Effects of functional group changes in the EcoRI recognition site on the cleavage reaction catalyzed by the endonuclease.

Oligodeoxynucleotides have been prepared that contain changes in the functional group pattern present in the EcoRI recognition site. These changes involve "functional group deletions", "functional group reversals", and "displaced functional groups". Steady-state kinetic parameters have been used to characterize the interaction of these modified recognition sites with the EcoRI endonuclease. Changes in the functional group pattern have varying effects upon the cleavage reaction. Both the exocyclic amino groups of the two adenine residues and the methyl groups of the thymine residues appear to interact with the endonuclease quite differently. In both cases efficient catalysis was observed when these functional groups were present at the "outer" dA-dT base pair. Selectivity was decreased by over an order of magnitude largely via increases in Km when these functional groups were deleted. Similar modifications at the "inner" dA-dT base pair did not alter the kinetic parameters significantly from those observed with the native sequence. Addition of an amino group to the minor groove at the outer dA-dT base pair resulted in a modified recognition site that interacted with the enzyme, on the basis of observed competitive inhibition kinetics, but was not cleaved.

Anticodon loop of tRNAPhe: structure, dynamics, and Mg2+ binding.

The structure, dynamics, and Mg2+ binding reactions of the isolated anticodon hairpin loop from tRNAPhe (yeast) have been analyzed by fluorescence-detected temperature-jump relaxation, melting experiments, and equilibrium sedimentation. Most of the measurements were performed at an ionic strength of 0.15 M and at temperatures below 25 degrees C, where the hairpin loop proved to be stable. A relaxation effect with a time constant of approximately 100 microseconds, indicated by the Wye base fluorescence, is attributed to a conformational change of the anticodon loop and is very similar to a corresponding transition observed previously for the whole tRNAPhe molecule. A Mg2+ binding site reflected by an inner-sphere relaxation process and associated with a strong increase of the Wye base fluorescence closely resembles a corresponding site observed in the complete tRNAPhe and is attributed to a site in the anticodon loop identified by X-ray analysis. In addition to the Mg2+ site in the loop, which is associated with a binding constant of 2 X 10(3) M-1, the existence of sites with a higher affinity is demonstrated by an unusual relaxation effect, showing a minimum in the reciprocal time constant with increasing Mg2+ concentration. The experimental data can be described by a transition between two states and Mg2+ binding to both states resulting in a reaction cycle, which is extended by an additional Mg2+ binding reaction to one of the states. The unusual effect has not been observed for the complete tRNAPhe and is also not observed when Ca2+ is added instead of Mg2+. This result indicates the existence of a conformational change involving Mg2+ inner-sphere complexation.(ABSTRACT TRUNCATED AT 250 WORDS)

Donor activation in the T4 RNA ligase reaction.

T4 RNA ligase catalyzes the adenylation of donor oligonucleotide substrates. These activated intermediates react with an acceptor oligonucleotide which results in phosphodiester bond formation and the concomitant release of AMP. Adenylation of the four common nucleoside 3',5'-bisphosphates as catalyzed by T4 RNA ligase in the absence of an acceptor oligonucleotide has been examined. The extents of product formation indicate that pCp is the best substrate in the reaction and pGp is the poorest. Kinetic parameters for the joining reaction between the preadenylated nucleoside 3',5'-bisphosphates, A(5')pp(5')Cp or A(5')pp(5')Gp, and a good acceptor substrate (ApApA) or a poor acceptor substrate (UpUpU) have been determined. The apparent Km values for both preadenylated donors in the joining reaction are similar, and the reaction velocity is much faster than observed in the overall joining reaction. The nonnucleotide adenylated substrate P1-(5'-adenosyl) P2-(o-nitrobenzyl) diphosphate also exhibits a similar apparent Km but reacts with a velocity 80-fold slower than the adenylated nucleoside 3',5'-bisphosphates. By use of preadenylated donors, oligonucleotide substrates can be elongated more efficiently than occurs with the nucleoside 3',5'-bisphosphates.

Yeast tRNAAsp: codon and wobble codon-anticodon interactions. A transferred nuclear Overhauser enhancement study.

The conformations of the ribotrinucleoside bisphosphates GpApC and GpApU, the codon and wobble codon for aspartic acid respectively, bound to yeast tRNAAsp in solution, have been examined by means of time-dependent transferred nuclear Overhauser enhancement measurements to determine distances between bound ligand protons. The conformations of the two bound ribotrinucleoside bisphosphates are shown to be very similar with an overall root-mean-square difference in interproton distances of 0.03 nm. The ribose conformations of all the residues are 3'-endo; the glycosidic bond torsion angles of the A and C residues of GpApC and of the A and U residues of GpApU are in the low anti range. These features are typical of an A-RNA type structure. In contrast, the G residue of both GpApC and GpApU exists as a mixture of syn and anti conformations. The overall conformation of the two bound ribotrinucleoside bisphosphates is also similar to A-RNA and the stability of the complexes is enhanced by extensive base-base stacking interactions. In addition, it is shown that the binding of the codon GpApC to tRNAAsp induces self-association into a multicomplex system consisting of four GpApC-tRNAAsp complexes, whereas the wobble codon GpApU fails to induce any observable self-association.

The solution structure of a RNA pentadecamer comprising the anticodon loop and stem of yeast tRNAPhe. A 500 MHz 1H-n.m.r. study.

A 500 MHz 1H-n.m.r. study on the semi-synthetic RNA pentadecamer 5'-r(C-A-G-A-Cm-U-Gm-A-A-Y-A-psi-m5C-U-G) comprising the anticodon loop and stem (residues 28-42) of yeast tRNAPhe is presented. By using pre-steady-state nuclear-Overhauser-effect measurements all exchangeable and non-exchangeable base proton resonances, all H1' ribose resonances and all methyl proton resonances are assigned and over 70 intra- and inter-nucleotide interproton distances determined. From the distance data the solution structure of the pentadecamer is solved by model-building. It is shown that the pentadecamer adopts a hairpin-loop structure in solution with the loop in a 3'-stacked conformation. This structure is both qualitatively and quantitatively remarkably similar to that of the anticodon loop and stem found in the crystal structures of tRNAPhe with an overall root-mean-square difference of 0.12 nm between the interproton distances determined by n.m.r. and X-ray crystallography. The hairpin-loop solution structure of the pentadecamer is very stable with a 'melting' temperature of 53 degrees C in 500 mM-KCl, and the structural features responsible for this high stability are discussed. Interaction of the pentadecamer with the ribotrinucleoside diphosphate UpUpC, one of the codons for the amino acid phenylalanine, results only in minor perturbations in the structure of the pentadecamer, and the 3'-stacked conformation of the loop is preserved. The stability of the pentadecamer-UpUpC complex (K approximately 2.5 X 10(4) M-1 at 0 degrees C) is approximately an order of magnitude greater than that of the tRNAPhe-UpUpC complex.

tRNA separation by high-performance liquid chromatography using an aggregate of ODS-Hypersil and trioctylmethylammonium chloride.

High-performance liquid chromatography on a reversed-phase support treated with a tetraalkylammonium salt was used to separate tRNAs from baker's yeast. While resolution by this column appears to result from both anion-exchange and reversed-phase chromatography, it is the hydrophobic interactions which govern the separation of one tRNA from another. Chromatography of bulk tRNA resulted in a number of fractions with different amino acid acceptor activities and little cross-contamination. In some cases the column resolved several single nucleotide modifications of tRNAPhe. Using a 250 x 6.2 mm column it has been possible to chromatograph a minimum of 100 A260 units of tRNA without serious loss in resolution. tRNAs isolated from this column as the last step of a purification procedure have very high amino acid acceptor activities.

Role of the 5'-terminal phosphate of tRNA for its function during protein biosynthesis elongation cycle.

The 5'-terminal phosphate of tRNAPhe from yeast was removed using tRNAPhe lacking its 3'-terminal adenosine. After regeneration of the C-C-A terminus this tRNA was investigated in following reactions: aminoacylation, spontaneous hydrolysis of the amino acid from aminoacyl-tRNA, aminoacyl-tRNA.EF-Tu.GTP ternary complex formation and poly(U)-dependent synthesis of poly(Phe). The absence of the 5'-terminal phosphate of Phe-tRNAPhe does not influence the rate of hydrolysis of the amino acid or the ability of this rRNA to participate in complex formation with EF-Tu.GTP. The translation of the polyuridylic acid is slightly inhibited whereas the rate and extent of the enzymatic aminoacylation is not affected.