Model for signal sequence recognition from amino-acid sequence of 54K subunit of signal recognition particle.

Protein targeting to the endoplasmic reticulum in mammalian cells is catalysed by signal recognition particle (SRP). Cross-linking experiments have shown that the subunit of relative molecular mass 54,000 (Mr 54K; SRP54) interacts directly with signal sequences as they emerge from the ribosome. Here we present the sequence of a complementary DNA clone of SRP54 which predicts a protein that contains a putative GTP-binding domain and an unusually methionine-rich domain. The properties of this latter domain suggest that it contains the signal sequence binding site. A previously uncharacterized Escherichia coli protein has strong homology to both domains. Closely homologous GTP-binding domains are also found in the alpha-subunit of the SRP receptor (SR alpha, docking protein) in the endoplasmic reticulum membrane and in a second E. coli protein, ftsY, which resembles SR alpha. Recent work has shown that SR alpha is a GTP-binding protein and that GTP is required for the release of SRP from the signal sequence and the ribosome on targeting to the endoplasmic reticulum membrane. We propose that SRP54 and SR alpha use GTP in sequential steps of the targeting reaction and that essential features of such a pathway are conserved from bacteria to mammals.

Accuracy of in vivo aminoacylation requires proper balance of tRNA and aminoacyl-tRNA synthetase.

The fidelity of protein biosynthesis in any cell rests on the accuracy of aminoacylation of tRNA. The exquisite specificity of this reaction is critically dependent on the correct recognition of tRNA by aminoacyl-tRNA synthetases. It is shown here that the relative concentrations of a tRNA and its cognate aminoacyl-tRNA synthetase are normally well balanced and crucial for maintenance of accurate aminoacylation. When Escherichia coli Gln-tRNA synthetase is overproduced in vivo, it incorrectly acylates the supF amber suppressor tRNA(Tyr) with Gln. This effect is abolished when the intracellular concentration of the cognate tRNA(Gln2) is also elevate. These data indicate that the presence of aminoacyl-tRNA synthetase and the cognate tRNAs in complexed form, which requires the proper balance of the two macromolecules, is critical in maintaining the fidelity of protein biosynthesis. Thus, limits exist on the relative levels of tRNAs and aminoacyl-tRNA synthetases within a cell.

Isolation and characterization of a cDNA clone encoding the 19 kDa protein of signal recognition particle (SRP): expression and binding to 7SL RNA.

Signal recognition particle (SRP) consists of a 7SL RNA molecule and 6 protein subunits. We have isolated and characterized cDNA clones from human liver which encode the 19kDa protein subunit (SRP19). This subunit binds to the RNA directly and mediates binding of a second polypeptide, the 54kDa subunit which is involved in signal sequence recognition. Amino acid sequences deduced from the human cDNA sequence were identical to amino acid sequences of tryptic peptides from canine pancreatic SRP19. In vitro transcription and translation of the human cDNA resulted in a protein product the same size as canine SRP19 which could be immunoprecipitated by an antiserum raised against canine SRP19. SRP19 synthesized in a cell-free system specifically bound to 7SL RNA. The sequence of SRP19 is discussed with respect to its binding to 7SL RNA.

Misaminoacylation by glutaminyl-tRNA synthetase: relaxed specificity in wild-type and mutant enzymes.

Escherichia coli glutaminyl-tRNA synthetase (GlnRS) (EC 6.1.1.18) is a monomeric polypeptide of 553 amino acids. Its amino acid sequence and its gene (glnS) sequence are known. A structural gene mutation, glnS7, codes for a mischarging GlnRS, which acylates some noncognate tRNA species (e.g., su+3 tRNATyr) with glutamine. The mutant enzyme was shown to catalyze in vitro the acylation of glutamine to su+3 tRNATyr, but not to wild-type tRNATyr. The mutation responsible produces an amino acid change in the amino-terminal half of the enzyme. Unexpectedly, overproduction of wild-type GlnRS also leads to in vivo mischarging of su+3 tRNATyr. In vitro and in vivo studies have not revealed evidence for an attenuation or autogenous regulation mechanism for GlnRS, but have implicated transcriptional and translational control in the expression of this enzyme.

Transfer RNA mischarging mediated by a mutant Escherichia coli glutaminyl-tRNA synthetase.

We have isolated mutations in the Escherichia coli glnS gene encoding glutaminyl-tRNA synthetase [GlnS; L-glutamine:tRNAGln ligase (AMP-forming), EC 6.1.1.18] that give rise to gene products with altered specificity for tRNA and are designated "mischarging" enzymes. These were produced by nitrosoguanine mutagenesis of the glnS gene carried on a transducing phage (lambda pglnS+). We then selected for mischarging of su+3 tRNATyr with glutamine by requiring suppression of a glutamine-requiring beta-galactosidase amber mutation (lacZ1000). Three independently isolated mutants (glnS7, glnS8, and glnS9) were characterized by genetic and biochemical means. The enzymes encoded by glnS7, glnS8, and glnS9 appear to be highly selective for su+3 tRNATyr, because in vivo mischarging of other amber suppressor tRNAs was not detected. The GlnS mutants described here retain their capacity to correctly aminoacylate tRNAGln. All three independently isolated mutant genes encode proteins with isoelectric points that differ from those of the wild-type enzyme but are identical to each other. This suggests that only a single site in the enzyme structure is altered to give the observed mischarging properties. In vitro aminoacylation reactions with purified GlnS7 protein show that this enzyme can also mischarge some tRNA species lacking the amber anticodon. This is an example of mischarging phenotype conferred by a mutation in an aminoacyl-tRNA synthetase gene; the results are discussed in the context of earlier genetic studies with mutant tRNAs.

Escherichia coli glutaminyl-tRNA synthetase. II. Characterization of the glnS gene product.

Glutaminyl-tRNA synthetase has been purified by a simple, two-column procedure from an Escherichia coli K12 strain carrying the glnS structural gene on plasmid pBR322. The primary sequence of this enzyme as derived from the DNA sequence (see accompanying paper) has been confirmed. Manual Edman degradation was used to identify the NH2-terminal sequence of the protein. Oligopeptides scattered throughout the primary sequence of glutaminyl-tRNA synthetase were sequenced by the gas chromatographic-mass spectrometric method and matched to the theoretical peptides derived from the translated DNA sequence. The expected carboxyl terminus at position 550 was verified by carboxypeptidase B digestion. The primary sequence of glutaminyl-tRNA synthetase contains no extensive sequence repeats. A search was made for sequence homologies between this enzyme and the few other aminoacyl-tRNA synthetases for which primary sequences are available. A single homologous region is shared by at least three of the synthetases examined here.

Expression of the chloroplast ribosomal RNA genes of Euglena gracilis during chloroplast development.

The cellular content and transcription program of the chloroplast ribosomal RNA genes of Euglena gracilis Z have been determined during the light-induced development of chloroplasts by hybridization of total cell DNA or RNA to purified 3H-labeled chloroplast ribosomal DNA ([3H]ctrDNA). Pancreatic DNase activated, partially purified chloroplast rDNA was enzymatically labeled in vitro by E. coli DNA polymerase I with [3H]TTP as a substrate. The [3H] DNA was denatured and hybridized with a vast excess of purified chloroplast 16 and 23S rRNA. The rRNA-[3H]ct rCNA hybrid was isolated by chromatography on hydroxylapatite. The [3H]ct rDNA was purified and characterized by the kinetics of its renaturation with chloroplast DNA and rRNA, and by the thermal stability of [3H]DNA-DNA and [3H]DNA-RNA hybrids. [3H]ct rDNA was hybridized in trace amounts to cellular RNA or DNA isolated from Euglena cells 0,4,8,12,24,48, and 72 h after the onset of chloroplast development. From a comparison of the kinetics of hybridization with hybridization of standards of known kinetic complexity quantitative estimates of the cellular rRNA and rDNA gene content were made. Chloroplast rRNA increases from 2 to 26% of the cellular RNA during development, while the percentage of cellular DNA represented by ct rDNA increases two- to threefold. Correcting for the change in cellular RNA and DNA content during development, the number of copies of the rRNA gene increases less than twofold, while the number of copies of rRNA per cell increases sixfold. The results are consistent with either a transcriptional activation of the ribosomal genes or an increased rRNA stability during developmental.

Cellular content of chloroplast DNA and chloroplast ribosomal RNA genes in Euglena gracilis during chloroplast development.

The cellular content of chloroplast DNA in Euglena gracilis has been quantitatively determined. DNA was extracted from Euglena cells at various stages of chloroplast development and renatured in the presence of trace amounts of 3H-labeled chloroplast DNA. From the kinetics of renaturation of the 3H-labeled chloroplast DNA, compared with the kinetics of renaturation of excess nonradioactive chloroplast DNA, the fraction of cellular DNA represented by chloroplast DNA was calculated. The content of chloroplast DNA was found to increase from 4.9 to 14.6% of cellular DNA during light-induced chloroplast development. Correcting for the change in DNA mass per cell, the number of copies of chloroplast DNA is found to vary from 1400 to 2900 per cell. During this developmental transition, the cellular content of the chloroplast ribosomal RNA genes varies from 1900 to 5200 copies per cell. The ratio of the number of copies of rRNA genes to chloroplast genomes per cell remains in the range of 1-2 throughout chloroplast development, ruling out selective amplification of chloroplast rRNA genes as a means of regulation of rRNA gene expression. Direct measurement of the number of rRNA cistrons per 9.2 X 10(7) dalton genome yields a value of 1 or 2.