MvaL1 autoregulates the synthesis of the three ribosomal proteins encoded on the MvaL1 operon of the archaeon Methanococcus vannielii by inhibiting its own translation before or at the formation of the first peptide bond

The control of ribosomal protein synthesis has been investigated extensively in Eukarya and Bacteria. In Archaea, only the regulation of the MvaL1 operon (encoding ribosomal proteins MvaL1, MvaL10 and MvaL12) of Methanococcus vannielii has been studied in some detail. As in Escherichia coli , regulation takes place at the level of translation. MvaL1, the homologue of the regulatory protein L1 encoded by the L11 operon of E . coli , was shown to be an autoregulator of the MvaL1 operon. The regulatory MvaL1 binding site on the mRNA is located about 30 nucleotides downstream of the ATG start codon, a sequence that is not in direct contact with the initiating ribosome. Here, we demonstrate that autoregulation of MvaL1 occurs at or before the formation of the first peptide bond of MvaL1. Specific interaction of purified MvaL1 with both 23S RNA and its own mRNA is confirmed by filter binding studies. In vivo expression experiments reveal that translation of the distal MvaL10 and MvaL12 cistrons is coupled to that of the MvaL1 cistron. A mRNA secondary structure resembling a canonical L10 binding site and preliminary in vitro regulation experiments had suggested a co-regulatory function of MvaL10, the homologue of the regulatory protein L10 of the β-operon of E . coli . However, we show that MvaL10 does not have a regulatory function.     

An archaebacterial gene from Methanococcus vannielii encoding a protein homologous to the ribosomal protein L10 family

An open reading frame upstream of the Methanococcus vannielii L12 gene has been detected. The beginning of this open reading frame agrees with the N-terminal region of a protein (MvaL10) which has been isolated from the 50 S ribosomal subunit of M. vannielii and sequenced. The length of this gene is 1008 nucleotides, coding for 336 amino acids. Excellent sequence similarities were found to the L10-like ribosomal proteins from Halobacterium halobium and man. The N-terminal part of the MvaL10 protein shows significant sequence similarities to the E. coli L10 protein. MvaL10 is more than twice as long as E. coli L10 but is of length similar to those of the homologous halobacterial and human proteins. Interestingly, the C-terminal region of MvaL10 shows exceptionally high similarity to the C-terminal sequence of the MvaL12 protein. This is not the case for the E. coli proteins but was also observed for the human, Halobacterium and Sulfolobus proteins.     

Translational regulation by ribosomal protein S8 in Escherichia coli: structural homology between rRNA binding site and feedback target on mRNA.

It has been previously shown that ribosomal protein synthesis in Escherichia coli is regulated at the level of translation by certain key ribosomal proteins. In the spc operon, S8 regulates the expression of L5 and some of the subsequent genes, while the first two genes (L14 and L24) are regulated independently. We therefore determined the DNA sequence at the junction of the L24 and L5 genes, which corresponds to the putative feedback target for S8. We show that there is a striking homology between the structure of the mRNA for this region and the known binding site for S8 on 16S rRNA. These results support the theory that the regulation of ribosomal protein synthesis is based on competition between rRNA and mRNA for regulatory ribosomal proteins.     

Feedback regulation of ribosomal protein synthesis in E. coli: Localization of the mRNA target sites for repressor action of ribosomal protein L1

E. coli ribosomal protein L1 is a translational repressor of the synthesis in vitro of both proteins encoded in the L11 operon (L11 and L1). L1 is shown to act at a single target site within the first 160 bases of the bicistronic mRNA, near (or at) the translation initiation site of the L11 cistron. Synthesis of L1 apparently requires translation of the preceding L11 cistron, allowing regulation of the synthesis of both proteins from a single mRNA target site. This observation suggests a sequential translation mechanism that results in the equimolar synthesis rates of the two proteins observed in vivo. It was found that the presence of 23S rRNA, but not 16S rRNA, relieves translational inhibition by L1. L1 presumably recognizes structural features of the mRNA target site that are homologous to the L1-binding site of 23S rRNA. Although previous work indicated that translationally inhibited ribosomal protein mRNA is degraded in vivo, L1 repressor action in the present in vitro system was found not to involve mRNA degradation.     

Overexpression of the methanococcal ribosomal protein L12 in Escherichia coli and its incorporation into halobacterial 50 S subunits yielding active ribosomes

The gene for the ribosomal L12 protein from the archaebacterium Methanococcus vannielii was cloned into the expression vector pKK223-3. The protein was overexpressed and remained stable in Escherichia coli XL1 cells. Purification yielded a protein with the same amino acid composition and sequence as in Methanococcus but it was acetylated at the N terminus as in the case with the homologous protein of E. coli. The in vivo incorporation of the overexpressed protein into the E. coli ribosomes was not observed. The overexpressed M. vannielii protein MvaL12e was incorporated into halobacterial ribosomes, thereby displacing the corresponding halobacterial L12 protein. Intact 70 S ribosomes were reconstituted from halobacterial 50 S subunits carrying the MvaL12e protein. These ribosomes were as active as native halobacterial ribosomes in a poly(U) assay. On the other hand, our attempts to incorporate L12 proteins from Bacillus stearothermophilus and E. coli into halobacterial ribosomes were not successful. These results support the conclusion which is based on primary sequence and predicted secondary structure comparisons that there exist two distinct L12 protein families, namely the eubacterial L12 protein family and the eukaryotic/archaebacterial L12 protein family.     

Translational regulation of the L11 ribosomal protein operon of Escherichia coli: mutations that define the target site for repression by L1.

The L11 ribosomal protein operon of Escherichia coli contains the genes for L11 and L1 and is feedback regulated by the translational repressor L1. The mRNA target site for this repression is located close to the Shine-Dalgarno sequence for the first cistron, rp1K (L11). By use of a random mutagenesis procedure we have isolated and characterized a series of point mutations in the L11 leader mRNA which eliminate or greatly diminish the regulation by L1. The mutations define a region essential for translational regulation upstream of the L11 Shine-Dalgarno sequence and identify a region of structural homology with the L1 binding site on 23S rRNA. These results are also consistent with the previously proposed model for the secondary structure of the L11 leader mRNA.     

Mutational analysis of the L1 binding site of 23S rRNA in Escherichia coli.

The L11 ribosomal protein operon of Escherichia coli contains the genes for L11 and L1 and is feedback regulated by the translational repressor L1. Both the L1 binding site on 23S rRNA and the L1 repressor target site on L11 operon mRNA share similar proposed secondary structures and contain some primary sequence identity. Several site-directed mutations in the binding region of 23S rRNA were constructed and their effects on binding were examined. For in vitro analysis, a filter binding method was used. For in vivo analysis, a conditional expression system was used to overproduce a 23S rRNA fragment containing the L1 binding region, which leads to specific derepression of the synthesis of L11 and L1. Changes in the shared region of the 23S rRNA L1 binding site produced effects on L1 binding similar to those found previously in analysis of corresponding changes in the L11 operon mRNA target site. The results support the hypothesis that r-protein L1 interacts with both 23S rRNA and L11 operon mRNA by recognizing similar features on both RNAs.     

The structure of a ribosomal protein S8/spc operon mRNA complex

In bacteria, translation of all the ribosomal protein cistrons in the spc operon mRNA is repressed by the binding of the product of one of them, S8, to an internal sequence at the 5' end of the L5 cistron. The way in which the first two genes of the spc operon are regulated, retroregulation, is mechanistically distinct from translational repression by S8 of the genes from L5 onward. A 2.8 A resolution crystal structure has been obtained of Escherichia coli S8 bound to this site. Despite sequence differences, the structure of this complex is almost identical to that of the S8/helix 21 complex seen in the small ribosomal subunit, consistent with the hypothesis that autogenous regulation of ribosomal protein synthesis results from conformational similarities between mRNAs and rRNAs. S8 binding must repress the translation of its own mRNA by inhibiting the formation of a ribosomal initiation complex at the start of the L5 cistron.     

The rpsD gene, encoding ribosomal protein S4, is autogenously regulated in Bacillus subtilis.

Although the mechanisms for regulation of ribosomal protein gene expression have been established for gram-negative bacteria such as Escherichia coli, the regulation of these genes in gram-positive bacteria such as Bacillus subtilis has not yet been characterized. In this study, the B. subtilis rpsD gene, encoding ribosomal protein S4, was found to be subject to autogenous control. In E. coli, rpsD is located in the alpha operon, and S4 acts as the translational regulator for alpha operon expression, binding to a target site in the alpha operon mRNA. The target site for repression of B. subtilis rpsD by protein S4 was localized by deletion and oligonucleotide-directed mutagenesis to the leader region of the monocistronic rpsD gene. The B. subtilis rpsD leader exhibits little sequence homology to the E. coli alpha operon leader but may be able to form a pseudoknotlike structure similar to that found in E. coli.     

The cyanelle genome of Cyanophora paradoxa, unlike the chloroplast genome, codes for the ribosomal L3 protein.

We describe a 1132 bp sequence of the cyanelle genome of Cyanophora paradoxa containing the rpl3 gene. This gene, which is not chloroplast encoded in plants, is the first of a long cyanelle ribosomal operon whose organization resembles that of the S10 operon of E. coli. We have shown that the rpl3 gene is transcribed in cyanelles as a 7500 nucleotide precursor and that the 5'-end of the mRNA starts approximately 90 nucleotides upstream from the initiation codon. However, no typical procaryotic promoter could be found for this gene. We have detected, using anti E. coli L3 antibodies, the cyanelle L3 protein in cyanelle extracts and in E. coli cells transformed with the cyanelle rpl3 gene.