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The half-life of ribosomal protein operon L11 mRNA in vivo was measured during exponential growth by following the kinetics of incorporation of radioactive precursors into L11 mRNA transcribed from multi-copy plasmids. The degree of translational feedback regulation by L1, the L11 operon-specific translational repressor protein, was changed by altering the site on the "L11 mRNA" where L1 interacts. The half-life of the overproduced L11 mRNA increased by about fivefold when translational repression was abolished, while the half-life of mRNA from the spc ribosomal protein operon, which is not translationally regulated by L1, stayed constant. Furthermore, the half-life of L11 operon mRNA carrying an additional mutation in the ribosome binding site that abolishes translation remains short. This indicates that the change in half-life observed during increased gene dosage is due to translational repression by L1 and is probably a consequence of L1 blocking translation of L11 mRNA and not due to some nucleolytic activity mediated by L1.
J Mol Biol 1986 Apr 05
PMID:Changes in the half-life of ribosomal protein messenger RNA caused by translational repression. 242 54

Transcripts from the rplKAJL-rpoBC ribosomal protein-RNA polymerase gene cluster have been quantified and their ends mapped using RNA-DNA hybridization, sucrose density-gradient sedimentation, Northern hybridization and S1 nuclease protection. The results indicate that the most abundant transcript is the 2600 nucleotide tetracistronic L11-L1-L10-L12 mRNA initiated at the upstream major PL11 promoter and terminated at the transcription attenuator in the L12-beta intergenic space. Somewhat less abundant 1300 nucleotide L11-L1 and L10-L12 bicistronic transcripts were observed. The 3' ends of the L11-L1 transcripts were heterogeneous; most of the ends were localized to three sites within a 110 base-pair region in the L1-L10 intergenic space. This intergenic space encodes also the major PL10 promoter and the mRNA binding site for the L10 translational control protein. Two 5' ends were observed for L10-L12 bicistronic mRNA, one at the PL10 promoter and the other 150 nucleotides further downstream in a region in which promoter activity has not been detected. It is suggested that this second downstream 5' end is generated by processing of the transcripts initiated at the major PL10 promoter. No transcript initiation in the L10-L12 intergenic space was detected. About 80% of the transcripts reading through the L12 gene were terminated in the vicinity of the transcription attenuator that is responsible for the reduction in the expression of the downstream RNA polymerase genes. Transcripts reading through the attenuator were partially processed by RNase III within a potential hairpin structure in the RNA transcript. Processing appears to produce 3' and 5' transcript end sites separated by about ten nucleotides. No other major 5' ends were observed in the L12-beta intergenic space. These results indicate that the two major promoters, PL11 and PL10, are both utilized to drive the interrelated transcriptional expression of this ribosomal protein-RNA polymerase gene cluster.
J Mol Biol 1987 Apr 20
PMID:Transcription products from the rplKAJL-rpoBC gene cluster. 244 6

A method has been found for reassembling fragment 1 of Escherichia coli 5S RNA from mixtures containing strand III (bases 69-87) and the complex consisting of strand II (bases 89-120) and strand IV (bases 1-11). The reassembled molecule is identical with unreconstituted fragment 1. With this technique, fragment 1 molecules have been constructed 15N-labeled either in strand III or in the strand II-strand IV complex. Spectroscopic data obtained with these partially labeled molecules show that the terminal helix of 5S RNA includes the GU and GC base pairs at positions 9 and 10 which the standard model for 5S secondary structure predicts [see Delihas, N., Anderson, J., & Singhal, R. P. (1984) Prog. Nucleic Acid Res. Mol. Biol. 31, 161-190] but that these base pairs are unstable both in the fragment and in native 5S RNA. The data also assign three resonances to the helix V region of the molecule (bases 70-77 and 99-106). None of these resonances has a "normal" chemical shift even though two of them correspond to AU or GU base pairs in the standard model. The implications of these findings for our understanding of the structure of 5S RNA and its complex with ribosomal protein L25 are discussed.
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PMID:Secondary structure of 5S RNA: NMR experiments on RNA molecules partially labeled with nitrogen-15. 244 55

The secondary structure of the autoregulatory mRNA binding site of Escherichia coli ribosomal protein L1 has been studied using enzymatic methods. The control region of the E. coli L11 operon was cloned into a vector under control of the Salmonella phage SP6 promoter, and RNA transcribed using SP6 RNA polymerase. The secondary structure of this RNA was probed using structure-specific nucleases, and by comparison of the data with computer predictions of RNA folding, secondary structural features were deduced. The proposed model is consistent with elements of some previously proposed models, but differs in other features. Finally, secondary structure information was obtained from two mutant mRNAs and the structural features correlated with observed phenotypes of the mutants.
Mol Gen Genet 1987 Nov
PMID:Secondary structure of the autoregulatory mRNA binding site of ribosomal protein L1. 244 90

Analysis of the antigenic structure of the E. coli ribosomal protein S1 was undertaken using a set of 13 monoclonal antibodies (MAbs) directed against the isolated S1. The location of the epitopes was mapped using a series of large fragments and truncated forms of S1. Most of the epitopes were localized in the C-terminal half of the molecule, while only one antibody bound to the N-terminal region. Two MAbs were able to bind to more than one region of S1, suggesting the presence of repeated epitopes related to internal sequence homologies. Six distinct antigenic domains were identified by competitive binding assays. Competition between some antibodies suggested that the C-terminal region of S1 might be in spatial proximity with the N-terminal domain in the tertiary structure of the protein. The binding of a few MAbs induced conformational changes in the protein which resulted in the complete inhibition of antibody binding at non-adjacent sites. All the MAbs reacted with the isolated form of S1 or with the protein bound to the small ribosomal subunit. This indicated that the same epitopes were expressed in the two forms of the antigen and that they were accessible to antibody binding when S1 was part of the ribosomal subunit.
Mol Immunol 1987 Dec
PMID:Antigenic regions of ribosomal protein S1 as defined by monoclonal antibodies. 244 12

The trmD operon of Escherichia coli encodes the ribosomal proteins S16 and L19, the tRNA(m1G37)methyltransferase and a 21,000 Mr protein of unknown function. Here we demonstrate that, in contrast to the expression of other ribosomal protein operons, the amount of trmD operon mRNA and the rate of synthesis of the proteins encoded by the operon respond to increased gene dosage. The steady-state level of the mRNA was about 18 times higher, and the relative rate of synthesis of the ribosomal proteins S16 and L19, the tRNA(m1G37)methyltransferase and the 21,000 Mr protein was 15, 9, 25 and 23 times higher, respectively, in plasmid-containing cells than in plasmid-free cells. Overproduced tRNA(m1G37)methyltransferase and 21,000 Mr protein were as stable as E. coli total protein, whereas the two ribosomal proteins were degraded to a large extent. The steady-state amount of S16 and L19 in the plasmid-containing cells exceeded that in plasmid-free cells by threefold and twofold, respectively. No significant effect on the synthesis of the trmD operon proteins from the chromosomally located genes was observed when parts of the operon were expressed on different plasmids. Taken together, these results suggest that the expression of the trmD operon is not subject to transcriptional or translational feedback regulation, and demonstrate that not all ribosomal protein operons are regulated in the same manner. We propose that ribosomal protein operons that do not encode proteins that bind directly to rRNA are not under autogenous control. Metabolic regulation at the transcriptional level and protein degradation are plausible mechanisms for the control of expression of such operons.
J Mol Biol 1988 Sep 05
PMID:Non-autogenous control of ribosomal protein synthesis from the trmD operon in Escherichia coli. 246 Jun 31

The spc ribosomal protein operon of Escherichia coli is feedback-regulated by ribosomal protein S8, a translational repressor. We have analyzed the region of the spc mRNA that is responsible for this regulation. First, we have established that the S8 target site on the mRNA is near the translation start site of the third gene encoding ribosomal protein L5 in the operon. This was done by constructing hybrid plasmids carrying spc operon ribosomal protein genes under lac transcriptional control, as well as their deletion derivatives, and carrying out both in vivo and in vitro protein synthesis experiments. Next, the secondary structure of this region was studied by analyzing 5' end-labeled RNA synthesized from the phage SP6 promoter using structure-specific nucleases. A secondary structure model consistent with the results was deduced with the aid of a computer prediction of RNA folding. In addition, we cloned and sequenced the corresponding region from Salmonella typhimurium, Proteus vulgaris and Serratia marcescens and found five "compensating" substitutions that support some of the deduced helical structures of mRNA. None of the base changes was inconsistent with the deduced secondary structure model. Finally, site-directed mutagenesis experiments have identified bases important for regulation, including two base-paired sites representing each of two helical regions. This has led to the conclusion that some specific nucleotide residues located between these two helical regions are directly involved in S8 recognition, and that the function of the two helical regions is to maintain the proper orientation of these nucleotide residues. Comparison of the structure of the S8 target site on the spc mRNA with the known S8 binding site on rRNA has revealed a striking similarity in both primary and secondary structures. In particular, primary sequences of rRNA conserved among distantly related bacterial species in this region is found to be identical with the sequences at the corresponding positions in mRNA. These results suggest that the same structural features of the S8 repressor protein are involved in the interaction with both 16 S rRNA and the mRNA target site.
J Mol Biol 1988 Nov 20
PMID:Translational regulation of the spc operon in Escherichia coli. Identification and structural analysis of the target site for S8 repressor protein. 246 92

The trmD operon is a four-cistron operon in which the first and fourth genes encode ribosomal proteins S16 (rpsP) and L19 (rplS), respectively. The second gene encodes a 21,000 Mr polypeptide of unknown function and the third gene (trmD) encodes the enzyme tRNA(m1G37)methyltransferase, which catalyzes the formation of 1-methylguanosine (m1G) next to the 3' end of the anticodon (position 37) of some tRNAs in Escherichia coli. Here we show under all regulatory conditions studied, transcription initiates at one unique site, and the entire operon is transcribed into one polycistronic mRNA. Between the promoter and the first gene, rpsP, an attenuator-like structure is found (delta G = -18 kcal; 1 cal = 4.184 J), followed by four uridine residues. This structure is functional in vitro, and terminates more than two-thirds of the transcripts. The different parts of the trmD operon mRNA decay at a uniform rate. The stability of the trmD mRNA is not reduced with decreasing growth rate, which is in contrast to what has been found for other ribosomal protein mRNAs. Furthermore, earlier experiments have shown the existence of differential expression as well as non-co-ordinate regulation within the operon. Our results are consistent with the regulation of the trmD operon being due to some mechanism(s) operating at the post-transcriptional level, and do not involve differential degradation of different mRNA segments, internal promoters or internal terminators.
J Mol Biol 1989 Aug 20
PMID:Differentially expressed trmD ribosomal protein operon of Escherichia coli is transcribed as a single polycistronic mRNA species. 247 11

The sequences of Saccharomyces carlsbergensis ribosomal protein (r-protein) SL25* and its equivalents from Candida utilis (CL25), Escherichia coli (EL23), Bacillus stearothermophilus (BL23), Mycoplasma capricolum (ML23), Marchantia polymorpha chloroplasts (McpL23), and Nicotiana tabacum chloroplasts (NcpL23) were examined using a computer program that evaluates the extent of sequence similarity by calculating correlation coefficients for each pair of residues in two proteins from a number of physical properties of individual amino acids. Comparison matrices demonstrate that the prokaryotic sequences (including McpL23 and NcpL23) can be aligned unambiguously by introducing small internal deletions/insertions at three specific positions. A similar comparison brought to light a clear evolutionary relationship between the prokaryotic and the yeast proteins despite the fact that visual inspection of these sequences revealed only limited similarity. The alignment deduced from this comparison shows the two yeast r-proteins to have acquired a long (50-60 amino acids) N-terminal extension as well as a 13-amino acid-long deletion near the C-terminus. The significance of these findings in terms of the evolution of r-proteins in general and the biological function of various parts of the SL25 protein in particular is discussed.
J Mol Evol 1989 May
PMID:Structural comparison of 26S rRNA-binding ribosomal protein L25 from two different yeast strains and the equivalent proteins from three eubacteria and two chloroplasts. 250 3

The trmD operon of Escherichia coli consists of the genes for the ribosomal protein (r-protein) S16, a 21 kDa protein (21K) of unknown function, the tRNA(m1G37)methyltransferase (TrmD), and r-protein L19, in this order. Previously we have shown that the steady-state amount of the two r-proteins exceeds that of the 21K and TrmD proteins 12- and 40-fold, respectively, and that this differential expression is solely explained by translational regulation. Here we have constructed translational gene fusions of the trmD operon and lacZ. The expression of a lacZ fusion containing the first 18 codons of the 21K protein gene is 15-fold higher than the expression of fusions containing 49 or 72 codons of the gene. This suggests that sequences between the 18th and the 49th codon may act as a negative element controlling the expression of the 21K protein gene. Evidence is presented which demonstrates that this regulation is achieved by reducing the efficiency of translation.
Mol Gen Genet 1989 Nov
PMID:A regulatory element within a gene of a ribosomal protein operon of Escherichia coli negatively controls expression by decreasing the translational efficiency. 251 39

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