Electron microscopy of tRNA crystals. II. 4 A resolution diffraction pattern and substantial stability to radiation damage.

Electron microscopy was applied to thin crystals of yeast tRNAPhe. The crystals embedded in glucose yield Bragg reflections with a spacing smaller than 4 A. The measurement of radiation damage rate demonstrates that they are 4 to 14 times less susceptible to electron exposures than protein crystals embedded in glucose.

Directly photocrosslinked nucleotides joining transfer RNA to aminoacyl-tRNA synthetase in methionine and tyrosine systems.

We have used ultraviolet photocrosslinking and 32P post-labeling to help define the contact surface between transfer RNAs and aminoacyl-tRNA synthetases for the methionine and tyrosine systems. Photocrosslinking between tRNAs and synthetases is shown to occur only in cognate complexes. The increased sensitivity of our procedures reduces the amounts of interacting macromolecules and permits lower ultraviolet light doses, thereby minimizing radiation damage. These procedures have detected crosslinks only within the 3'-terminal RNase T1 fragments in yeast tRNAMeti and Escherichia coli tRNATyr2; and although the photoadducts were unstable, we have identified the crosslinked nucleotides. These crosslinks occur at positions C74 and A76 in yeast tRNAMeti and position U64 in E. coli tRNATyr1&2 (conventional tRNA numbering system of Gauss & Sprinzl, 1981). This work demonstrates that even labile photocrosslinks can be exploited for mapping crosslinked nucleotides.

Formation and properties of a covalent complex between elongation factor Tu and Phe-tRNA bearing a photoaffinity probe on its 3-(3-amino-3-carboxypropyl)uridine residue.

Escherichia coli Phe-tRNA, modified with the photoaffinity reagent 6-(2-nitro-4-azidophenylamino)caproate on the 3-(3-amino-3-carboxypropyl)uridine residue, was crosslinked to E. coli EFTu Section upon irradiation at 0 degree C with visible light at wavelengths greater than 400 nm. Crosslinking was dependent on irradiation, the photoaffinity probe, and was blocked by pre-photolysis. 1 mM-dithiothreitol completely quenched crosslinking. Binding of the tRNA to EFTu was a prerequisite for crosslinking, because neither EFTu . GDP nor AcPhe-tRNA could substitute; EFTu . GDPCP, however, was almost as active as EFTu . GTP. Crosslinking was complete in less than five minutes and was stable to at least 20 minutes of irradiation with a single 650 W tungsten lamp 4 cm away. The crosslinking yield ranged from 15% to 25%. The crosslinked complex possessed several remarkable properties. At 0.5 mM-Mg2+, the complex protected the AA-tRNA link to chemical hydrolysis, stabilized the bound GTP to dissociation or exchange, and was not adsorbed to cellulose nitrate filters. The purified crosslinked complex could be bound to ribosomes with concomitant hydrolysis of GTP. Extensive peptide bond formation with AcPhe-tRNA in the P site occurred despite the presence of the crosslinked EFTu. We conclude that hydrolysis of GTP is sufficient to release the 3' end of the Phe-tRNA from complexation with EFTu. Translocation of the A site bound complex did not occur. The crosslink site on EFTu is probably near the periphery of the molecule, because shortening the probe from 20 A to 14 A completely blocked crosslinking. A similar but shorter 8 A probe, p-azidophenacyl-4-thiouridine located on the opposite face of the tRNA, did not crosslink.

Nucleotide residues of tRNA, directly interacting with proteins within the complex of the 30 S subunit of E. coli ribosome with poly(U) and NAcPhe-tRNA(Phe).

With the aid of photoinduced tRNA-protein cross-linking, nucleotide residues A21, U45 and U60 were shown to interact directly with proteins S5, S7 and S9 respectively, in the complex of the 30 S subunit of E. coli ribosome with poly(U) and NAcPhe-tRNA(Phe). These nucleotide residues are located in the central part of the L-form in the tertiary structure of RNA.

Photocrosslinking of thiolated aminoacyl-tRNA to ribosomal RNA and proteins.

tRNA has been converted to a form that can be photoactivated by chemical modification of some of the exposed cytidine residues to thio-4-uridine A certain percentage of the modified molecules can be charged and bound to the ribosome; thiolated fMet-tRNAfMet is bound to the P-site as shown by puromycin reactivity. Near the UV irradiation produces covalent crosslinks between total thiolated AA-tRNA or fMet-tRNAfMet and the ribosome. AA-tRNA becomes crosslinked to both 30S and 50S subunits but fMet-tRNAfMet to 50S subunits alone. In each case, crosslinking of tRNA was found to be not only to ribosomal proteins, but also to rRNA. The covalent complexes appear sufficiently stable to allow identification of the proteins or rRNA sequences involved.

[Photoaffinity modification of Escherichia coli ribosomes by fMet-tRNAf Met derivatives in the 70S initiation complex]. / Issledovanie fotoaffinnoi modifikatsii ribosom Escherichia coli proizvodnymi fMet-tRNKf Met v sostave 70S kompleksa initsiatsii.

Photoaffinity labeling of E. coli ribosomes within the 70S initiation complex was studied by using photoreactive derivatives of fMet-tRNAfMet bearing arylazidogroups scattered statistically over guanosine residues. It is shown that fMet-azido-tRNAfMet-II bearing 2 moles of the reagent residues per mole of tRNA (modified in the conditions of stability of tRNA tertiary structure) is fully active in aminoacylation and in the factor-dependent binding with ribosomes to form the 70S initiation complex. Functional activity of fMet-azido-tRNAfMet-I bearing also 2 moles of the reagent residues per mole of tRNA (but modified in conditions of lability of tRNA tertiary structure) decreases up to approximately 45% in aminoacylation and up to 70% in IF-2 X GTP-dependent binding to the ribosomes. Irradiation of complexes 70S ribosome-MS2-RNA-fMet-azido-tRNAfMet results in covalent linking of the tRNA derivative to the ribosomes. Both subunits are labeled, the 30S to a larger extent than 50S. It is shown that fMet-azido-tRNAfMet-II labels proteins S1, S7, S9, L27 whereas fMet-azido-tRNAfMet-1--proteins S1, S3, S5, S9, S14, L1, L2, L7/L12.

Photoreaction of 8-methoxypsoralen with yeast-tRNAPhe. Identification of the major reaction sites.

Yeast tRNAPhe was photoreacted with [3H]8-methoxypsoralen and the product was digested with ribonuclease T1, ribonuclease A or a combination of the two or cleaved with sodium borohydride/aniline. The oligonucleotides from these digestions were analyzed by polyacrylamide gel electrophoresis or high-pressure liquid chromatography and the psoralen-containing fragments were identified. The results indicate that one major and two minor photoreaction sites for 8-methoxypsoralen exist in yeast tRNAPhe. The major site (containing about 55% of the label) was determined as U50 in the T psi arm of the tRNA molecule while the minor sites were assigned to U59 (30% of the label) and C70 (15%) respectively. Our results suggest that psoralens may be used as photoprobes for studying conformational changes in tRNA molecules.

Photochemical cross-linking of tRNA1Arg to the 30S ribosomal subunit using aryl azide reagents attached to the anticodon loop.

The 2-thiocytidine residue at position 32 of tRNA1Arg from Escherichia coli was modified specifically with three photoaffinity reagents of different lengths, and the corresponding N-acetylarginyl-tRNA1Arg derivatives were cross-linked to the P site of E. coli 70S ribosomes by irradiation. Covalent attachment was dependent upon the presence of a polynucleotide template and exposure to light of the appropriate wavelength. From 4% to 6% of the noncovalently bound tRNA became cross-linked to the ribosome as a result of photolysis, and attachment to the P site was confirmed by the reactivity of arginine in the covalent complexes toward puromycin. Analysis of the irradiated ribosomes by sucrose-gradient sedimentation at low Mg2+ concentration revealed that the tRNA was associated exclusively with the 30S subunit in all cases. Two of the N-acetylarginyl-tRNA1Arg derivatives were attached primarily to ribosomal proteins whereas the third was cross-linked mainly to 16S RNA. Partial RNase digestion of the latter complex demonstrated that the tRNA had become attached to the 3' third of the rRNA molecule. In addition, the tRNA-rRNA bond was shown to be susceptible to cleavage by hydroxylamine and mercaptoethanol.

tRNAPhe and tRNAPro are the near-ultraviolet molecular targets triggering the growth delay effect.

The illumination of Escherichia coli cells with UVA light, 320 nm less than or equal to lambda less than or equal to 380 nm, triggers a transient growth and division delay. The built-in 4-thiouridine chromophore which absorbs light at 340 nm leads to the quantitative 8-13 crosslinking of a number of tRNA species corresponding to 50% of the bulk tRNA molecules. Determination of the tRNA acylation level by the various aminoacids shows that only the tRNA species acylated by Phe and Pro are strikingly affected in vivo. Both acylation levels decrease to less than 10% of their initial value during the illumination period, remain stable all along the growth lag and increase concomitantly with cell mass when growth resumes. Hence tRNA(Phe) and tRNA(Pro) are the UVA light molecular targets triggering growth delay and related effects of biological significance such as cell volume reduction, photoprotection and protection against UV mutagenesis (antiphotomutagenesis).