pH-dependent conformational flexibility within the ribosomal peptidyl transferase center.

A universally conserved adenosine, A2451, within the ribosomal peptidyl transferase center has been proposed to act as a general acid-base catalyst during peptide bond formation. Evidence in support of this proposal came from pH-dependent dimethylsulfate (DMS) modification within Escherichia coli ribosomes. A2451 displayed reactivity consistent with an apparent acidity constant (pKa) near neutrality, though pH-dependent structural flexibility could not be rigorously excluded as an explanation for the enhanced reactivity at high pH. Here we present three independent lines of evidence in support of the alternative interpretation. First, A2451 in ribosomes from the archaebacteria Haloarcula marismortui displays an inverted pH profile that is inconsistent with proton-mediated base protection. Second, in ribosomes from the yeast Saccharomyces cerevisiae, C2452 rather than A2451 is modified in a pH-dependent manner. Third, within E. coli ribosomes, the position of A2451 modification (N1 or N3 imino group) was analyzed by testing for a Dimroth rearrangement of the N1-methylated base. The data are more consistent with DMS modification of the A2451 N1, a functional group that, according to the 50S ribosomal crystal structure, is solvent inaccessible without structural rearrangement. It therefore appears that pH-dependent DMS modification of A2451 does not provide evidence either for or against a general acid-base mechanism of protein synthesis. Instead the data suggest that there is pH-dependent conformational flexibility within the peptidyl transferase center, the exact nature and physiological relevance of which is not known.

Phenanthroline-Cu(II) cleavage as a probe of rRNA structure.

Chemical cleavage is developing into a powerful tool for analysis and characterization of nucleic acids. Phenanthroline-Cu(II) cleavage has been used extensively for studies of DNA for the last two decades, but recently has been applied to structural studies of RNA as well. This approach has been used to study the structure and structural changes occurring in ribosomal RNA within the ribosomes. In this article we discuss the mechanism by which phenanthroline cleaves, the applications possible using this approach, and the results that can be obtained. Protocols for use of phenanthroline are outlined as well.

A single adenosine with a neutral pKa in the ribosomal peptidyl transferase center.

Biochemical and crystallographic evidence suggests that 23S ribosomal RNA (rRNA) is the catalyst of peptide bond formation. To explore the mechanism of this reaction, we screened for nucleotides in Escherichia coli 23S rRNA that may have a perturbed pKa (where Ka is the acid constant) based on the pH dependence of dimethylsulfate modification. A single universally conserved A (number 2451) within the central loop of domain V has a near neutral pKa of 7.6 +/- 0.2, which is about the same as that reported for the peptidyl transferase reaction. In vivo mutational analysis of this nucleotide indicates that it has an essential role in ribosomal function. These results are consistent with a mechanism wherein the nucleotide base of A2451 serves as a general acid base during peptide bond formation.

Using a targeted chemical nuclease to elucidate conformational changes in the E. coli 30S ribosomal subunit.

Determining the detailed tertiary structure of 16S rRNA within 30S ribosomal subunits remains a challenging problem. The particular structure of the RNA which allows tRNA to effectively interact with the associated mRNA during protein synthesis remains particularly ambiguous. This study utilizes a chemical nuclease, 1, 10-o-phenanthroline-copper, to localize regions of 16S rRNA proximal to the decoding region under conditions in which tRNA does not readily associate with the 30S subunit (inactive conformation), and under conditions which optimize tRNA binding (active conformation). By covalently attaching 1,10-phenanthroline-copper to a DNA oligomer complementary to nucleotides in the decoding region (1396-1403), we have determined that nucleotides 923-929, 1391-1396, and 1190-1192 are within approximately 15 A of the nucleotide base-paired to nucleotide 1403 in inactive subunits, but in active subunits only cleavages (1404-1405) immediately proximal to the 5' end of the hybridized probe remain. These results provide evidence for dynamic movement in the 30S ribosomal subunit, reported for the first time using a targeted chemical nuclease.

Positions in the 30S ribosomal subunit proximal to the 790 loop as determined by phenanthroline cleavage.

Positioning rRNA within the ribosome remains a challenging problem. Such positioning is critical to understanding ribosome function, as various rRNA regions interact to form suitable binding sites for ligands, such as tRNA and mRNA. We have used phenanthroline, a chemical nuclease, as a proximity probe, to help elucidate the regions of rRNA that are near neighbors of the stem-loop structure centering at nt 790 in the 16S rRNA of the Escherichia coli 30S ribosomal subunit. Using phenanthroline covalently attached to a DNA oligomer complementary to nt 787-795, we found that nt 582-584, 693-694, 787-790, and 795-797 were cleaved robustly and must lie within about 15 A of the tethered site at the 5' end of the DNA oligomer, which is adjacent to nt 795 of 16S rRNA.

Cleavage of a 23S rRNA pseudoknot by phenanthroline-Cu(II).

Studying the intricate folding of rRNA within the ribosome remains a complex problem. Phenanthroline-Cu(II) complexes cleave phosphodiester bonds in rRNA in specific regions, apparently especially where the rRNA structure is constrained in some fashion. We have introduced phenanthroline-copper complexes into 50S Escherichia coli ribosomal subunits and shown specific cleavages in the regions containing nucleotides 60-66 and 87-100. This specificity of cleavage is reduced when the ribosome is heated to 80 degrees C and reduced to background when the ribosomal proteins are extracted and the cleavage repeated on protein-free 23S rRNA. It has been suggested that nucleotides 60-66 and 87-95 in E.coli 23S rRNA are involved in a putative pseudoknot structure, which is supported by covariance data. The paired cleavages of nearly equal intensity of these two regions, when in the ribosome, may further support the existence of a pseudoknot structure in the 100 region of 23S rRNA.

The binding interaction of Coomassie blue with proteins.

The Coomassie brilliant blue protein assay is commonly used because of its sensitivity and convenience, but it is not well understood on a molecular level. This study attempts to gain better understanding of the assay system through spectrophotometric binding studies carried out on selected proteins under solvent conditions characteristic of the normal protein assay. The studies were generally conducted at high protein/dye concentration ratios, where only the high-affinity dye binding sites would be occupied. Modified Scatchard and Hill analyses show that these high-affinity sites are few in number compared to the total number of dye-binding sites on a given protein. The magnitudes of the high-affinity binding constants are typical of noncovalent binding interactions.