23S rRNA positions essential for tRNA binding in ribosomal functional sites

rRNA plays an important role in function of peptidyl transferase, the catalytic center of the ribosome responsible for the peptide bond formation. Proper placement of the peptidyl transferase substrates, peptidyl-tRNA and aminoacyl-tRNA, is essential for catalysis of the transpeptidation reaction and protein synthesis. In this report, we define a small set of rRNA nucleotides that are most likely directly involved in binding of tRNA in the functional sites of the large ribosomal subunit. By binding biotinylated tRNA substrates to randomly modified large ribosomal subunits from Escherichia coli and capturing resulting complexes on the avidin resin, we identified four nucleotides in the large ribosomal subunit rRNA (positions G2252, A2451, U2506, and U2585) whose modifications prevent binding of a peptidyl-tRNA analog in the P site and one residue (U2555) whose modification interferes with transfer of peptidyl moiety to puromycin. These nucleotides represent a subset of positions protected by tRNA analogs from chemical modification and significantly narrow the number of 23S rRNA nucleotides that may be directly involved in tRNA binding in the ribosomal functional sites.     

The chemical synthesis of E. coli tRNA(Lys) anticodon loop fragment and its analogues

E. coli tRNA(Lys) anticodon loop fragment (Umnm5s2UUUt6A) 1 and its analogues 2-6 were synthesized by the classical phosphotriester approach in solution. The preparation of suitably protected derivatives of N6-threonylcarbamoyladenosine 18 is also described.     

A tRNA identity switch mediated by the binding interaction between a tRNA anticodon and the accessory domain of a class II aminoacyl-tRNA synthetase

Identity elements in tRNAs and the intracellular balance of tRNAs allow accurate selection of tRNAs by aminoacyl-tRNA synthetases. The histidyl-tRNA from Escherichia coli is distinguished by a unique G-1.C73 base pair that upon exchange with other nucleotides leads to a marked decrease in the rate of aminoacylation in vitro. G-1.C73 is also a major identity element for histidine acceptance, such that the substitution of C73 brings about mischarging by glycyl-, glutaminyl-, and leucyl-tRNA synthetases. These identity conversions mediated by the G-1.C73 base pair were exploited to isolate secondary site revertants in the histidyl-tRNA synthetase from E. coli which restore histidine identity to a histidyl-tRNA suppressor carrying U73. The revertant substitutions confer a 3-4 fold reduction in the Michaelis constant for tRNAs carrying the amber-suppressing anticodon and map to the C-terminal domain of HisRS and its interface with the catalytic core. These findings demonstrate that the histidine tRNA anticodon plays a significant role in tRNA selection in vivo and that the C-terminal domain of HisRS is in large part responsible for recognizing this trinucleotide. The kinetic parameters determined also show a small degree of anticooperativity (delta delta G = -1.24 kcal/mol) between recognition of the discriminator base and the anticodon, suggesting that the two helical domains of the tRNA are not recognized independently. We propose that these effects substantially account for the ability of small changes in tRNA binding far removed from the site of a major determinant to bring about a complete conversion of tRNA identity.     

Codon recognition by artificial tRNA molecules with modified nucleosides in the anticodon

Proteins with unnatural amino acids at specific positions can be produced through cell-free protein synthesis. The synthesis of such molecules can, in principle, be facilitated by improving the codon reading efficiency of the tRNA that inserts the unnatural amino acid. In the present study, we prepared tRNA molecules with 2'-O-methyl nucleosides at the second and third positions of the anticodon and measured their codon-reading efficiencies. The results indicated, contrary to our expectation, that the modification damaged the decoding function completely.     

Major groove binding of the tRNA/mRNA complex to the 16 S ribosomal RNA decoding site

We propose a detailed three-dimensional model, with atomic detail, for the structure of the Escherichia coli 16 S rRNA decoding site in a complex with mRNA and the A and P-site tRNAs. Model building began with four primary assumptions: (1) A and P-site tRNA conformations are identical with those seen in the tRNA crystal structure; (2) A and P-site tRNAs adopt an S-type orientation upon binding mRNA in the ribosome; (3) A1492 and A1493 bind non-specifically to the mRNA through a series of hydrogen bonds; and (4) C1400 lies in close proximity to the P-site tRNA wobble base in order to satisfy a UV-induced photocrosslink formed between the two residues. We have models with both major groove and minor groove binding of the tRNA/mRNA complex to the decoding site RNA, and conclude that major groove binding is more likely. Both classes of models maintain structural features reported in the NMR structure of the A-site region of the decoding site RNA with bound paromomycin. We also present models for the tRNA/mRNA complex bound to the decoding site RNA in the presence of the aminoglycoside paromomycin. We discuss possible mechanisms for ribosomal proof reading and antibiotic disruption of this proofreading.     

A functional requirement for modification of the wobble nucleotide in tha anticodon of a T4 suppressor tRNA

Temperature-sensitive mutants of E. coli have been isolated which restrict the growth of strains of bacteriophage T4 which are dependent upon the function of a T4-coded amber or ochre suppressor transfer RNA. One such mutant restricts the growth of certain ochre but not amber suppressor-requiring phage. Analysis of the T4 tRNAs synthesized in this host revealed that many nucleotide modifications are significantly reduced. The modifications most strongly affected are located in the anticodon regions of the tRNA'S. The T4 ochre suppressor tRNAs normally contain a modified U residue in the wobble position of the anticodon; it has been possible to correlate tha absence of this specific modification in the mutant host with the restriction of suppressor activity. Furthermore, the extent of this restriction varies dramatically with the site of the nonsense codon, indicating that the modification requirement is strongly influenced by the local context of the mRNA. An analysis of spontaneous revertants of the E. coli ts mutant indicates that temperature sensitivity, restriction of phage suppressor function, and undermodification of tRNA are the consequences of a single genetic lesion. The isolation of a class of partial revertants to temperature insensitivity which have simultaneously become sensitive to streptomycin suggests that the translational requirement for the anticodon modification can be partially overcome by a change in the structure of the ribosome.     

Determination of the angle between the acceptor and anticodon stems of a truncated mitochondrial tRNA

Significant departures from the canonical (cloverleaf) secondary structure of transfer (t)RNAs can be found among the mitochondrial (m)tRNAs of higher metazoans; these mtRNAs thus pose a challenge to the concept of an invariant, L-shaped tertiary conformation for all tRNAs. For bovine mtRNASer(AGY), which lacks the entire "dihydrouridine" (dhU) arm, two distinct tertiary models have been proposed: the first model preserves the L-shaped conformation at the expense of overall size; the second model preserves the absolute distance between the 3' terminus and the anticodon loop, while allowing the acceptor-anticodon interstem angle to vary. We have tested the central predictions of these two models by performing a series of transient electric birefringence measurements on bovine mtRNASer(AGY) constructs in which the aminoacyl-acceptor and anticodon stems were each extended by approximately 70 bp. This mtRNA species is particularly amenable to analysis, since the native bovine (heart) mtRNA is completely unmodified outside of the anticodon loop. For magnesium ion concentrations above 1 mM, the interstem angle for the extended mtRNA, 120(+/-5) degrees, is approximately 50% larger than the corresponding angle for yeast tRNAPhe (70-80 degrees) under the same ionic conditions. Furthermore, the interstem angles of the two tRNAs exhibit strikingly different responses to the addition of magnesium ions: the interstem angle for yeast tRNAPhe is reduced by nearly 50 % upon addition of 2 mM magnesium ions, whereas the angle for mtRNASer(AGY) increases by about 10%. Our data thus support a central prediction of the second model; namely, that truncated mtRNAs will possess more open interstem angles. In addition, we demonstrate that birefringence amplitude data can be used to provide model-independent estimates for the interstem angles.     

The anticodon and discriminator base are important for aminoacylation of Escherichia coli tRNA(Asn)

A gel shift assay that distinguishes the aminoacylated form from the deacylated form of tRNAs was used to study the requirements for aminoacylation of Escherichia coli tRNA(Asn) in vivo. tRNA(Asn) derivatives containing single base changes in their anticodons or discriminator bases were constructed, and the extent of in vivo aminoacylation was determined directly. Substitution of U35 with C35 or U36 with C36 abolished aminoacylation of the tRNA. Substitution of G34 with C34 converted tRNA(Asn) into a lysine acceptor. Thus, each of the anticodon nucleotides are important for aminoacylation of tRNA(Asn). Substitution of discriminator base G73 with A73 affected the extent of aminoacylation in vivo indicating that the discriminator base also contributes to aminoacylation of tRNA(Asn).     

Identification of a specific binding site for the anabolic steroid stanozolol in male rat liver microsomes

Male rat liver microsomes contain a [3H]dexamethasone binding site, capable of binding glucocorticoids and progesterone. We have shown previously that the 17 alpha-alkylated androgen, stanozolol, can inhibit the [3H]dexamethasone binding to microsomes through a negative allosteric mechanism, which gives rise to the possibility of its interaction with a different binding site. In this study, the existence of a single-saturating binding site, capable of binding the radioactive steroid with a maximum number of the specific binding site of 49 +/- 2 pmol/mg of protein and a Kd of 37 +/- 1.3 nM was demonstrated by using [3H]stanozolol. In competition experiments, only stanozolol and danazol were able to compete with [3H]stanozolol for its binding to microsomes, among more than 60 steroids and other compounds tested. The binding of [3H]stanozolol was depressed after protease treatment of the microsomes, or after the administration of cycloheximide to adult male rats for 24 hr, which suggest its proteic nature. The [3H]stanozolol binding site was detected in many tissues of the rat, with the highest concentrations being found in the liver. It was detected from birth, increasing afterward in concentration and reaching a peak at 2 to 3 months of age. This is the first experimental verification of the existence in liver microsomes of a specific binding site for some 17 alpha-alkylate androgens, such as stanozolol and danazol, different from the androgen receptor or the [3H]dexamethasone binding site.     

A functional analysis of the Tn5 transposase. Identification of domains required for DNA binding and multimerization

A series of deletions were constructed in the 476 amino acid Tn5 transposase in order to assemble an initial domain structure for this protein. The first four amino acids were found to be important for transposition activity but not for DNA binding to the Tn5 outside end (OE). Larger amino-terminal deletions result in the complete loss of transposition in vivo and the concomitant loss of specific DNA binding. Four point mutants and a six base-pair deletion in the amino terminus between residues 20 and 36 were also found to impair DNA binding to the OE. Analysis of a series of carboxy-terminal deletions has revealed that the carboxy terminus may actually mask the DNA binding domain, since deletions to residues 388 and 370 result in a large increase in DNA binding activity. In addition, the carboxy-terminal deletion to residue 370 results in a significant increase in the mobility of the Tnp-OE complex indicative of a change in the oligomeric state of this complex. Further carboxy-terminal deletions beyond residue 370 also abolished DNA binding activity. These results indicate that the first four amino acids of Tnp are important for transposition but not DNA binding, a region between residues 5 and 36 is critical for DNA binding, the wild-type carboxy terminus acts to inhibit DNA binding, and that a region towards the carboxy terminus, defined by residues 370 to 387, is critical for Tnp multimeric interactions.     

Identification of elements on GeneX-secA RNA of Escherichia coli required for SecA binding and secA auto-regulation

The protein translocation ATPase of Escherichia coli, SecA protein, auto-regulates its translation by binding to its translation initiation region in geneX-secA mRNA. To analyze this regulation further the secondary structure of this portion of geneX-secA RNA was investigated utilizing structure-specific nucleases and chemical probing approaches. The results of this analysis were consistent with the existence of two adjacent helices, helix I and the lower portion of helix II, whose function in secA activation and repression, respectively, has been demonstrated. Binding of SecA protein to geneX-secA RNA or various mutant derivatives of this RNA was studied by measurement of affinity constants, RNA footprint analysis, and quantitation of auto-repression in vivo. This analysis showed that the SecA-binding site in geneX-secA RNA was remarkably large spanning a region of 96 nucleotides including a 3' portion of helix II, the secA translation initiation region and distal sequences. From the size of the SecA-binding site and the plasticity of its response to mutational alteration, it is suggested that SecA protein contains two distinct RNA-binding sites. Finally, it was shown that SecA binding was not sufficient to promote auto-regulation and that sequences both upstream (helix I) and within the binding site can contribute to auto-regulation without affecting SecA-binding affinity.     

Binding of a fragment of yeast phenylalanyl tRNA containing an anticodon loop with 30S and 70S ribosomes from Escherichia coli. The role of guanosine-42 in this interaction

Poly(U)-dependent binding of isolated yeast tRNA(Phe) anticodon hairpin (15-nucleotide-long, corresponding to nucleotides 28-42 within the tRNA) and several its derivatives to the P site of Escherichia coli 30S and 70S ribosomes was studied quantitatively. The affinity for the hairpin binding to 70S ribosomes was shown to be only 30-fold weaker than that for the binding of total tRNA(Phe). Within the anticodon hairpin, removal of the 3'-terminal nucleotide corresponding to guanosine-42 in tRNA(Phe) decreases the association constant for the anticodon arm-ribosome interaction 15-fold. Replacement of this guanosine with other nucleosides does not affect the affinity, regardless of involvement in the hairpin secondary structure. These data indicate that G-42 affects the anticodon arm affinity most likely by forming a direct contact with the ribosome. One can assume that this nucleotide within intact tRNA also forms a contact with the P site. Since the 3'-terminal ribose modifications (oxidation, oxidation and reduction) as well as the presence or absence of the 3'-terminal phosphate does not affect the affinity of the anticodon arm fragment, the latter is obviously involved in the interaction through 3'-terminal nucleotide base groups which does not take part in base pairing.     

Three modified nucleosides present in the anticodon stem and loop influence the in vivo aa-tRNA selection in a tRNA-dependent manner

Programmed cell death (PCD) is activated during the response of multicellular organisms to some invading pathogens. One of the key aspects of this process is the degradation of nuclear DNA which is thought to facilitate the recycling of DNA from dead cells. The PCD of tobacco plants (genotype NN) infected with tobacco mosaic virus (TMV) is accompanied by the induction of nuclease activities and the cleavage of nuclear DNA to fragments of about 50 kb. We examined the correlation between the increase in nuclease activities and the fragmentation of nuclear DNA during TMV- and bacteria-induced PCD in tobacco. We found that the increase in nuclease activities did not always correlate with fragmentation of nuclear DNA. Thus, in addition to pathogens that induce PCD, mechanical injury and infiltration of leaves with 1 M sucrose or bacteria that did not induce PCD also resulted in an increase in nuclease activities. Analysis of nuclease activities in total leaf extracts, nuclear extracts, and intercellular fluid (i.e., apoplast) revealed that at least four different nuclease activities are induced during PCD in tobacco; of these at least three appear to be secreted into the intercellular fluid. Although the latter were also induced in response to treatments that did not result in DNA fragmentation, they may function in the recycling of plant DNA during late stages of PCD when the integrity of the plasma membrane is compromised. This suggestion is supported by the finding that DNA degradation occurred late during TMV-induced PCD in tobacco. In addition, the finding of induced nuclease activities in the intercellular fluid raises the possibility that they may serve a protective function by degrading the DNA of invading pathogens.     

Identification of a specific tyrosine residue in Bryodin 1 distinct from the active site but required for full catalytic and cytotoxic activity

Parvovirus B19 (B19) can cause chronic anemia due to persistent infection in immunocompromised hosts who cannot produce neutralizing antibody necessary for clearing B19. Three patients with X-linked hyper-IgM syndrome (XHIM), who were all asymptomatic until they developed B19-induced chronic anemia at the ages of 8, 14, and 17 years, respectively, were found to have mutations of the CD40L gene, including a missense mutation (T254M), a nonsense mutation resulting in a new initiation codon and loss of the intracellular domain (R11X), and a splice site mutation (nt 309+2t-->a). Antibody responses to the T cell-dependent antigen, bacteriophage phiX174, were impaired, but neutralizing antibody titers were higher than in XHIM patients with classic phenotype. All 3 patients responded to intravenous immune globulin (IVIG) treatment. Certain mutations of the CD40L gene result in a mild XHIM phenotype that may become apparent following B19 infection in patients not on IVIG therapy and therefore not protected from B19 infection.     

Identification of two specific prolactin binding sites on Nb2 rat lymphoma cells

IS1201, a 1387-bp insertion sequence isolated from Lactobacillus helveticus, was identified by its nucleotide (nt) sequence. It carries a single open reading frame encoding a 369-amino-acid protein, which shares homology with transposases found in a class of related IS, including ISRm3 from Rhizobium meliloti, IS256 from Staphylococcus aureus, IS6120 from Mycobacterium smegmatis, IS1081 from M. bovis, IST2 from Thiobacillus ferroxidans and IS406 from Pseudomonas cepacia. IS1201 has terminal inverted repeats of 24 bp in length and a target site duplication of 8 bp. Its copy number ranges from 3 to about 16 per L. helveticus genome. No homology was found between the nt sequence of IS1201 and those of the other bacterial IS from the same class. These results, together with previous observations [de los Reyes-Gavilán et al., Appl. Environ. Microbiol., 58 (1992) 3429-3432], confirm that IS1201 can be used as a specific DNA probe for the identification of L. helveticus strains.     

Lateral dimerization is required for the homophilic binding activity of C-cadherin

Regulation of cadherin-mediated adhesion can occur rapidly at the cell surface. To understand the mechanism underlying cadherin regulation, it is essential to elucidate the homophilic binding mechanism that underlies all cadherin-mediated functions. Therefore, we have investigated the structural and functional properties of the extracellular segment of Xenopus C-cadherin using a purified, recombinant protein (CEC 1-5). CEC 1-5 supported adhesion of CHO cells expressing C-cadherin. The extracellular segment was also capable of mediating aggregation of microspheres. Chemical cross-linking and gel filtration revealed that CEC 1-5 formed dimers in the presence as well as absence of calcium. Analysis of the functional activity of purified dimers and monomers demonstrated that dimers retained substantially greater homophilic binding activity than monomers. These results demonstrate that lateral dimerization is necessary for homophilic binding between cadherin extracellular segments and suggest multiple potential mechanisms for the regulation of cadherin activity. Since the extracellular segment alone possessed significant homophilic binding activity, the adhesive activity of the extracellular segment in a cellular context was analyzed. The adhesion of CHO cells expressing a truncated version of C-cadherin lacking the cytoplasmic tail was compared to cells expressing the wild-type C-cadherin using a laminar flow assay on substrates coated with CEC 1-5. CHO cells expressing the truncated C-cadherin were able to attach to CEC 1-5 and to resist detachment by low shear forces, demonstrating that tailless C-cadherin can mediate basic, weak adhesion of CHO cells. However, cells expressing the truncated C-cadherin did not exhibit the complete adhesive activity of cells expressing wild-type C-cadherin. Cells expressing wild-type C-cadherin remained attached to CEC 1-5 at high shear forces, while cells expressing the tailless C-cadherin did not adhere well at high shear forces. These results suggest that there may be two states of cadherin-mediated adhesion. The first, relatively weak state can be mediated through interactions between the extracellular segments alone. The second strong adhesive state is critically dependent on the cytoplasmic tail.