and polysome-derived 30S subunits. The presence of S21 prevents the binding of Fmet-tRNA if and only if 50S subunits are present. In contrast, proteins S2, S3 and S14 stimulate the binding of Fmet-tRNA. These results have been used to rationalize other data concerning the mechanism of Fmet-tRNA binding by ribosomes. In addition, the present data indicate that the 30S ribosomal subunits are heterogeneousin vivo as well asin vitro.

Secondary structure of the central region of bacteriophage MS2 RNA: conservation and biological significance

The RNA of the Escherichia coli RNA phages is highly structured with 75% of the nucleotides estimated to take part in base-pairing. We have used enzymatic and chemical sensitivity of nucleotides, phylogenetic sequence comparison and the phenotypes of constructed mutants to develop a secondary structure model for the central region (900 nucleotides) of the group I phage MS2. The RNA folds into a number of, mostly irregular, helices and is further condensed by several long-distance interactions. There is substantial conservation of helices between the related groups I and II, attesting to the relevance of discrete RNA folding. In general, the secondary structure is thought to be needed to prevent annealing of plus and minus strand and to confer protection against RNase. Superimposed, however, are features required to regulate translation and replication. The MS2 RNA section studied here contains three translational start sites, as well as the binding sites for the coat protein and the replicase enzyme. Considering the density of helices along the RNA, it is not unexpected to find that all these sites lie in helical regions. This fact, however, does not mean that these sites are recognized as secondary structure elements by their interaction partners. This holds true only for the coat protein binding site. The other four sites function in the unfolded state and the stability of the helix in which they are contained serves to negatively control their accessibility. Mutations that stabilize helices containing ribosomal binding sites reduce their efficiency and vice versa. Comparison of homologous helices in different phage RNAs indicates that base substitutions have occurred in such a way that the thermodynamic stability of the helix is maintained. The evolution of individual helices shows several distinct size-reduction patterns. We have observed codon deletions from loop areas and shortening of hairpins by base-pair deletions from either the bottom, the middle or the top of stem structures. Evidence for the coaxial stacking of some helical segments is discussed.

Processing and functional display of the 86 kDa heterodimeric penicillin G acylase on the surface of phage fd.

The large heterodimeric penicillin G acylase from Alcaligenes faecalis was displayed on the surface of phage fd. We fused the coding sequence (alpha subunit-internal peptide-beta subunit) to the gene of a phage coat protein. A modified g3p signal sequence was used to direct the polypeptide to the periplasm. Here we show that a heterodimeric enzyme can be expressed as a fusion protein that matures to an active biocatalyst connected to the coat protein of phage fd, resulting in a phage to which the beta-subunit is covalently linked and the alpha-subunit is non-covalently attached. The enzyme can be displayed either fused to the minor coat protein g3p or fused to the major coat protein g8p. In both cases the penicillin G acylase on the phage has the same Michaelis constant as its freely soluble counterpart, indicating a proper folding and catalytic activity of the displayed enzyme. The display of the heterodimer on phage not only allows its further use in protein engineering but also offers the possibility of applying this technology for the excretion of the enzyme into the extracellular medium, facilitating purification of the protein. With the example of penicillin acylase the upper limit for a protein to become functionally displayed by phage fd has been further explored. Polyvalent display was not observed despite the use of genetic constructs designed for this aim. These results are discussed in relation to the pore size being formed by the g4p multimer.

The amino terminal half of the MS2-coded lysis protein is dispensable for function: implications for our understanding of coding region overlaps

We have asked whether genetic overlaps only evolve to provide extra coding capacity in genomes of restricted size. As a model system we have used the lysis gene of the RNA bacteriophage MS2. This gene overlaps with the distal part of the coat protein gene and with the proximal part of the replicase gene. Using recombinant DNA procedures we have determined whether either of the two overlaps codes for amino acids that are not essential for the function of the 75 amino acid long lysis protein. We find that the first 40 amino acids of the lysis protein are dispensable for function. Thus all of the genetic information essential to the synthesis of the active C‐terminal peptide lies within the overlap with the replicase gene, whereas all dispensable residues are encoded in the overlap with the coat protein gene and in the intercistronic region. This suggests that the overlap with the coat protein gene is not required for extra coding capacity but serves to regulate the expression of the lysis gene. Comparative sequence analysis is consistent with this idea.

Translational interference at overlapping reading frames in prokaryotic messenger RNA

In overlapping reading frames of prokaryotic mRNA, the ribosome-binding site (RBS) of the downstream cistron is part of the coding sequence of the upstream message. We have examined whether the rate of translation in Escherichia coli can be sufficiently high to preclude the use of an RBS in initiation of protein synthesis when it is part of an actively decoded reading frame. The two sets of gene overlap present in the RNA phage MS2 are used as a model system. We find that translation of an upstream cistron can fully block initiation of protein synthesis at the overlapping RBS of the downstream cistron. Nonsense mutations in the upstream gene restore the translation of the downstream gene.

In situ breakage of turnip yellow mosaic virus rna and in situ aggregation of the fragments

Abstract Turnip yellow mosaic virus (TYMV) has been treated at alkaline pH (10.5–11.0) and high ionic strength (1.0 M KCl) at 30° for 8 minutes. According to Kaper and Halperin (1965) such a treatment causes in situ breakage of the viral RNA chain, yielding fragments of uniform size (about 5 S). In the present paper it is demonstrated that in situ fragmentation is accompanied by in situ aggregation of the RNA fragments. The aggregate can be released as such from the capsid with phenol and sediments more rapidly and more uniformly than TYMV-RNA. It is assumed that each aggregate molecule is derived from one virus particle and has adopted a structure which is more compact than that of TYMV-RNA. Deaggregation, which is essentially irreversible outside of the capsid, can be accomplished by (a) heating at 55° for 2 minutes; (b) treatment with dime thylsulfoxide; (c) the successive removal of divalent and monovalent cations. Below limiting temperatures aggregates of intermediate sizes persist when the heating is prolonged. Possible models for the structure of the aggregate are discussed.