Origins of minigene-dependent growth inhibition in bacterial cells.

The expression of very short open reading frames in Escherichia coli can lead to the inhibition of translation and an arrest in cell growth. Inhibition occurs because peptidyl-tRNA hydrolase fails to recycle sufficiently rapidly peptidyl-tRNA released from ribosomes at the stop signal in competition with normal termination, causing starvation for essential species of tRNA. Previous studies have shown that the last sense codon, the strength of the Shine-Dalgarno sequence and the nature and context of the stop codon affect the toxicity associated with mini-gene expression. Here, several important parameters are studied as a function of the length of the mini-gene coding sequence. The rate of peptidyl-tRNA drop-off catalysed by translation factors decreases dramatically for peptides longer than a hexamer. The probability that ribosomes recycle without dissociation of the mini-gene mRNA varies strongly with the length of the coding sequence. The peptidyl-tRNA hydrolase rap mutant, unlike the wild-type enzyme, is highly sensitive to the length and sequence of the peptide. Together, these parameters explain the length dependence of mini-gene toxicity.

Shutdown in protein synthesis due to the expression of mini-genes in bacteria.

Mutants of Escherichia coli partially deficient in peptidyl-tRNA hydrolase are killed by the expression of certain very short open reading frames (mini-genes), encoded by the wild-type bar regions of phage lambda. According to the current hypothesis, protein synthesis is shut off, and the host cells die, after essential tRNA species become sequestered due to abnormal translation termination (drop-off) of mini-gene-encoded peptides as peptidyl-tRNA. Here we study variants of bar mini-genes, both in vivo and in vitro, in order to identify the structural elements that influence this inhibition of protein synthesis. Three parameters were measured during the expression of these variants: the rates of normal translation termination, peptidyl-tRNA dissociation from the ribosome and hydrolysis of peptidyl-tRNA by peptidyl-tRNA hydrolase were measured. Previous observations that RRF, EF-G and RF3 stimulated drop-off were confirmed and extended; stimulation by these factors can reach 30-fold. Both factor-stimulated and spontaneous drop-off depended on the nature of the stop signal. The degree of inhibition of cell growth following induction of mini-gene expression could be accounted for in terms of a toxicity index comprising the three parameters above. Inhibition was greatly reduced in cells lacking RF3. Mini-genes with more efficient Shine/Dalgarno sequences killed cells even with normal peptidyl-tRNA hydrolase activity. It is proposed that the retranslation by ribosomes of mini-gene transcripts with efficient ribosome binding (Shine/Dalgarno) sequences strongly contributes to the inhibitory effects of mini-gene expression on protein synthesis.

A direct estimation of the context effect on the efficiency of termination.

An in vitro assay in which terminating Escherichia coli ribosomes with different stop signals in the A-site compete for a limited amount of a release factor (RF1 or RF2) has been used to estimate the relative termination efficiencies at stop codons with different adjacent downstream nucleotides. The assay allows direct measurements of relative kcat/Km parameters for the productive association of release factors to ribosomes. The kcat/Km parameter is larger for UAA(U) than for UAA(C) programmed ribosomes and the difference in kcat/Km is much larger for RF2 (about 80%) than for RF1 (about 30%). These differences in the kcat/Km parameter are not affected by the addition of release factor RF3. The only discernible effect of RF3 is a considerable acceleration of RF1/2 recycling.The estimated kcat/Km parameters correlate well with the affinities of release factors for ribosomes programmed with different stop signals. These affinities were estimated from the extent of inhibition of ribosomal recycling by high concentrations of release factors in the absence of release factor RF3. The affinity for RF2 depends on the immediate downstream context of the stop codon in the translated mRNA and is about three times higher for UAA(U) than for UAA(C). The corresponding difference in affinities for RF1 is twofold. For all stop signals studied, the estimated affinity of RF2 for terminating ribosomes is much lower than that of RF1. It is also striking that the affinity of ribosomes for a chromosomally expressed RF2 is at least three times higher than for RF2 isolated from an overproducing E. coli strain.

tRNA-ribosome interactions.

Direct measurements of the rates of dissociation of dipeptidyl-tRNA from the ribosome show that hyperaccurate SmP and SmD ribosomes have unstable A-site binding of peptidyl-tRNA, while P-site binding is extremely stable in relation to the wild type. Error-prone Ram ribosomes, on the other hand, have stable A-site and unstable P-site binding of peptidyl-tRNA. At least for these mutant ribosomes, we conclude that stabilization of peptidyl-tRNA in one site destabilizes binding in the other. Elongation factor Tu (EF-Tu) undergoes a dramatic structural transition from its GDP-bound form to its active GTP-bound form, in which it binds aa-tRNA (aminoacyl-tRNA) in ternary complex. The effects of substitution mutations at three sites in domain I of EF-Tu, Gln124, Leu120, and Tyr160, all of which point into the domain I-domain III interface in both the GTP and GDP conformations of EF-Tu, were examined. Mutations at each position cause large reductions in aa-tRNA binding. An attractive possibility is that the mutations alter the domain I-domain III interface such that the switching of EF-Tu between different conformations is altered, decreasing the probability of aa-tRNA binding. We have previously found that two GTPs are hydrolyzed per peptide bond on EF-Tu, the implication being that two molecules of EF-Tu may interact on the ribosome to catalyze the binding of a single aa-tRNA to the A-site. More recently we found that ribosomes programmed with mRNA constructs other than poly(U), including the sequence AUGUUUACG, invariably use two GTPs per peptide bond in EF-Tu function. Other experiments measuring the protection of aa-tRNA from deacylation or from RNAse A attack show that protection requires two molecules of EF-Tu, suggesting an extended ternary complex. To remove remaining ambiguities in the interpretion of these experiments, we are making direct molecular weight determinations with neutron scattering and sedimentation-diffusion techniques.

Two GTPs are consumed on EF-Tu per peptide bond in poly(Phe) synthesis, in spite of switching stoichiometry of the EF-Tu.aminoacyl-tRNA complex with temperature.

Recent observations indicate that the stoichiometry for the complex between EF-Tu.GTP and aminoacyl-tRNA (aa-tRNA) changes with temperature. At 37 degrees C two EF-Tu.GTPs bind one aa-tRNA in an extended ternary complex, but at 0 degrees C the complex has 1:1 stoichiometry. However, the present experiments show that there are two GTPs hydrolyzed on EF-Tu per peptide bond in poly(Phe) synthesis at 37 degrees C as well as at 0 degrees C. This indicates two different pathways for the enzymatic binding of aa-tRNA to the A-site on the ribosome.

Plasmid stability in immobilized mixed cultures of recombinant Escherichia coli.

The growth behavior of a mixed culture of plasmid-free and plasmid-containing (YEp352) Escherichia coli HB101 cells in free suspension and immobilized conditions was studied experimentally. It was found that immobilization in calcium alginate beads delayed the reduction of the plasmid-containing fraction for a period of time inversely related to the total number of cells initially immobilized. A simple unstructured model that assumes compartmentalization of cells in the immobilization matrix at the beginning of growth gave a fit which was in good agreement with the data.