Sequence organization of replication origin of the Escherichia coli K-12 chromosome

A sequence of 245 base-pairs (oriC) in the replication origin of the Escherichia coli K-12 chromosome has been shown to provide all the information essential for initiation of bidirectional replication. In order to elucidate the sequence organization of oriC, numerous mutants carrying a single-to-multiple transitions from G X C to A X T base-pair were constructed by localized mutagenesis in vitro, which uses sodium bisulfite, and the correlation between the mutation sites and replicating ability (Ori function) was systematically analyzed. By isolating non-defective (Ori+) mutants with multiple base changes, transitions at 71 positions among 101 G X C pairs in oriC were found to have no effect on Ori function. Investigation of defective (Ori-) mutants, on the other hand, showed that individual replacements at 18 positions were detrimental to Ori function to some extent. These irreplaceable G X C pairs fell in the positions where no substitution was detected in the Ori+ mutants. The defect of the Ori- mutants with a single base substitution was generally weaker than that of the previously constructed Ori- mutants lacking a part of oriC. The addition of two or more base changes each giving a faint Ori- phenotype, however, resulted in a more intensive Ori- phenotype. We have previously demonstrated that oriC contains several regions where deletion or insertion of oligonucleotides leads to strong Ori- phenotypes. Transitions in those areas did not cause any defect of Ori function. Combining present results on base substitution mutants with the previous observations together, we assumed that the oriC sequence provides multiple interaction sites with replication initiation factors, and the precise arrangement of these sites are required for Ori function.     

Involvement of helix 34 of 16 S rRNA in decoding and translocation on the ribosome

Helix 34 of 16 S rRNA is located in the head of the 30 S ribosomal subunit close to the decoding center and has been invoked in a number of ribosome functions. In the present work, we have studied the effects of mutations in helix 34 both in vivo and in vitro. Several nucleotides in helix 34 that are either highly conserved or form important tertiary contacts in 16 S rRNA (U961, C1109, A1191, and A1201) were mutated, and the mutant ribosomes were expressed in the Escherichia coli MC250 Delta7 strain that lacks all seven chromosomal rRNA operons. Mutations at positions A1191 and U961 reduced the efficiency of subunit association and resulted in structural rearrangements in helix 27 (position 908) and helix 31 (position 974) of 16 S rRNA. All mutants exhibited increased levels of frameshifting and nonsense readthrough. The effects on frameshifting were specific in that -1 frameshifting was enhanced with mutant A1191G and +1 frameshifting with the other mutants. Mutations of A1191 moderately (approximately 2-fold) inhibited tRNA translocation. No significant effects were found on efficiency and rate of initiation, misreading of sense codons, or binding of tRNA to the E site. The data indicate that helix 34 is involved in controlling the maintenance of the reading frame and in tRNA translocation.     

Mischarging mutants of Su+2 glutamine tRNA in E. coli. I. Mutations near the anticodon cause mischarging

In order to select the mischarging mutants of Su+2 glutamine tRNA, auxotrophic amber mutants of E. coli K12 which cannot be suppressed particularly by Su+2 were screened. By utilizing these mutants, cysam235 and metam3, several tens of mischarging mutants of Su+2 were isolated, as those conferring altered suppression patterns for a set of tester amber mutants of bacteria and phages. Nucleotide sequence analysis revealed that the mutation sites were found to be exclusively at psi 37 residue located at the 3'-end of anticodon loop, changing it to either A37 or C37. These mutants were obtained as those suppressing cysam235, and not metam3. From these, secondary mutants were selected. In these mutants suppression patterns were further altered by the additional base substitutions, capable of suppressing metam3. Such mutants were obtained exclusively from A37 and not from C37 mutant tRNA. Additional mutations to A37 were found to be either A29 or C38, which are located at the lowermost two base pairs in anticodon stem. The mischarging sites in Su+2 glutamine tRNA locate in the newly detected region of tRNA, differing from the previous case of Su+3 tyrosine or Su+7 tryptophan tRNAs. Implication of this finding is discussed on L-shaped tRNA molecule in relation to aminoacyl-tRNA synthetase recognition. Suppression patterns given by the double-mutants, A37A29 and A37C38, were consistent with the observation that the mutant tRNAs interact with tryptophanyl-tRNA synthetase.     

Role of the three consecutive G:C base pairs conserved in the anticodon stem of initiator tRNAs in initiation of protein synthesis in Escherichia coli.

The three consecutive G:C base pairs, G29:C41, G30:C40, and G31:C39, are conserved in the anticodon stem of virtually all initiator tRNAs from eubacteria, eukaryotes, and archaebacteria. We show that these G:C base pairs are important for function of the tRNA in initiation of protein synthesis in vivo. We changed these base pairs individually and in combinations and analyzed the activities of the mutant Escherichia coli initiator tRNAs in initiation in vivo. For assessment of activity of the mutant tRNAs in vivo, mutations in the G:C base pairs were coupled to mutation in the anticodon sequence from CAU to CUA. Mutations in each of the G:C base pairs reduced activity of the mutant tRNA in initiation, with mutation in the second G:C base pair having the most severe effect. The greatly reduced activity of this C30:G40 mutant tRNA is not due to defects in aminoacylation or formulation of the tRNA or defects in base modification of the A37, next to the anticodon, which we had previously shown to be important for activity of the mutant tRNAs in initiation. The anticodon stem mutants are most likely affected specifically at the step of binding to the ribosomal P site. The pattern of cleavages in the anticodon loop of mutant tRNAs by S1 nuclease indicate that the G:C base pairs may be involved directly in interactions of the tRNA with components of the P site on the ribosome rather than indirectly by inducing a particular conformation of the anticodon loop critical for function of the tRNA in initiation.     

Interaction of translation initiation factor IF1 with the E. coli ribosomal A site

Initiation Factor 1 (IF1) is required for the initiation of translation in Escherichia coli. However, the precise function of IF1 remains unknown. Current evidence suggests that IF1 is an RNA-binding protein that sits in the A site of the decoding region of 16 S rRNA. IF1 binding to 30 S subunits changes the reactivity of nucleotides in the A site to chemical probes. The N1 position of A1408 is enhanced, while the N1 positions of A1492 and A1493 are protected from reactivity with dimethyl sulfate (DMS). The N1-N2 positions of G530 are also protected from reactivity with kethoxal. Quantitative footprinting experiments show that the dissociation constant for IF1 binding to the 30 S subunit is 0.9 microM and that IF1 also alters the reactivity of a subset of Class III sites that are protected by tRNA, 50 S subunits, or aminoglycoside antibiotics. IF1 enhances the reactivity of the N1 position of A1413, A908, and A909 to DMS and the N1-N2 positions of G1487 to kethoxal. To characterize this RNA-protein interaction, several ribosomal mutants in the decoding region RNA were created, and IF1 binding to wild-type and mutant 30 S subunits was monitored by chemical modification and primer extension with allele-specific primers. The mutations C1407U, A1408G, A1492G, or A1493G disrupt IF1 binding to 30 S subunits, whereas the mutations G530A, U1406A, U1406G, G1491U, U1495A, U1495C, or U1495G had little effect on IF1 binding. Disruption of IF1 binding correlates with the deleterious phenotypic effects of certain mutations. IF1 binding to the A site of the 30 S subunit may modulate subunit association and the fidelity of tRNA selection in the P site through conformational changes in the 16 S rRNA.     

The A1 x U72 base pair conserved in eukaryotic initiator tRNAs is important specifically for binding to the eukaryotic translation initiation factor eIF2.

The formation of a specific ternary complex between eukaryotic initiation factor 2 (eIF2), the initiator methionyl-tRNA (Met-tRNA), and GTP is a critical step in translation initiation in the cytoplasmic protein-synthesizing system of eukaryotes. We show that the A1 x U72 base pair conserved at the end of the acceptor stem in eukaryotic and archaebacterial initiator methionine tRNAs plays an important role in this interaction. We changed the A1 x U72 base pair of the human initiator tRNA to G1 x C72 and expressed the wild-type and mutant tRNA genes in the yeast Saccharomyces cerevisiae by using constructs previously developed in our laboratory for expression of the human initiator tRNA gene in yeasts. We show that both the wild-type and mutant human initiator tRNAs are aminoacylated well in vivo. We have isolated the wild-type and mutant human initiator tRNAs in substantially pure form, free of the yeast initiator tRNA, and have analyzed their properties in vitro. The G1 x C72 mutation affects specifically the binding affinity of eIF2 for the initiator tRNA. It has no effect on the subsequent formation of 40S or 80S ribosome initiator Met-tRNA-AUG initiation complexes in vitro or on the puromycin reactivity of the Met-tRNA in the 80S initiation complex.     

Footprinting mRNA-ribosome complexes with chemical probes.

We footprinted the interaction of model mRNAs with 30S ribosomal subunits in the presence or absence of tRNA(fMet) or tRNA(Phe) using chemical probes directed at the sugar-phosphate backbone or bases of the mRNAs. When bound to the 30S subunits in the presence of tRNA(fMet), the sugar-phosphate backbones of gene 32 mRNA and 022 mRNA are protected from hydroxyl radical attack within a region of about 54 nucleotides bounded by positions -35 (+/- 2) and +19, extending to position +22 when tRNA(Phe) is used. In 70S ribosomes, protection is extended in the 5' direction to about position -39 (+/- 2). In the absence of tRNA, the 30S subunit protects only nucleotides -35 (+/- 2) to +5. Introduction of a stable tetraloop hairpin between positions +10 and +11 of gene 32 mRNA does not interfere with tRNA(fMet)-dependent binding of the mRNA to 30S subunits, but results in loss of protection of the sugar-phosphate backbone of the mRNA downstream of position +5. Using base-specific probes, we find that the Shine-Dalgarno sequence (A-12, A-11, G-10 and G-9) and the initiation codon (A+1, U+2 and G+3) of gene 32 mRNA are strongly protected by 30S subunits in the presence of initiator tRNA. In the presence of tRNA(Phe), the same Shine-Dalgarno bases are protected, as are U+4, U+5 and U+6 of the phenylalanine codon. Interestingly, A-1, immediately preceding the initiation codon, is protected in the complex with 30S subunits and initiator tRNA, while U+2 and G+3 are protected in the complex with tRNA(Phe) in the absence of initiator tRNA. Additionally, specific bases upstream from the Shine-Dalgarno region (U-33, G-32 and U-22) as well as 3' to the initiation codon (G+11) are protected by 30S subunits in the presence of either tRNA. These results imply that the mRNA binding site of the 30S subunit covers about 54-57 nucleotides and are consistent with the possibility that the ribosome interacts with mRNA along its sugar-phosphate backbone.     

Yeast as a model of human mitochondrial tRNA base substitutions: investigation of the molecular basis of respiratory defects

We investigate the relationships between acylation defects and structure alterations due to base substitutions in yeast mitochondrial (mt) tRNA(UUR)(Leu). The studied substitutions are equivalent to the A3243G and T3250C human pathogenetic tRNA mutations. Our data show that both mutations can produce tRNA(UUR)(Leu) acylation defects, although to a different extent. For mutant A14G (equivalent to MELAS A3243G base substitution), the presence of the tRNA and its defective aminoacylation could be observed only in the nuclear context of W303, a strain where the protein synthesis defects caused by tRNA base substitutions are far less severe than in previously studied strains. For mutant T20C (equivalent to the MM/CPEO human T3250C mutation), the acylation defect was less severe, and a thermosensitive acylation could be detected also in the MCC123 strain. The correlation between the severity of the in vivo phenotypes of yeast tRNA mutants and those obtained in in vitro studies of human tRNA mutants supports the view that yeast is a suitable model to study the cellular and molecular effects of tRNA mutations involved in human pathologies. Furthermore, the yeast model offers the possibility of modulating the severity of yeast respiratory phenotypes by studying the tRNA mutants in different nuclear contexts. The nucleotides at positions 14 and 20 are both highly conserved in yeast and human mt tRNAs; however, the different effect of their mutations can be explained by structure analyses and quantum mechanics calculations that can shed light on the molecular mechanisms responsible for the experimentally determined defects of the mutants.