Transcription of the S10 ribosomal protein operon is regulated by an attenuator in the leader

Coupled Transcription-Translation in Prokaryotes: An Old Couple With New Surprises

Coupled transcription-translation (CTT) is a hallmark of prokaryotic gene expression. CTT occurs when ribosomes associate with and initiate translation of mRNAs whose transcription has not yet concluded, therefore forming "RNAP.mRNA.ribosome" complexes. CTT is a well-documented phenomenon that is involved in important gene regulation processes, such as attenuation and operon polarity. Despite the progress in our understanding of the cellular signals that coordinate CTT, certain aspects of its molecular architecture remain controversial. Additionally, new information on the spatial segregation between the transcriptional and the translational machineries in certain species, and on the capability of certain mRNAs to localize translation-independently, questions the unanimous occurrence of CTT. Furthermore, studies where transcription and translation were artificially uncoupled showed that transcription elongation can proceed in a translation-independent manner. Here, we review studies supporting the occurrence of CTT and findings questioning its extent, as well as discuss mechanisms that may explain both coupling and uncoupling, e.g., chromosome relocation and the involvement of cis- or trans-acting elements, such as small RNAs and RNA-binding proteins. These mechanisms impact RNA localization, stability, and translation. Understanding the two options by which genes can be expressed and their consequences should shed light on a new layer of control of bacterial transcripts fate.

Posttranscriptional Regulation of tnaA by Protein-RNA Interaction Mediated by Ribosomal Protein L4 in Escherichia coli

Some ribosomal proteins have extraribosomal functions in addition to ribosome translation function. The extraribosomal functions of several r-proteins control operon expression by binding to own-operon transcripts. Previously, we discovered a posttranscriptional, RNase E-dependent regulatory role for r-protein L4 in the stabilization of stress-responsive transcripts. Here, we found an additional extraribosomal function for L4 in regulating the tna operon by L4-intergenic spacer mRNA interactions. L4 binds to the transcribed spacer RNA between tnaC and tnaA and alters the structural conformation of the spacer RNA, thereby reducing the translation of TnaA. Our study establishes a previously unknown L4-mediated mechanism for regulating gene expression, suggesting that bacterial cells have multiple strategies for controlling levels of tryptophanase in response to varied cell growth conditions.

Escherichia coli ribosomal protein (r-protein) L4 has extraribosomal biological functions. Previously, we described L4 as inhibiting RNase E activity through protein-protein interactions. Here, we report that from stabilized transcripts regulated by L4-RNase E, mRNA levels of tnaA (encoding tryptophanase from the tnaCAB operon) increased upon ectopic L4 expression, whereas TnaA protein levels decreased. However, at nonpermissive temperatures (to inactivate RNase E), tnaA mRNA and protein levels both increased in an rne temperature-sensitive [rne(Ts)] mutant strain. Thus, L4 protein fine-tunes TnaA protein levels independently of its inhibition of RNase E. We demonstrate that ectopically expressed L4 binds with transcribed spacer RNA between tnaC and tnaA and downregulates TnaA translation. We found that deletion of the 5′ or 3′ half of the spacer compared to the wild type resulted in a similar reduction in TnaA translation in the presence of L4. In vitro binding of L4 to the tnaC-tnaA transcribed spacer RNA results in changes to its secondary structure. We reveal that during early stationary-phase bacterial growth, steady-state levels of tnaA mRNA increased but TnaA protein levels decreased. We further confirm that endogenous L4 binds to tnaC-tnaA transcribed spacer RNA in cells at early stationary phase. Our results reveal the novel function of L4 in fine-tuning TnaA protein levels during cell growth and demonstrate that r-protein L4 acts as a translation regulator outside the ribosome and its own operon.

IMPORTANCE Some ribosomal proteins have extraribosomal functions in addition to ribosome translation function. The extraribosomal functions of several r-proteins control operon expression by binding to own-operon transcripts. Previously, we discovered a posttranscriptional, RNase E-dependent regulatory role for r-protein L4 in the stabilization of stress-responsive transcripts. Here, we found an additional extraribosomal function for L4 in regulating the tna operon by L4-intergenic spacer mRNA interactions. L4 binds to the transcribed spacer RNA between tnaC and tnaA and alters the structural conformation of the spacer RNA, thereby reducing the translation of TnaA. Our study establishes a previously unknown L4-mediated mechanism for regulating gene expression, suggesting that bacterial cells have multiple strategies for controlling levels of tryptophanase in response to varied cell growth conditions.

Ribosomal protein L4 of Lactobacillus rhamnosus LRB alters resistance to macrolides and other antibiotics

Lactobacillus rhamnosus is an important lactic acid bacterium that is predominantly used as a probiotic supplement. This bacterium secretes immunomodulatory and antibacterial peptides that are necessary for the probiotic trait. This organism also occupies diverse ecological niches, such as gastrointestinal tracts and the oral cavity. Several studies have shown that L. rhamnosus is prone to spontaneous genome rearrangement irrespective of the ecological origins. We previously characterized an oral isolate of L. rhamnosus, LRB, which is genetically closely related to the widely used probiotic strain L. rhamnosus LGG. In this study, we isolated a nontargeted mutant that was particularly sensitive to acid stress. Using next generation sequencing, we further mapped the putative mutations in the genome and found that the mutant had acquired a deletion of 75 base pairs in the rplD gene that encodes the large ribosomal subunit L4. The mutant had a growth defect at 37°C and at ambient temperature. Further antibiotic sensitivity analyses indicated that the mutant is relatively more resistant to erythromycin and chloramphenicol; two antibiotics that target the 50S subunit. In contrast, the mutant was more sensitive to tetracycline, which targets the 30S subunit. Thus, it appears that nontargeted mutations could significantly alter the antibiotic resistance profile of L. rhamnosus. Our study raises concern that probiotic use of L. rhamnosus should be carefully monitored to avoid unintended consequences.

Identification of essential proteins based on ranking edge-weights in protein-protein interaction networks

Essential proteins are those that are indispensable to cellular survival and development. Existing methods for essential protein identification generally rely on knock-out experiments and/or the relative density of their interactions (edges) with other proteins in a Protein-Protein Interaction (PPI) network. Here, we present a computational method, called EW, to first rank protein-protein interactions in terms of their Edge Weights, and then identify sub-PPI-networks consisting of only the highly-ranked edges and predict their proteins as essential proteins. We have applied this method to publicly-available PPI data on Saccharomyces cerevisiae (Yeast) and Escherichia coli (E. coli) for essential protein identification, and demonstrated that EW achieves better performance than the state-of-the-art methods in terms of the precision-recall and Jackknife measures. The highly-ranked protein-protein interactions by our prediction tend to be biologically significant in both the Yeast and E. coli PPI networks. Further analyses on systematically perturbed Yeast and E. coli PPI networks through randomly deleting edges demonstrate that the proposed method is robust and the top-ranked edges tend to be more associated with known essential proteins than the lowly-ranked edges.

Most RNAs regulating ribosomal protein biosynthesis in Escherichia coli are narrowly distributed to Gammaproteobacteria

In Escherichia coli, 12 distinct RNA structures within the transcripts encoding ribosomal proteins interact with specific ribosomal proteins to allow autogenous regulation of expression from large multi-gene operons, thus coordinating ribosomal protein biosynthesis across multiple operons. However, these RNA structures are typically not represented in the RNA Families Database or annotated in genomic sequences databases, and their phylogenetic distribution is largely unknown. To investigate the extent to which these RNA structures are conserved across eubacterial phyla, we created multiple sequence alignments representing 10 of these messenger RNA (mRNA) structures in E. coli. We find that while three RNA structures are widely distributed across many phyla of bacteria, seven of the RNAs are narrowly distributed to a few orders of Gammaproteobacteria. To experimentally validate our computational predictions, we biochemically confirmed dual L1-binding sites identified in many Firmicute species. This work reveals that RNA-based regulation of ribosomal protein biosynthesis is used in nearly all eubacterial phyla, but the specific RNA structures that regulate ribosomal protein biosynthesis in E. coli are narrowly distributed. These results highlight the limits of our knowledge regarding ribosomal protein biosynthesis regulation outside of E. coli, and the potential for alternative RNA structures responsible for regulating ribosomal proteins in other eubacteria.

Detection of small RNAs in Bordetella pertussis and identification of a novel repeated genetic element

Background

Small bacterial RNAs (sRNAs) have been shown to participate in the regulation of gene expression and have been identified in numerous prokaryotic species. Some of them are involved in the regulation of virulence in pathogenic bacteria. So far, little is known about sRNAs in Bordetella, and only very few sRNAs have been identified in the genome of Bordetella pertussis, the causative agent of whooping cough.

Results

An in silico approach was used to predict sRNAs genes in intergenic regions of the B. pertussis genome. The genome sequences of B. pertussis, Bordetella parapertussis, Bordetella bronchiseptica and Bordetella avium were compared using a Blast, and significant hits were analyzed using RNAz. Twenty-three candidate regions were obtained, including regions encoding the already documented 6S RNA, and the GCVT and FMN riboswitches. The existence of sRNAs was verified by Northern blot analyses, and transcripts were detected for 13 out of the 20 additional candidates. These new sRNAs were named Bordetella pertussis RNAs, bpr. The expression of 4 of them differed between the early, exponential and late growth phases, and one of them, bprJ2, was found to be under the control of BvgA/BvgS two-component regulatory system of Bordetella virulence. A phylogenetic study of the bprJ sequence revealed a novel, so far undocumented repeat of ~90 bp, found in numerous copies in the Bordetella genomes and in that of other Betaproteobacteria. This repeat exhibits certain features of mobile elements.

Conclusion

We shown here that B. pertussis, like other pathogens, expresses sRNAs, and that the expression of one of them is controlled by the BvgA/BvgS system, similarly to most virulence genes, suggesting that it is involved in virulence of B. pertussis.

Direct regulation of Escherichia coli ribosomal protein promoters by the transcription factors ppGpp and DksA

We show here that the promoters for many of the Escherichia coli ribosomal protein operons are regulated directly by two transcription factors, the small RNA polymerase-binding protein DksA and the nutritional stress-induced nucleotide ppGpp. ppGpp and DksA work together to inhibit transcription initiation from ribosomal protein promoters in vitro and in vivo. The degree of promoter regulation by ppGpp/DksA varies among the r-protein promoters, but some are inhibited almost as much as rRNA promoters. Thus, many r-protein operons are regulated at the level of transcription in addition to their control by the classic translational feedback systems discovered ~30 y ago. We conclude that direct control of r-protein promoters and rRNA promoters by the same signal, ppGpp/DksA, makes a major contribution to the balanced and coordinated synthesis rates of all of the ribosomal components.

Identification of candidate structured RNAs in the marine organism 'Candidatus Pelagibacter ubique'

Background

Metagenomic sequence data are proving to be a vast resource for the discovery of biological components. Yet analysis of this data to identify functional RNAs lags behind efforts to characterize protein diversity. The genome of 'Candidatus Pelagibacter ubique' HTCC 1062 is the closest match for approximately 20% of marine metagenomic sequence reads. It is also small, contains little non-coding DNA, and has strikingly low GC content.

Results

To aid the discovery of RNA motifs within the marine metagenome we exploited the genomic properties of 'Cand. P. ubique' by targeting our search to long intergenic regions (IGRs) with relatively high GC content. Analysis of known RNAs (rRNA, tRNA, riboswitches etc.) shows that structured RNAs are significantly enriched in such IGRs. To identify additional candidate structured RNAs, we examined other IGRs with similar characteristics from 'Cand. P. ubique' using comparative genomics approaches in conjunction with marine metagenomic data. Employing this strategy, we discovered four candidate structured RNAs including a new riboswitch class as well as three additional likely cis-regulatory elements that precede genes encoding ribosomal proteins S2 and S12, and the cytoplasmic protein component of the signal recognition particle. We also describe four additional potential RNA motifs with few or no examples occurring outside the metagenomic data.

Conclusion

This work begins the process of identifying functional RNA motifs present in the metagenomic data and illustrates how existing completed genomes may be used to aid in this task.

Structural and functional analysis of the E. coli NusB-S10 transcription antitermination complex

Protein S10 is a component of the 30S ribosomal subunit and participates together with NusB protein in processive transcription antitermination. The molecular mechanisms by which S10 can act as a translation or a transcription factor are not understood. We used complementation assays and recombineering to delineate regions of S10 dispensable for antitermination, and determined the crystal structure of a transcriptionally active NusB-S10 complex. In this complex, S10 adopts the same fold as in the 30S subunit and is blocked from simultaneous association with the ribosome. Mass spectrometric mapping of UV-induced crosslinks revealed that the NusB-S10 complex presents an intermolecular, composite, and contiguous binding surface for RNAs containing BoxA antitermination signals. Furthermore, S10 overproduction complemented a nusB null phenotype. These data demonstrate that S10 and NusB together form a BoxA-binding module, that NusB facilitates entry of S10 into the transcription machinery, and that S10 represents a central hub in processive antitermination.

The extended loops of ribosomal proteins L4 and L22 are not required for ribosome assembly or L4-mediated autogenous control

Ribosomal proteins L4 and L22 both have a globular domain that sits on the surface of the large ribosomal subunit and an extended loop that penetrates its core. The tips of both loops contribute to the lining of the peptide exit tunnel and have been implicated in a gating mechanism that might regulate the exit of nascent peptides. Also, the extensions of L4 and L22 contact multiple domains of 23S rRNA, suggesting they might facilitate rRNA folding during ribosome assembly. To learn more about the roles of these extensions, we constructed derivatives of both proteins that lack most of their extended loops. Our analysis of ribosomes carrying L4 or L22 deletion proteins did not detect any significant difference in their sedimentation property or polysome distribution. Also, the role of L4 in autogenous control was not affected. We conclude that these extensions are not required for ribosome assembly or for L4-mediated autogenous control of the S10 operon.

RNA-structural mimicry in Escherichia coli ribosomal protein L4-dependent regulation of the S10 operon

Ribosomal protein L4 regulates the 11-gene S10 operon in Escherichia coli by acting, in concert with transcription factor NusA, to cause premature transcription termination at a Rho-independent termination site in the leader sequence. This process presumably involves L4 interaction with the leader mRNA. Here, we report direct, specific, and independent binding of ribosomal protein L4 to the S10 mRNA leader in vitro. Most of the binding energy is contributed by a small hairpin structure within the leader region, but a 64-nucleotide sequence is required for the bona fide interaction. Binding to the S10 leader mRNA is competed by the 23 S rRNA L4 binding site. Although the secondary structures of the mRNA and rRNA binding sites appear different, phosphorothioate footprinting of the L4-RNA complexes reveals close structural similarity in three dimensions. Mutational analysis of the mRNA binding site is compatible with the structural model. In vitro binding of L4 induces structural changes of the S10 leader RNA, providing a first clue for how protein L4 may provoke transcription termination.

Comparative anatomy of a regulatory ribosomal protein

Ribosomal protein L4 is a crucial folding mediator and an important architectural component of the large ribosomal subunit. Furthermore, Escherichia coli L4 produced in excess of its rRNA binding sites downregulates the transcription and translation of its own S10 operon, encoding 11 ribosomal proteins. Genetic experiments and the crystal structure of Thermotoga maritima L4 had implicated separable regions on L4 in ribosome association and expression control while RNA competition experiments and the regulatory capacity of heterologous L4 had suggested an overlap of the protein sequences involved in the two functions. We report herein that contrary to other foreign bacterial L4 proteins, L4 from T. maritima only weakly controlled expression of the S10 operon in E. coli. Also, wildtype T. maritima L4 was more weakly associated with E. coli ribosomes than with the E. coli analog. Rational mutageneses were performed to try to increase the regulatory competence of T. maritima L4. The ribosome incorporation of the mutant proteins was also investigated. Two different deletions removing T. maritima-specific sequences had little effects on regulation although one did improve ribosome association. Interestingly, a set of multiple mutations, which rendered the region around helices alpha4 and alpha5 in T. maritima L4 more E. coli-like, had no influence on the incorporation of the protein into the large ribosomal subunit but considerably improved its regulatory potential. Therefore, the area around helices alpha4 and alpha5, which is critical for the initial folding steps of the large subunit, is also a central element of autogenous control, presumably by contacting the S10 mRNA leader. Ribosome association is compounded at later stages of assembly by additional rRNA contacts through L4 areas which do not participate in regulation. Similarly, sequences outside the alpha4/alpha5 region aid expression control.

Complete nucleotide sequence of the S10-spc operon of phytoplasma: gene organization and genetic code resemble those of Bacillus subtilis

An 11.4-kbp region of genomic DNA containing the complete S10-spc operon was constructed by an integrative mapping technique with eight plasmid vectors carrying ribosomal protein sequences from onion yellows phytoplasma. Southern hybridization analysis indicated that phytoplasmal S10-spc is a single-copy operon. This is the first complete S10-spc operon of a phytoplasma to be reported, although only a part of six serial genes of the S10 operon is reported previously. The operon has a context of 5'-rps10, rpl3, rpl4, rpl23, rpl2, rps19, rpl22, rps3, rpl16, rpl29, rps17, rpl14, rpl24, rpl5, rps14, rps8, rpl6, rpl18, rps5, rpl30, rpl15, SecY-3', and is composed of 21 ribosomal protein subunit genes and a SecY protein translocase subunit gene. Resembling Bacillus, this operon contains an rpl30 gene that other mollicutes (Mycoplasma genitalium, M. pneumoniae, and M. pulmonis) lack. A phylogenetic tree based on the rps3 sequence showed that phytoplasmas are phylogenetically closer to acholeplasmas and bacillus than to mycoplasmas. In the S10-spc operon, translation may start from either a GTG codon or an ATG codon, and stop at a TGA codon, as has been reported for acholeplasmas and bacillus. However, in mycoplasmas, GTG was found as a start codon, and TGA was found not as a stop codon, but instead as a tryptophan codon. These data derived from the gene organization, and the genetic code deviation support the hypothesis that phytoplasmal genes resemble those of acholeplasmas and Bacillus more than those of other mollicutes.

Organellar RNA polymerases of higher plants

The nuclear genome of the model plant Arabidopsis thaliana contains a small gene family consisting of three genes encoding RNA polymerases of the single-subunit bacteriophage type. There is evidence that similar gene families also exist in other plants. Two of these RNA polymerases are putative mitochondrial enzymes, whereas the third one may represent the nuclear-encoded RNA polymerase (NEP) active in plastids. In addition, plastid genes are transcribed from another, entirely different multisubunit eubacterial-type RNA polymerase, the core subunits of which are encoded by plastid genes [plastid-encoded RNA polymerase (PEP)]. This core enzyme is complemented by one of several nuclear-encoded sigma-like factors. The development of photosynthetically active chloroplasts requires both PEP and NEP. Most NEP promoters show certain similarities to mitochondrial promoters in that they include the sequence motif 5'-YRTA-3' near the transcription initiation site. PEP promoters are similar to bacterial promoters of the -10/-35 sigma 70 type.

The nuclear RPL4 gene encodes a chloroplast protein that co-purifies with the T7-like transcription complex as well as plastid ribosomes

We have cloned and sequenced the cDNA and the gene coding for plastid ribosomal protein L4 (RPL4) from two higher plant species, spinach and Arabidopsis thaliana. Ribosomal protein L4 is one of the ribosomal proteins for which extraribosomal functions in transcriptional regulation has been demonstrated in prokaryotes. Sequence comparison of the two plant cDNAs and genes shows that the RPL4 gene has acquired a remarkable 3' extension during evolutionary transfer to the nuclear genome. This extension harbors an intron and codes for a glutamic and aspartic acid-rich amino acid sequence that resembles highly acidic C-terminal tails of some transcription factors. Co-purification of ribosomal protein L4 with plastid RNA polymerase and transcription factor CDF2 using different purification protocols as well as the surprising amino acid sequence of the L4 protein make it a likely candidate to play a role in plastid transcriptional regulation.

Analysis of the Bacillus subtilis S10 ribosomal protein gene cluster identifies two promoters that may be responsible for transcription of the entire 15-kilobase S10-spc-alpha cluster

We have sequenced a previously uncharacterized region of the Bacillus subtilis S10 ribosomal protein gene cluster. The new segment includes genes for S10, L3, L4, L23, L2, S19, L22, S3, and part of L16. These B. subtilis genes map in the same order as the genes in the Escherichia coli S10 ribosomal protein operon. Two potential promoter sequences were identified, one approximately 200 bases and the other approximately 140 bases upstream of the S10 gene. The activities of the two promoters were demonstrated by primer extension analysis, in vitro transcription experiments, and in vivo promoter fusion plasmid studies. In agreement with previous reports, our Northern analysis of exponentially growing cells failed to identify terminators or other active promoters within the S10-spc-alpha region. Our observations suggest that the two S10 promoters reported here are responsible for transcribing a 15-kb-long transcript for all of the genes in the B. subtilis S10, spc, and alpha clusters.

Isolation and preliminary characterization of the Streptococcus mutans rpsJ gene

We previously reported that four putative open reading frames were identified in the regions flanking the Streptococcus mutans GS-5 fructosyltransferase gene. For one of these, ORF 4, only a small region had been isolated and the first 30 nucleotides had been sequenced. In order to determine whether this open reading frame is part of an expressed gene, we isolated a DNA fragment containing intact ORF 4 and a portion of the downstream ORF 5 by inverse polymerase chain reaction. A comparison of the deduced amino acid sequences of ORF 4 and ORF 5 with other proteins revealed that the ORF 4 and ORF 5 gene products were highly homologous to ribosomal proteins S10 and L3, respectively, of several bacteria. To identify the precise transcriptional start site for the ORF 4 gene, primer extension analysis was carried out. The results indicated initiation at a G residue with corresponding -10 and -35 regions homologous to the Escherichia coli consensus promoter sequences. These results indicate that the sequences of ORF 4 and ORF 5 are consistent with the structures of ribosomal proteins S10 and L3, respectively, and are present in a ribosomal protein operon.

A hairpin structure upstream of the terminator hairpin required for ribosomal protein L4-mediated attenuation control of the S10 operon of Escherichia coli

Ribosomal protein L4 of Escherichia coli regulates transcription of the 11-gene S1O operon by promoting premature termination of transcription (attenuation) at a specific site within the 172-base untranslated leader. We have analyzed the roles of various domains of the leader RNA in this transcription control. Our results indicate that the first 60 bases of the leader, forming the three proximal hairpin structures, are not essential for in vivo L4-mediated attenuation control. However, a deletion removing the fourth hairpin, which is immediately upstream of the terminator hairpin, eliminates L4's effect on transcription. Base changes disrupting complementarity in the 6-bp stem of this hairpin also abolish L4 control, but compensatory base changes that restore complementarity also restore L4's effect. In vitro transcription studies confirm that this hairpin structure is necessary for L4's role in stimulating transcription termination by RNA polymerase.

Regulation of the Escherichia coli S10 ribosomal protein operon by heterologous L4 ribosomal proteins

We have cloned the L4 ribosomal protein genes from Morganella morganii and Haemophilus influenza. The sequences of these genes were compared with published sequences for Escherichia coli, Yersinia pseudotuberculosis, and Bacillus stearothermophilus. All five of these L4 genes were expressed in E. coli and shown to function as repressors of both transcription and translation of the E. coli S10 operon. Possible implications for regulation of r-protein synthesis in species other E. coli are discussed.

Post-transcriptional regulation of the str operon in Escherichia coli. Ribosomal protein S7 inhibits coupled translation of S7 but not its independent translation

The str operon of Escherichia coli consists of the genes for ribosomal proteins S12 (rpsL) and S7 (rpsG) and elongation factors G (fusA) and Tu (tufA). Previous studies have shown that S7 is a translational feedback repressor and inhibits the synthesis of itself and of elongation factor G. We have now shown that induction of S7 synthesis from the S7 gene fused to the arabinose promoter on a plasmid also leads to inhibition of the synthesis of S12 from the chromosomal S12 gene, and that this regulation takes place using the same target site as that used for distal gene regulation, i.e. S7 retroregulates S12. We have then demonstrated that S7 synthesis is mostly translationally coupled with the translation of the preceding S12 gene. Using a rpsG'-'lacZ fusion gene as a reporter for S7 synthesis, we found that abolishing S12 translation by a mutational alteration of the AUG start codon of the S12 gene leads to about tenfold reduction of S7 synthesis without significantly affecting its rate of transcription. Deletion of the proximal portion of the S12 gene or a premature termination of S12 translation by an amber mutation at the 26th codon also led to a large reduction of S7 synthesis. Unexpectedly, we have discovered that overproduction of S7 in trans from a plasmid leads to repression of the rpsG'-'lacZ fusion gene when the fusion gene is preceded by the intact S12 gene, but not when the S12 gene carried the above-mentioned mutations that abolish S12 translation. Thus, a novel feature of this regulatory system is that translation of S7 achieved by independent initiation is not inhibited by S7 in vivo, whereas translation of S7 achieved by translational coupling is sensitive to S7 repression. These observations also suggest that the coupled S7 translation is probably achieved by the use of ribosomal subunits employed for translation of the upstream S12 gene.

Autogenous translational regulation of the ribosomal MvaL1 operon in the archaebacterium Methanococcus vannielii

The mechanisms for regulation of ribosomal gene expression have been characterized in eukaryotes and eubacteria, but not yet in archaebacteria. We have studied the regulation of the synthesis of ribosomal proteins MvaL1, MvaL10, and MvaL12, encoded by the MvaL1 operon of Methanococcus vannielii, a methanogenic archaebacterium. MvaL1, the homolog of the regulatory protein L1 encoded by the L11 operon of Escherichia coli, was shown to be an autoregulator of the MvaL1 operon. As in E. coli, regulation takes place at the level of translation. The target site for repression by MvaL1 was localized by site-directed mutagenesis to a region within the coding sequence of the MvaL1 gene commencing about 30 bases downstream of the ATG initiation codon. The MvaL1 binding site on the mRNA exhibits similarity in both primary sequence and secondary structure to the L1 regulatory target site of E. coli and to the putative binding site for MvaL1 on the 23S rRNA. In contrast to other regulatory systems, the putative MvaL1 binding site is located in a sequence of the mRNA which is not in direct contact with the ribosome as part of the initiation complex. Furthermore, the untranslated leader sequence is not involved in the regulation. Therefore, we suggest that a novel mechanism of translational feedback regulation exists in M. vannielii.

Domain I of 23S rRNA competes with a paused transcription complex for ribosomal protein L4 of Escherichia coli

Ribosomal protein L4 of Escherichia coli regulates expression of its own eleven gene S10 operon both by inhibiting translation and by stimulating premature termination of transcription. Both regulatory processes presumably involve L4 recognition of the S10 leader RNA. To help define L4's regulatory target, we have investigated the protein's cognate target on 23S rRNA. Binding of L4 to various fragments of the 23S rRNA was monitored by determining their ability to sequester L4 in an in vitro transcription system and thereby eliminate the protein's effect on transcription. Using this approach we identified a region of about 110 bases within domain I of 23S rRNA which binds L4. A two base deletion within this region, close to the base to which L4 has been cross-linked in intact 50S subunits, eliminates L4 binding. These results also confirm the prediction of the autogenous control model, that L4 bound to its target on rRNA is not active in regulating transcription of the S10 operon.

Primary structures of ribosomal proteins L3 and L4 from Bacillus stearothermophilus

Ribosomal proteins L3 and L4 were purified to homogeneity from total protein isolated from the 50S subunit of Bacillus stearothermophilus by reversed-phase high-performance liquid chromatography (RP-HPLC). Amino acid sequences of both proteins were determined by automated N-terminal sequence analysis and sequencing of internal peptides. Using oligonucleotides deduced from the N-terminal region of protein L3 as hybridization probes, a DNA fragment coding for proteins L3, L4 and the N-terminal part of protein L23 has been identified, cloned and sequenced. The organization of the genes is identical to that found in the S10 operon of Escherichia coli. Comparison of the sequences of proteins L3 and L4 with those of other organisms revealed that all proteins of the L3 family are highly conserved. On the other hand, the archaebacterial L4 proteins show no significant sequence similarity to the E. coli L4 protein whereas the L4 protein of B. stearothermophilus is significantly similar to all of the L4 proteins and thus justifies the membership of all the L4 proteins in one protein family. The results are discussed with respect to the phylogenetic relationship between eubacteria, archaebacteria and eukaryotes and possible functional domains of proteins L3 and L4.

Premature termination of in vivo transcription of a gene encoding a branched-chain amino acid transport protein in Escherichia coli

Previous studies have suggested that control of expression of genes of the LIV-I permease system for the high-affinity transport of branched-chain amino acids in Escherichia coli involves modulation in the frequency of mRNA elongation. Mutation of the Rho transcription termination factor and shortages of charged leucyl-tRNA have been shown to alter LIV-I transport activity. Rho-dependent transcription termination regulated by shortages of charged leucyl-tRNA at sites preceding structural genes has been proposed to account for their role in regulation of LIV-I transport. Transcription of the livJ-binding protein gene, encoding one of the periplasmic components of the LIV-I system, was analyzed in vivo with strains which lack repression of the LIV-I genes and harbor a temperature-sensitive allele for either leucyl-tRNA synthetase or Rho factor. Analysis of mRNA synthesis by DNA-RNA hybridization in the various mutant strains indicated that both shortages of leucyl-tRNA caused by inactivation of the temperature-sensitive leucyl-tRNA synthetase and inactivation of the Rho factor were associated with increased synthesis of livJ mRNA. Nuclease protection and gel electrophoresis studies detected prematurely terminated transcripts corresponding in size to the leader region of livJ mRNA. Accumulations of these short transcripts were suppressed in strains harboring temperature-sensitive alleles for either leucyl-tRNA synthetase or Rho factor. These results provide support for the hypothesis that expression of livJ involves Rho-dependent transcription termination in which antitermination is associated with the intracellular availability of aminoacyl leucyl-tRNA.

Ribosomal protein L4 of Escherichia coli: in vitro analysis of L4-mediated attenuation control

Ribosomal protein L4 of Escherichia coli functions not only as a component of the ribosome but also as a regulatory factor inhibiting both transcription and translation of its own operon, the 11 gene S10 operon. L4-mediated transcription control results in premature termination of transcription within the 172 base S10 operon leader. This attenuation control can be reproduced in a purified transcription system containing RNA polymerase, but depends on the addition of transcription factor NusA. The NusA stimulation saturates at about 2-4 copies per RNA polymerase. The L4 effect plateaus at about 4 copies per RNA polymerase. The specific recognition sites on 23S rRNA and in the S10 leader for L4 binding are not yet known. However, we can demonstrate that a fragment of 23S rRNA containing the proximal 840 bases can eliminate in vitro L4-stimulated attenuation, and hence, contains the information sufficient for L4 binding to 23S rRNA.

Mapping of two promoters for elongation factor Tu within the structural gene for elongation factor G

The str operon of Escherichia coli contains the genes for ribosomal proteins S7 and S12 as well as elongation factors G and Tu (EF-G, EF-Tu). We have previously reported that there is a secondary promoter for expression of EF-Tu mapping within the upstream fus gene encoding EF-G (Zengel, J.M. and Lindahl, L. (1982) Mol. Gen. Genet. 185, 487-492) and have identified several potential promoter sequences within fus (Zengel, J.M., Archer, R.H. and Lindahl, L. (1984) Nucleic Acids Res. 12, 2181-2192). We have now further characterized this promoter activity. Measurements of transcription rates from various regions of the str operon in cells carrying the fus gene and the beginning of the tufA gene on a high copy number plasmid confirmed that transcription was initiated within a 600 bp EcoRI fragment in the distal portion of the fus gene. Furthermore, T1 nuclease mapping studies identified two 5' ends within this region, one about 400 bases upstream of tufA, the other about 270 bases upstream, suggesting that there are two tufA promoters within the fus gene. Both of these promoters are active in the intact chromosomal str operon.

Conditional expression of RPA190, the gene encoding the largest subunit of yeast RNA polymerase I: effects of decreased rRNA synthesis on ribosomal protein synthesis

The synthesis of ribosomal proteins (r proteins) under the conditions of greatly reduced RNA synthesis were studied by using a strain of the yeast Saccharomyces cerevisiae in which the production of the largest subunit (RPA190) of RNA polymerase I was controlled by the galactose promoter. Although growth on galactose medium was normal, the strain was unable to sustain growth when shifted to glucose medium. This growth defect was shown to be due to a preferential decrease in RNA synthesis caused by deprivation of RNA polymerase I. Under these conditions, the accumulation of r proteins decreased to match the rRNA synthesis rate. When proteins were pulse-labeled for short periods, no or only a weak decrease was observed in the differential synthesis rate of several r proteins (L5, L39, L29 and/or L28, L27 and/or S21) relative to those of control cells synthesizing RPA190 from the normal promoter. Degradation of these r proteins synthesized in excess was observed during subsequent chase periods. Analysis of the amounts of mRNAs for L3 and L29 and their locations in polysomes also suggested that the synthesis of these proteins relative to other cellular proteins were comparable to those observed in control cells. However, Northern analysis of several r-protein mRNAs revealed that the unspliced precursor mRNA for r-protein L32 accumulated when rRNA synthesis rates were decreased. This result supports the feedback regulation model in which excess L32 protein inhibits the splicing of its own precursor mRNA, as proposed by previous workers (M. D. Dabeva, M. A. Post-Beittenmiller, and J. R. Warner, Proc. Natl. Acad. Sci. USA 83:5854-5857, 1986).

Escherichia coli ribosomal protein L4 stimulates transcription termination at a specific site in the leader of the S10 operon independent of L4-mediated inhibition of translation

Transcription of the 11-gene S10 operon of Escherichia coli is inhibited by excess ribosomal protein L4, the product of the third gene of the operon. Previous studies suggested that L4 regulates transcription by modulating the level of readthrough at an attenuator in the S10 leader. To understand better the molecular details of the transcriptional regulation, we have determined the site of L4-induced termination of transcription using a method that allows us to map the 5' and 3' ends of newly synthesized RNA. Our results indicate that L4 stimulates termination about 140 bases from the transcription start site. Thus, the termination point is more than 30 bases upstream from the most proximal structural gene of the S10 operon, and coincides with a string of U residues on the descending side of a terminator-like hairpin structure. Since L4 is also known to inhibit translation of the S10 operon, we have analyzed the role of translation control in the protein's regulation of transcription by deleting sequences downstream from the termination site, including bases involved in translation initiation of the proximal structural gene. We find that the first 150 bases of the S10 leader contain the information sufficient for L4-mediated attenuation control and, therefore, that L4 regulates transcription by a mechanisms that is independent of the protein's inhibition of translation.

Conditional expression of RPA190, the gene encoding the largest subunit of yeast RNA polymerase I: effects of decreased rRNA synthesis on ribosomal protein synthesis

The synthesis of ribosomal proteins (r proteins) under the conditions of greatly reduced RNA synthesis were studied by using a strain of the yeast Saccharomyces cerevisiae in which the production of the largest subunit (RPA190) of RNA polymerase I was controlled by the galactose promoter. Although growth on galactose medium was normal, the strain was unable to sustain growth when shifted to glucose medium. This growth defect was shown to be due to a preferential decrease in RNA synthesis caused by deprivation of RNA polymerase I. Under these conditions, the accumulation of r proteins decreased to match the rRNA synthesis rate. When proteins were pulse-labeled for short periods, no or only a weak decrease was observed in the differential synthesis rate of several r proteins (L5, L39, L29 and/or L28, L27 and/or S21) relative to those of control cells synthesizing RPA190 from the normal promoter. Degradation of these r proteins synthesized in excess was observed during subsequent chase periods. Analysis of the amounts of mRNAs for L3 and L29 and their locations in polysomes also suggested that the synthesis of these proteins relative to other cellular proteins were comparable to those observed in control cells. However, Northern analysis of several r-protein mRNAs revealed that the unspliced precursor mRNA for r-protein L32 accumulated when rRNA synthesis rates were decreased. This result supports the feedback regulation model in which excess L32 protein inhibits the splicing of its own precursor mRNA, as proposed by previous workers (M. D. Dabeva, M. A. Post-Beittenmiller, and J. R. Warner, Proc. Natl. Acad. Sci. USA 83:5854-5857, 1986).

Ribosomal protein L4 stimulates in vitro termination of transcription at a NusA-dependent terminator in the S10 operon leader

The 11-gene S10 ribosomal protein operon of Escherichia coli is under the autogenous control of L4, the product of the third gene of the operon. Ribosomal protein L4 inhibits both transcription and translation of the operon. Our in vivo studies indicated that L4 regulates transcription by causing premature termination within the untranslated S10 operon leader. We have now used an in vitro transcription system to study the effect of purified L4 on expression of the S10 operon. We find that the cell-free system reproduces the in vivo observations. Namely, in the absence of L4, most of the RNA polymerases read through the termination site in the S10 attenuator; the addition of L4 results in increased termination at this site. However, RNA polymerase does not terminate at the S10 attenuator, with or without L4, unless an additional factor, protein NusA, is added to the transcription reaction. These results suggest that the attenuator in the S10 operon is a NusA-dependent terminator whose efficiency is regulated by ribosomal protein L4.

Autogenous control is not sufficient to ensure steady-state growth rate-dependent regulation of the S10 ribosomal protein operon of Escherichia coli

The regulation of the S10 ribosomal protein operon of Escherichia coli was studied by using a lambda prophage containing the beginning of the S10 operon (including the promoter, leader, and first one and one-half structural genes) fused to lacZ. The synthesis of the lacZ fusion protein encoded by the phage showed the expected inhibition during oversynthesis of ribosomal protein L4, the autogenous regulatory protein of the S10 operon. Moreover, the fusion gene responded to a nutritional shift-up in the same way that genuine ribosomal protein genes did. However, the gene did not exhibit the expected growth rate-dependent regulation during steady-state growth. Thus, the genetic information carried on the prophage is sufficient for L4-mediated autogenous control and a normal nutritional shift-up response but is not sufficient for steady-state growth rate-dependent control. These results suggest that, at least for the 11-gene S10 ribosomal protein operon, additional regulatory processes are required to coordinate the synthesis of ribosomal proteins with cell growth rate and, furthermore, that sequences downstream of the proximal one and one-half genes of the operon are involved in this control.

Escherichia coli ribosomal protein L10 is rapidly degraded when synthesized in excess of ribosomal protein L7/L12

In Escherichia coli the genes encoding ribosomal proteins L10 and L7/12, rplJ and rplL, respectively, are cotranscribed and subject to translational coupling. Synthesis of both proteins is coordinately regulated at the translational level by binding of L10 or a complex of L10 and L7/L12 to a single target in the mRNA leader region upstream of rplJ. Unexpectedly, small deletions that inactivated the ribosome-binding site of the rplL gene carried on multicopy plasmids exerted a negative effect on expression of the upstream rplJ gene. This effect could be overcome by overproduction of L7/L12 in trans from another plasmid. This apparent stimulation resulted from stabilization of the overproduced L10 protein by L7/L12, presumably because free L10, in contrast to L10 complexed with L7/L12, is subject to rapid proteolytic decay. The contribution of this decay mechanism to the regulation of the rplJL operon is evaluated.

Differentially expressed trmD ribosomal protein operon of Escherichia coli is transcribed as a single polycistronic mRNA species

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.

Translational coupling of the two proximal genes in the S10 ribosomal protein operon of Escherichia coli

We have examined the translational coupling between the first two genes in the S10 ribosomal protein operon. We isolated mutations blocking the translation of the first gene of the operon, coding for S10, and monitored their effects on translation of the downstream gene, coding for L3. All of the mutations inhibiting S10 synthesis also affected the synthesis of L3. However, these experiments were complicated by decreased mRNA synthesis resulting from transcription polarity, which we could only partially eliminate by using a rho-100 strain. To completely eliminate the problem of transcription polarity and obtain a more accurate measurement of the coupling, we replaced the natural S10 promoter with a promoter used by the bacteriophage T7 RNA polymerase. As expected, the T7 RNA polymerase was not subject to transcription polarity. Using this system, we were able to show that a complete abolishment of S10 translation resulted in an 80% inhibition of L3 synthesis. Other experiments show that the synthesis of L3 goes up as a function of increasing S10 synthesis, but the translational coupling does not assure strictly proportional output from the two genes.

Effects of induction of rRNA overproduction on ribosomal protein synthesis and ribosome subunit assembly in Escherichia coli

Overproduction of rRNA was artificially induced in Escherichia coli cells to test whether the synthesis of ribosomal protein (r-protein) is normally repressed by feedback regulation. When rRNA was overproduced more than twofold from a hybrid plasmid carrying the rrnB operon fused to the lambda pL promoter (pL-rrnB), synthesis of individual r-proteins increased by an average of about 60%. This demonstrates that the synthesis of r-proteins is repressed under normal conditions. The increase of r-protein production, however, for unknown reasons, was not as great as the increase in rRNA synthesis and resulted in an imbalance between the amounts of rRNA and r-protein synthesis. Therefore, only a small (less than 20%) increase in the synthesis of complete 30S and 50S ribosome subunits was detected, and a considerable fraction of the excess rRNA was degraded. Lack of complete cooperativity in the assembly of ribosome subunits in vivo is discussed as a possible explanation for the absence of a large stimulation of ribosome synthesis observed under these conditions. In addition to the induction of intact rRNA overproduction from the pL-rrnB operon, the effects of unbalanced overproduction of each of the two large rRNAs, 16S rRNA and 23S rRNA, on r-protein synthesis were examined using pL-rrnB derivatives carrying a large deletion in either the 23S rRNA gene or the 16S rRNA gene. Operon-specific derepression after 23S or 16S rRNA overproduction correlated with the overproduction of rRNA containing the target site for the operon-specific repressor r-protein. These results are discussed to explain the apparent coupling of the assembly of one ribosomal subunit with that of the other which was observed in earlier studies on conditionally lethal mutants with defects in ribosome assembly.

Feedback regulation of the spc operon in Escherichia coli: translational coupling and mRNA processing

The spc operon of Escherichia coli encodes 10 ribosomal proteins in the order L14, L24, L5, S14, S8, L6, L18, S5, L30, and L15. This operon is feedback regulated by S8, which binds near the translation start site of L5 and inhibits translation of L5 directly and that of the distal genes indirectly. We constructed plasmids carrying a major portion of the spc operon genes under lac transcriptional control. The plasmids carried a point mutation in the S8 target site which abolished regulation and resulted in overproduction of plasmid-encoded ribosomal proteins upon induction. We showed that alteration of the AUG start codon of L5 to UAG decreased the synthesis rates of plasmid-encoded distal proteins, as well as L5, by approximately 20-fold, with a much smaller (if any) effect on mRNA synthesis rates, indicating coupling of the distal cistrons' translation with the translation of L5. This conclusion was also supported by experiments in which S8 was overproduced in trans. In this case, there was a threefold reduction in the synthesis rates of chromosome-encoded L5 and the distal spc operon proteins, but no decrease in the mRNA synthesis rate. These observations also suggest that transcription from ribosomal protein promoters may be special, perhaps able to overcome transcription termination signals. We also analyzed the state of ribosomal protein mRNA after overproduction of S8 in these experiments and found that repression of ribosomal protein synthesis was accompanied by stimulation of processing (and degradation) of spc operon mRNA. The possible role of mRNA degradation in tightening the regulation is discussed.

Secondary structure of the leader transcript from the Escherichia coli S10 ribosomal protein operon

Genetic analysis of the autogenous control of the S10 ribosomal protein operon of Escherichia coli has suggested that the secondary or tertiary structure of the leader transcript is important for this regulation. We have therefore determined the secondary structure of the leader by enzyme digestion and chemical modification. Our results suggest that the 172 base leader exists in two forms, differing only immediately upstream of the Shine-Dalgarno sequence of the first gene. We discuss the possibility that the equilibrium between these alternate structures is important for the L4-mediated regulation of translation of the S10 operon. We have also determined the structure of several mutant transcripts. Correlation of these structures with the regulatory phenotypes suggest that a hairpin about 50 bases upstream of the first gene is essential for the control of translation of the operon. Finally, our results show that a two base substitution in an eight base loop destabilizes the attached stem.

Organization of ribosomal protein genes rpl23, rpl2, rps19, rpl22 and rps3 on the Euglena gracilis chloroplast genome

The nucleotide sequence (4,814 bp) was determined for a cluster of five ribosomal protein genes and their DNA flanking regions from the chloroplast genome of Euglena gracilis. The genes are organized as rpl23-150 bp spacer-rpl2-59 bp spacer-rps19-110 bp spacer-rpl22-630 bp spacer-rps3. The genes are all of the same polarity and reside 148 bp downstream from an operon for two genes of photosystem I and four genes of photosystem II. The Euglena ribosomal protein gene cluster resembles the S-10 ribosomal protein operon of Escherichia coli in gene organization and follows the exact linear order of the analogous genes in the tobacco and liverwort chloroplast genomes. The number and positions of introns in the Euglena ribosomal protein loci are different from their higher plant counterparts. The Euglena rpl23, rps19 and rps3 loci are unique in that they contain three, two and two introns, respectively, whereas rpl2 and rpl22 lack introns. The introns found in rpl23 (106, 99 and 103 bp), rps19 (103 and 97 bp) and rps3 intron 2 (102 bp) appear to represent either a new class of chloroplast intron found only in constitutively expressed genes, or possibly a degenerate version of Euglena chloroplast group II introns. They are deficient in bases C and G and extremely rich in base T, with a base composition of 53-76% T, 25-34% A, 3-10% G and 2-7% C in the mRNA-like strand. These six introns show minimal resemblance to group II chloroplast introns. They have a degenerate version of the group II intron conserved boundary sequences at their 5' and 3' ends. No conserved internal secondary structures are apparent. By contrast, rps3 intron 1 (409 bp) has a potential group II core secondary structure. The five genes, rpl23 (101 codons), rpl2 (278 codons), rps19 (95 codons), rpl22 (114 codons) and rps3 (220 codons) encode lysine-rich polypeptides with predicted molecular weights of 12,152, 31,029, 10,880, 12,819, and 25,238, respectively. The Euglena gene products are 18-50%, and 29-58% identical in primary structure to their E. coli and higher plant counterparts, respectively. Oligonucleotide sequences corresponding to Euglena chloroplast ribosome binding sites are not apparent in the intergenic regions. Inverted repeat sequences are found in the upstream flanking region of rpl23 and downstream from rps3.

Deficiency in both type I and type II DNA topoisomerase activities differentially affect rRNA and ribosomal protein synthesis in Schizosaccharomyces pombe

The synthesis of rRNA and r-proteins was studied in temperature-sensitive topoisomerase mutants of the fisson yeast Schizosaccharomyces pombe. To reduce the severity of heatshock response seen in the wild type strain, slow temperature shift-up of the cultures was used to inactivate the mutant topoisomerases. It was found that the temperature shift caused a large preferential reduction of rRNA synthesis in the top1top2 double mutant. In contrast, no preferential inhibition of rRNA synthesis was observed in top1 or top2 single mutants, although some reduction in the total RNA synthesis was observed in the top2 mutant. Thus, as observed with Saccharomyces cerevisiae (Brill et al. 1987), relaxation of supercoiled DNA structures by either topoisomerase I or II appears to be essential for efficient transcription of rRNA genes. Analysis of r-protein synthesis indicated that there were small decreases in the differential synthesis rates of r-proteins after temperature shift-up in the top1top2 mutant, but the observed negative effects on r-protein synthesis was much smaller than that on rRNA synthesis, and degradation of the newly synthesized r-proteins was observed. These observations indicate the apparent lack of tight coupling between rRNA and r-protein synthesis in S. pombe under these experimental conditions.

Transcription of the tRNA-tufB operon of Escherichia coli: activation, termination and antitermination

Signals setting the level of transcription of the tRNA-tufB operon have been studied by deletion mapping. TufB transcription was measured in vivo with plasmid-borne tRNA-tufB:galk operon fusions. Removal of the sequences from -133 to -58 with respect to the transcription start point, results in a 90% decrease of tufB transcription. This demonstrates the presence of a region, upstream of the tRNA-tufB promoter, that enhances the expression of the operon. DNA fragments bearing this upstream activator region do not display an abnormal electrophoretic mobility, as has been observed for the rrnB P1 upstream activator. Deletions starting in the first tRNA gene and directing towards tufB reveal at least two sites that influence tufB transcription. One signals transcription termination in the intergenic region between thrT and tufB. The other may be involved in antitermination. Possible mechanisms underlying antitermination and termination are considered in the light of the nucleotide sequence.

Secondary structure of the autoregulatory mRNA binding site of ribosomal protein L1

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.

Autogenous control of the S10 ribosomal protein operon of Escherichia coli: genetic dissection of transcriptional and posttranscriptional regulation

The S10 ribosomal protein operon is regulated autogenously by the product of one of the genes of the operon, the gene encoding ribosomal protein L4. We have used site-directed mutagenesis to isolate leader mutations affecting L4 control. The phenotypes of these mutants demonstrate that L4 regulates both transcription and translation of the S10 operon. Several mutations abolish both levels of L4 control; others eliminate either transcriptional or translational control with little or no effect on the other mode of regulation. We conclude that L4-mediated transcriptional and translational control share some sequence requirements, but the two regulatory processes recognize somewhat different features of the S10 leader. Primary as well as secondary structures within the S10 leader appear to be involved.

S4-alpha mRNA translation repression complex. I. Thermodynamics of formation

Expression of the four ribosomal proteins from the Escherichia coli alpha operon (S4, S11, S13, and L17) is regulated at the level of translation by the binding of S4 to the alpha mRNA. Using a filter binding assay and alpha mRNA sequences prepared by in-vitro transcription, previous work located the S4 target site within the approximately 100-base leader sequence. We have extended this work to include fragments of the alpha leader with six different 5' end points and four different 3' end points. A core region between bases 23 and 69 (numbering from the first nucleotide of the E. coli transcript) binds S4 with an affinity of approximately 2 microM-1. Regions of weak interactions are located in the 22 nucleotides 5' and the 70 nucleotides 3' to this core; they increase the S4 affinity to approximately 13 microM-1. Studies of S4-alpha mRNA binding under different conditions have revealed the following. (1) Specific and non-specific binding show the same dependence on K+ concentration, with delta log+ K/delta log [K+] approximately 4 in most potassium salts. With KCl and KBr, much weaker salt dependence of specific complex formation is observed suggesting that the protein responds to the correct RNA substrate by binding halide anions. (2) Increasing the MgCl2 concentration between 1 and 4 mM enhances binding by a factor of 4, with no further effects up to 20 mM. About five Mg2+ are taken up by the complex with an average binding constant of approximately 600 M-1 each. Renaturation of the RNA in the presence of MgCl2 is also required to obtain full binding. These effects are seen only with alpha mRNA extending beyond the initiation codon; S4 binding to the alpha leader sequence itself is insensitive to Mg2+. (3) The association kinetics are fast and probably diffusion controlled. (4) Formation of the complex is entirely entropy driven.

Localization of a r-protein gene within the chloroplast DNA replication origin of Chlamydomonas

In our previous study of chloroplast (Cp) DNA replication in Chlamydomonas reinhardtii, one D-loop site with its flanking regions was cloned and sequenced. The D-loop site mapped by electron microscopy (EM) overlaps with an open reading frame (ORF) potentially coding for a polypeptide of 136 amino acids. In this report, the corresponding D-loop isolated from another species of Chlamydomonas was sequenced. An ORF was also detected. Sequence comparison indicated that most conserved sequences between these two cloned origins are located within the ORF. Amino acid sequences of these two ORFs are highly conserved. The corresponding sequence for this ORF in the tobacco Cp genome was located by a Southern blotting analysis. Since the complete sequence data of Cp DNAs from a liverwort and from tobacco have been determined in 2 Japanese laboratories recently, it has been possible for us to show that this ORF encodes a protein homologous to the Cp ribosomal protein (r-protein) L16, by sequence comparison.