Philip R. Cunningham

Chemical evidence for domain assembly of the Escherichia coli 30S ribosome.

A fragment of 16S RNA corresponding to most of the 5′‐domain (residues 1‐526) was prepared by in vitro run‐off transcription. When this fragment was incubated with a mixture of 30S proteins under conditions known to result in the in vitro assembly of a complete, functional 30S ribosome from a full‐length transcript, a discrete 16S particle was formed. This particle contained near stoichiometric amounts of ribosomal proteins S4, S16, S17, and S20. These four proteins are the same, and only, ones that have been shown to interact with the 5′ domain of 16S RNA in the intact 30S ribosome in the foot‐printing studies of Noller and co‐workers. We conclude that the 5′ fragment 1‐526 is capable of folding independently of the rest of the molecule so as to generate the protein binding sites for the same four proteins with which the corresponding segment of full‐length 16S RNA normally interacts. These sites not only include those for S4, S17, and S20 that are known to bind directly to the RNA, but also the site for S16, which requires the prior binding of S4 and S20.— Weitzmann, C. J., Cunningham, P. R., Nurse, K., and Ofengand, J. Chemical evidence for domain assembly of the Escherichia coli 30S ribosome. FASEB J. 7: 177‐180; 1993.

Aerobic Activity of Escherichia coli Alcohol Dehydrogenase Is Determined by a Single Amino Acid

Expression of the alcohol dehydrogenase gene, adhE, in Escherichia coli is anaerobically regulated at both the transcriptional and the translational levels. To study the AdhE protein, the adhE(+) structural gene was cloned into expression vectors under the control of the lacZ and trp(c) promoters. Wild-type AdhE protein produced under aerobic conditions from these constructs was inactive. Constitutive mutants (adhC) that produced high levels of AdhE under both aerobic and anaerobic conditions were previously isolated. When only the adhE structural gene from one of the adhC mutants was cloned into expression vectors, highly functional AdhE protein was isolated under both aerobic and anaerobic conditions. Sequence analysis revealed that the adhE gene from the adhC mutant contained two mutations resulting in two amino acid substitutions, Ala267Thr and Glu568Lys. Thus, adhC strains contain a promoter mutation and two mutations in the structural gene. The mutant structural gene from adhC strains was designated adhE*. Fragment exchange experiments revealed that the substitution responsible for aerobic expression in the adhE* clones is Glu568Lys. Genetic selection and site-directed mutagenesis experiments showed that virtually any amino acid substitution for Glu568 produced AdhE that was active under both aerobic and anaerobic conditions. These findings suggest that adhE expression is also regulated posttranslationally and that strict regulation of alcohol dehydrogenase activity in E. coli is physiologically significant.

Site-specific mutation of the conserved m62 A m62 A residues of E. coli 16S ribosomal RNA. Effects on ribosome function and activity of the ksgA methyltransferase

In vitro synthesis of mutant 16S RNA and reconstitution with ribosomal proteins into a mutant 30S ribosome was used to make all possible single base changes at the universally conserved A1518 and A1519 residues. All of the mutant RNAs could be assembled into a ribosomal subunit which sedimented at 30 S and did not lack any of the ribosomal proteins. A series of in vitro tests of protein synthesis ability showed that all of the mutants had some activity. The amount varied according to the assay and mutant, but was never less than 30% and was generally above 50%. Therefore, neither the conserved A1518 nor A1519 residues are essential for ribosome function. The mutant ribosomes could also be methylated by the ksgA methyltransferase to 70-120% of the expected amount. Thus, neither of the A residues is required for methylation of the other, ruling out any obligate order of methylation of A1518 and A1519.

Functional Studies of the 900 Tetraloop Capping Helix 27 of 16 S Ribosomal RNA

The 900 tetraloop (positions 898-901) of Escherichia coli 16S rRNA caps helix 27, which is involved in a conformational switch crucial for the decoding function of the ribosome. This tetraloop forms a GNRA motif involved in intramolecular RNA-RNA interactions with its receptor in helix 24 of 16S rRNA. It is involved also in an intersubunit bridge, via an interaction with helix 67 in domain IV of 23S rRNA. Using a specialized ribosome system and an instant-evolution procedure, the four nucleotides of this loop were randomized and 15 functional mutants were selected in vivo. Positions 899 and 900, responsible for most of the tetraloop/receptor interactions, were found to be the most critical for ribosome activity. Functional studies showed that mutations in the 900 tetraloop impair subunit association and decrease translational fidelity. Computer modeling of the mutations allows correlation of the effect of mutations with perturbations of the tetraloop/receptor interactions.

Combinatorial genetic technology for the development of new anti-infectives

CONTEXT We previously developed a novel technology known as instant evolution for high-throughput analysis of mutations in Escherichia coli ribosomal RNA. OBJECTIVE To develop a genetic platform for the isolation of new classes of anti-infectives that are not susceptible to drug resistance based on the instant evolution system. DESIGN Mutation libraries were constructed in the 16S rRNA gene of E coli and analyzed. In addition, the rRNA genes from a number of pathogenic bacteria were cloned and expressed in E coli. The 16S rRNA genes were incorporated into the instant-evolution system in E coli. SETTING The Department of Biological Sciences, Wayne State University, Detroit, Mich. MAIN OUTCOME MEASURES Ribosome function was assayed by measuring the amount of green fluorescent protein produced by ribosomes containing mutant or foreign RNA in vivo. RESULTS We have developed a new combinatorial genetic technology (CGT) platform that allows high-throughput in vivo isolation and analysis of rRNA mutations that might lead to drug resistance. This information is being used to develop anti-infectives that recognize the wild type and all viable mutants of the drug target. CGT also provides a novel mechanism for identifying new drug targets. CONCLUSIONS Antimicrobials produced using CGT will provide new therapies for the treatment of infections caused by human pathogens that are resistant to current antibiotics. The new therapeutics will be less susceptible to de novo resistance because CGT identifies all mutations of the target that might lead to resistance during the earliest stages of the drug discovery process.

Selection of peptides targeting helix 31 of bacterial 16S ribosomal RNA by screening M13 phage-display libraries.

Ribosomal RNA is the catalytic portion of ribosomes, and undergoes a variety of conformational changes during translation. Structural changes in ribosomal RNA can be facilitated by the presence of modified nucleotides. Helix 31 of bacterial 16S ribosomal RNA harbors two modified nucleotides, m2G966 and m5C967, that are highly conserved among bacteria, though the degree and nature of the modifications in this region are different in eukaryotes. Contacts between helix 31 and the P-site tRNA, initiation factors, and ribosomal proteins highlight the importance of this region in translation. In this work, a heptapeptide M13 phage-display library was screened for ligands that target the wild-type, naturally modified bacterial helix 31. Several peptides, including TYLPWPA, CVRPFAL, TLWDLIP, FVRPFPL, ATPLWLK, and DIRTQRE, were found to be prevalent after several rounds of screening. Several of the peptides exhibited moderate affinity (in the high nM to low µM range) to modified helix 31 in biophysical assays, including surface plasmon resonance (SPR), and were also shown to bind 30S ribosomal subunits. These peptides also inhibited protein synthesis in cell-free translation assays.

Identification and role of functionally important motifs in the 970 loop of Escherichia coli 16S ribosomal RNA.

The 970 loop (helix 31) of Escherichia coli 16S ribosomal RNA contains two modified nucleotides, m(2)G966 and m(5)C967. Positions A964, A969, and C970 are conserved among the Bacteria, Archaea, and Eukarya. The nucleotides present at positions 965, 966, 967, 968, and 971, however, are only conserved and unique within each domain. All organisms contain a modified nucleoside at position 966, but the type of the modification is domain specific. Biochemical and structure studies have placed this loop near the P site and have shown it to be involved in the decoding process and in binding the antibiotic tetracycline. To identify the functional components of this ribosomal RNA hairpin, the eight nucleotides of the 970 loop of helix 31 were subjected to saturation mutagenesis and 107 unique functional mutants were isolated and analyzed. Nonrandom nucleotide distributions were observed at each mutated position among the functional isolates. Nucleotide identity at positions 966 and 969 significantly affects ribosome function. Ribosomes with single mutations of m(2)G966 or m(5)C967 produce more protein in vivo than do wild-type ribosomes. Overexpression of initiation factor 3 specifically restored wild-type levels of protein synthesis to the 966 and 967 mutants, suggesting that modification of these residues is important for initiation factor 3 binding and for the proper initiation of protein synthesis.

Genetic Analysis of the Invariant Residue G791 in Escherichia coli 16S rRNA Implicates RelA in Ribosome Function

Previous studies identified G791 in Escherichia coli 16S rRNA as an invariant residue for ribosome function. In order to establish the functional role of this residue in protein synthesis, we searched for multicopy suppressors of the mutant ribosomes that bear a G-to-U substitution at position 791. We identified relA, a gene whose product has been known to interact with ribosomes and trigger a stringent response. Overexpression of RelA resulted in the synthesis of approximately 1.5 times more chloramphenicol acetyltransferase (CAT) protein than could be synthesized by the mutant ribosomes in the absence of RelA overexpression. The ratio of mutant rRNA to the total ribosome pool was not changed, and the steady-state level of CAT mRNA was decreased by RelA overexpression. These data confirmed that the phenotype of RelA as a multicopy suppressor of the mutant ribosome did not result from the enhanced synthesis of mutant rRNA or CAT mRNA from the plasmid. To test whether the phenotype of RelA was related to the stringent response induced by the increased cellular level of (p)ppGpp, we screened for mutant RelA proteins whose overexpression enhances CAT protein synthesis by the mutant ribosomes as effectively as wild-type RelA overexpression and then screened for those whose overexpression does not produce sufficiently high levels of (p)ppGpp to trigger the stringent response under the condition of amino acid starvation. Overexpression of the isolated mutant RelA proteins resulted in the accumulation of (p)ppGpp in cells, which was amounted to approximately 18.2 to 38.9% of the level of (p)ppGpp found in cells that overexpress the wild-type RelA. These findings suggest that the function of RelA as a multicopy suppressor of the mutant ribosome does not result from its (p)ppGpp synthetic activity. We conclude that RelA has a previously unrecognized role in ribosome function.

Photoinduced cleavage by a rhodium complex at G.U mismatches and exposed guanines in large and small RNAs.

Photoinduced cleavage reactions by the rhodium complex tris(4,7-diphenyl-1,10-phenanthroline)rhodium(III) [Rh(DIP)(3)(3+)] with three RNA hairpins, r(GGGGU UCGCUC CACCA) (16 nucleotide, tetraloop(Ala2)), r(GGGGCUAUAGCUCUAGCUC CACCA) (24 nucleotide, microhelix(Ala)), and r(GGCGGUUAGAUAUCGCC) (17 nucleotide, 790 loop), and full-length (1542 nucleotide) 16S rRNA from Escherichia coli were investigated. The cleavage reactions were monitored by gel electrophoresis and the sites of cleavage by Rh(DIP)(3)(3+) were determined by comparisons with chemical or enzymatic sequencing reactions. In general, RNA backbone scission by the metal complex was induced at G.U mismatches and at exposed G residues. The cleavage activity was observed on the three small RNA hairpins as well as on the isolated 1542-nucleotide ribosomal RNA.

Protein–RNA Dynamics in the Central Junction Control 30S Ribosome Assembly

Interactions between ribosomal proteins (rproteins) and ribosomal RNA (rRNA) facilitate the formation of functional ribosomes. S15 is a central domain primary binding protein that has been shown to trigger a cascade of conformational changes in 16S rRNA, forming the functional structure of the central domain. Previous biochemical and structural studies in vitro have revealed that S15 binds a three-way junction of helices 20, 21, and 22, including nucleotides 652-654 and 752-754. All junction nucleotides except 653 are highly conserved among the Bacteria. To identify functionally important motifs within the junction, we subjected nucleotides 652-654 and 752-754 to saturation mutagenesis and selected and analyzed functional mutants. Only 64 mutants with greater than 10% ribosome function in vivo were isolated. S15 overexpression complemented mutations in the junction loop in each of the partially active mutants, although mutations that produced inactive ribosomes were not complemented by overexpression of S15. Single-molecule Förster or fluorescence resonance energy transfer (smFRET) was used to study the Mg(2+)- and S15-induced conformational dynamics of selected junction mutants. Comparison of the structural dynamics of these mutants with the wild type in the presence and absence of S15 revealed specific sequence and structural motifs in the central junction that are important in ribosome function.