Escherichia coli tryptophan operon directs the in vivo synthesis of a leader peptide

Low molecular weight proteins: a challenge for post-genomic research

The EcoGene project involves the examination of Escherichia coli K-12 DNA sequences and accompanying annotation in the public databases in order to refine the representation and prediction of the entire set of E. coli K-12 chromosomally encoded protein sequences. The results of this ongoing effort have been deposited in the SWISSPROT protein sequence database as sequencing of the E. coli genome has progressed to completion in recent years. Through this continuing research, we have discovered that the prediction of low molecular weight (small) proteins, arbitrarily defined as protein sequences < or = 150 amino acids (aa) in length, is problematic and requires special attention. We describe the small protein subset of EcoGene and the approach used to derive this subset from the complete E. coli genome sequence and database annotations. These E. coli proteins have helped to identify new small genes in other organisms and to identify conserved residues (motifs) using database searches and multiple alignments. Two thirds of the E. coli small proteins have not been characterized experimentally. The careful application of computer and laboratory methods to the analysis of small proteins is needed for accurate prediction, verification and characterization. The problem of accurate protein sequence identification is not limited to small proteins or to E. coli; these problems are encountered to varying degrees throughout all sequence databases.

Energy-dependent degradation of lambda O protein in Escherichia coli

Protein O of bacteriophage lambda is a short-lived protein which has a key role in the replication of the phage DNA in Escherichia coli. Here we present evidence that lambda O degradation is energy dependent: it is impaired by cyanide and alpha-methylglucoside, both of which inhibit cellular energy metabolism. Removal of these inhibitors restored the degradation of lambda O. Our experiments suggest that limited amounts of cellular energy are sufficient to support lambda O degradation. In addition, degradation of lambda O protein is prevented by a mutation in the E. coli clpP gene, but not by a mutation in the clpA gene. These results suggest that the ClpP protease is involved in the energy-dependent degradation of the lambda O protein.

Frameshifting in the expression of the Escherichia coli trpR gene

The trpR gene of Escherichia coli carries an open reading frame that encodes the trp repressor, 108 amino acids long. Here we show that translation of an additional (+1) reading frame of trpR occurs both in vivo and in vitro. This results in the synthesis of a stable +1 frame polypeptide. Using site-specific mutagenesis, immunological techniques and amino acid sequencing we have found that the N-terminus of the +1 frame product and that of the known 0 frame product are identical but that their C-termini differ. Our results are discussed in relation to the role of natural frameshifting as a regulatory mechanism of gene expression in general, and with respect to tryptophan biosynthesis in particular.

An additional function for bacteriophage lambda rex: the rexB product prevents degradation of the lambda O protein

The rex operon of bacteriophage lambda excludes the development of several unrelated bacteriophages. Here we present an additional lambda rexB function: it prevents degradation of the short-lived protein lambda O known to be involved in lambda DNA replication. We have shown that it is the product of rexB that is responsible for the stabilization of lambda O: when a nonsense mutation is present in rexB, lambda O protein is labile; suppression of the mutation by the corresponding nonsense suppressor causes partial restabilization of lambda O. lambda rexB also stabilizes lambda O in trans. We discuss our results in relation to the function of rexB in lambda DNA replication and its role in the protein degradation pathways of bacteriophage lambda.

Dependence of expression of an inducible Staphylococcus aureus cat gene on the translation of its leader sequence

The gene for chloramphenicol (Cm) acetyltransferase (CAT) carried by the staphylococcal plasmid pUB112, whose expression can be stimulated by Cm, is preceded by a regulatory region containing two control elements. One of these consists of a Shine-Dalgarno (SD) sequence followed by an open reading frame coding for a leader peptide of nine amino acids. Previous work has shown that the SD sequence is essential for inducibility of Cm resistance by the antibiotic (Brückner and Matzura 1985). Here we demonstrate that fusion of the leader peptide coding sequence to a truncated 'lacZ gene results in synthesis of a leader peptide-beta-galactosidase fusion protein. Introduction of an ochre nonsense codon into the reading frame of the leader peptide sequence leads to considerable reduction of the basal expression and loss of inducibility of the cat gene. These results reveal that synthesis of the leader peptide is required for the basal and inducible expression of the cat gene and support the model of translational attenuation for its regulation.

Specificity of the attenuation response of the threonine operon of Escherichia coli is determined by the threonine and isoleucine codons in the leader transcript

Expression of the threonine (thr) operon enzymes of Escherichia coli is regulated by an attenuation mechanism. The regulatory portion of the operon contains a region coding for a leader peptide that contains consecutive threonine and isoleucine codons. It is thought that translation of the leader peptide controls the frequency of transcription termination at the attenuator site. Using oligonucleotide-directed site-specific mutagenesis we have altered the putative control codons of the leader peptide coding region. In two of the mutants the threonine and isoleucine codons were changed to produce peptides containing histidine and tyrosine codons. Both mutants showed loss of regulation by threonine and isoleucine. A hisT mutation, which leads to an undermodification of tRNA(His), increased thr operon expression in the mutants threefold but did not affect expression of the wild-type thr operon. Two other mutants were constructed that contained two histidine codons early in the leader peptide. Expression in both of these mutants was unaltered by the presence of the hisT allele or by the addition of threonine and isoleucine to the growth medium. In addition, a wild-type strain containing a temperature-sensitive threonyl-tRNA synthetase mutation showed increased thr operon expression at the non-permissive temperature, whereas none of the mutants showed any change. Taken together these data indicate that the specificity of the attenuation response is effected by specific control codons within the thr leader peptide coding region. We have also directly demonstrated thr leader peptide synthesis in vitro using a plasmid encoding the wild-type thr leader region to direct the synthesis of a peptide of the appropriate molecular weight when labeled with [3H]threonine but not with [3H]histidine or [3H]tyrosine. Conversely, when extracts were incubated with templates containing the mutated DNAs, peptides were labeled that showed patterns consistent with the expected amino acid compositions. These data indicate that the thr leader RNA is translated into the predicted leader peptide.