Photoaffinity labeling of Escherichia coli ribosomes by an aryl azide analogue of puromycin. Evidence for the functional site specificity of labeling

The photoincorporation of p-azido[3H]puromycin [6-(dimethylamino)-9-[3'-deoxy-3'-[(p-azido-L-phenylalanyl)amino]-beta-D-ribofuranosyl]purine] into specific ribosomal proteins and ribosomal RNA [Nicholson, A. W., Hall, C. C., Strycharz, W. A., & Cooperman, B. S. (1982) Biochemistry (preceding paper in this issue)] is decreased in the presence of puromycin, thus demonstrating that labeling is site specific. The magnitudes of the decreases in incorporation into the major labeled 50S proteins found on addition of different potential ribosome ligands parallel the abilities of these same ligands to inhibit peptidyltransferase. This result provides evidence that p-azidopuromycin photoincorporation into these proteins occurs at the peptidyltransferase center of the 50S subunit, a conclusion supported by other studies of ribosome structure and function. A striking new finding of this work is that puromycin aminonucleoside is a competitive inhibitor of puromycin in peptidyltransferase. The photoincorporation of p-azidopuromycin is accompanied by loss of ribosomal function, but photoincorporated p-azidopuromycin is not a competent peptidyl acceptor. The significance of these results is discussed. Photolabeling of 30S proteins by p-azidopuromycin apparently takes place from sites of lower puromycin affinity than that of the 50S site. The possible relationship of the major proteins labeled, S18, S7, and S14, to tRNA binding is considered.     

Localization of sites of photoaffinity labeling of the large subunit of Escherichia coli ribosomes by arylazide derivative of puromycin

Previous work (Nicholson, A. W., Hall, C. C., Strycharz, W. A., and Cooperman, B. S. (1982) Biochemistry 21, 3797-3808) showed that [3H]p-azidopuromycin photoaffinity labeled 70 S Escherichia coli ribosomes and that photoincorporation into 50 S subunit proteins was in the order L23 greater than L18/22 greater than L15. In the present work we report on immunoelectron microscopic studies of the complexes formed by p-azidopuromycin-modified 50 S subunits with antibodies to the N6,N6-dimethyladenosine moiety of the antibiotic. The p-azidopuromycin-modified 50 S subunits appear to be identical to unmodified control subunits in electron micrographs. Complexes of modified subunits with antibodies to the N6,N6-dimethyladenosine moiety of p-azidopuromycin were visualized in micrographs. Individual subunits with a single bound antibody (monomeric complexes) and pairs of subunits cross-linked by a single antibody (dimeric complexes) were separately evaluated and showed similar results. Two regions of p-azidopuromycin photoincorporation were identified. The primary site, seen in about 75% of the complexes, is between the central protuberance and small projection, on the side away from the L7/L12 arm, in a region thought to contain the peptidyltransferase center. The secondary site, of unknown significance, is at the base of the subunit maximally distant from the arm. These placements are essentially identical to those we observed in analyses of puromycin photoincorporation (Olson, H. M., Grant, P. G., Cooperman, B. S., and Glitz, D. G. (1982) J. Biol. Chem. 257, 2649-2656) and quantitatively similar to evaluations of monomeric puromycin-50 S subunit complexes. The data support the placement of proteins L23, L18/22, and L15 at or near the peptidyltransferase center at the primary site and suggest, in addition, that the secondary site includes a genuine area of puromycin affinity.     

On the structural specificity of puromycin binding to Escherichia coli ribosomes

We have examined the structural specificity of the puromycin binding sites on the Escherichia coli ribosome that we have previously identified [Nicholson, A. W., Hall, C. C., Strycharz, W. A., & Cooperman, B. S. (1982) Biochemistry 19, 3809-3817, and references cited therein] by examining the interactions of a series of adenine-containing compounds with these sites. We have used as measures of such interactions the inhibition of [3H]puromycin photoincorporation into ribosomal proteins from these sites, the site-specific photoincorporation of the 3H-labeled compounds themselves, and the inhibition of peptidyl transferase activity. For the first two of these measures we have made extensive use of a recently developed high-performance liquid chromatography (HPLC) method for ribosomal protein separation [Kerlavage, A. R., Weitzmann, C., Hasan, T., & Cooperman, B.S. (1983) J. Chromatogr. 266, 225-237]. We find that puromycin aminonucleoside (PANS) contains all of the structural elements necessary for specific binding to the three major puromycin binding sites, those of higher affinity leading to photoincorporation into L23 and S14 and that of lower affinity leading to photoincorporation into S7. Although tight binding to the L23 and S7 sites requires both the N6,N6-dimethyl and 3'-amino groups within PANS, only the N6,N6-dimethyl group and not the 3'-amino group is required for binding to the S14 site. Our current results reinforce our previous conclusion that photoincorporation into L23 takes place from the A' site within the peptidyl transferase center and lead us to speculate that the S14 site might be specific for the binding of modified nucleosides. They also force the conclusion that puromycin photoincorporation proceeds through its adenosyl moiety.     

Reconstitution of Escherichia coli 50S ribosomal subunits containing puromycin-modified L23: functional consequences

In previous work we have shown that both puromycin [Weitzmann, C. J., & Cooperman, B. S. (1985) Biochemistry 24, 2268-2274] and p-azidopuromycin [Nicholson, A. W., Hall, C. C., Strycharz, W. A., & Coooperman, B. S. (1982) Biochemistry 21, 3809-3817] site specifically photoaffinity label protein L23 to the highest extent of any Escherichia coli ribosomal protein. In this work we demonstrate that L23 that has been photoaffinity labeled within a 70S ribosome by puromycin (puromycin-L23) can be separated from unmodified L23 by reverse-phase high-performance liquid chromatography (RP-HPLC) and further that puromycin-L23 can reconstitute into 50S subunits when added in place of unmodified L23 to a reconstitution mixture containing the other 50S components in unmodified form. We have achieved a maximum incorporation of 0.5 puromycin-L23 per reconstituted 50S subunit. As compared with reconstituted 50S subunits either containing unmodified L23 or lacking L23, reconstituted 50S subunits containing 0.4-0.5 puromycin-L23 retain virtually all (albeit low) peptidyl transferase activity but only 50-60% of mRNA-dependent tRNA binding stimulation activity. We conclude that although L23 is not directly at the peptidyl transferase center, it is sufficiently close that puromycin-L23 can interfere with tRNA binding. This conclusion is consistent with a number of other experiments placing L23 close to the peptidyl transferase center but is difficult to reconcile with immunoelectron microscopy results placing L23 near the base of the 50S subunit on the side facing away from the 30S subunit [Hackl, W., & St?ffler-Meilicke, M. (1988) Eur. J. Biochem. 174, 431-435].     

Reconstitution of Escherichia coli ribosomes containing puromycin-modified S14: functional effects of the photoaffinity labeling of a protein essential for tRNA binding

In previous work we have shown that puromycin photoaffinity labels two proteins, L23 and S14, from separate sites of high affinity on Escherichia coli ribosomes [Jaynes, E. N., Jr., Grant, P. G., Giangrande, G., Wieder, R., & Cooperman, B. S. (1978) Biochemistry 17, 561-569; Weitzmann, C. J., & Cooperman, B. S. (1985) Biochemistry 24, 2268-2274], that puromycin-modified S14 is separable from native S14 by reverse-phase high-performance liquid chromatography (RP-HPLC), and that ribosomal proteins prepared by RP-HPLC can be reconstituted into active 30S subunits [Kerlavage, A. R., Weitzmann, C. J., & Cooperman, B. S. (1984) J. Chromatogr. 317, 201-212]. In this work we definitively identify puromycin-modified S14 by tryptic fingerprinting, an analysis that also provides evidence that the single tryptophan-containing peptide in S14 is the site of puromycin photoincorporation. We show that reconstituted 30S subunits, in which all of the S14 present is stoichiometrically modified with puromycin and all other ribosomal components are present in unmodified form, lack Phe-tRNAPhe binding activity and further that 70S ribosomes containing such reconstituted 30S subunits have substantially diminished binding activity to both the A and P sites, as differentiated through use of tetracycline. Suitable control experiments strongly indicate that this loss of activity is a direct consequence of puromycin photoincorporation.     

Antibiotic effects on the photoinduced affinity labeling of Escherichia coli ribosomes by puromycin.

The effect of ribosomal antibiotics on the photoinduced affinity labeling of Escherichia coli ribosomes by puromycin [Cooperman, B.S., Jaynes, E.N., Brunswick, D.J., & Luddy, M.A. (1975) Proc. Natl. Acad. Sci. U.S.A. 72, 1974; Jaynes, E.N. Jr., Grant, P.G., Giangrande, G., Wieder, R., & Cooperman, B.S. (1978) Biochemistry 17, 561] has been studied. Although blasticidin S, sparsomycin, lincomycin, and erythromycin are essentially without effect, major changes are seen on addition of either chloramphenicol or tetracycline. The products of photoincorporation have been characterized by one- and two-dimensional gel electrophoresis and by specific immunoprecipitation with antibodies to ribosomal proteins. In the presence of chloramphenicol, protein S14 becomes the major labeled protein. In the presence of tetracycline, L23 remains the major labeled protein, but the yield of labeled ribosomes is enormously increased, and the labeling is more specific for L23. These results are discussed in terms of the known modes of action of these antibiotics and the photoreactivity of tetracycline.     

Single protein omission reconstitution studies of tetracycline binding to the 30S subunit of Escherichia coli ribosomes

In previous work we showed that on photolysis of Escherichia coli ribosomes in the presence of [3H]tetracycline (TC) the major protein labeled is S7, and we presented strong evidence that such labeling takes place from a high-affinity site related to the inhibitory action of TC [Goldman, R. A., Hasan, T., Hall, C. C., Strycharz, W. A., & Cooperman, B. S. (1983) Biochemistry 22, 359-368]. In this work we use single protein omission reconstitution (SPORE) experiments to identify those proteins that are important for high-affinity TC binding to the 30S subunit, as measured by both cosedimentation and filter binding assays. With respect to both sedimentation coefficients and relative Phe-tRNAPhe binding, the properties of the SPORE particles we obtain parallel very closely those measured earlier [Nomura, M., Mizushima, S., Ozaki, M., Traub, P., & Lowry, C. V. (1969) Cold Spring Harbor Symp. Quant. Biol. 34, 49-61], with the exception of the SPORE particle lacking S13. A total of five proteins, S3, S7, S8, S14, and S19, are shown to be important for TC binding, with the largest effects seen on omission of proteins S7 and S14. Determination of the protein compositions of the corresponding SPORE particles demonstrates that the observed effects are, for the most part, directly attributable to the omission of the given protein rather than reflecting an indirect effect of omitting one protein on the uptake of another. A large body of evidence supports the notion that four of these proteins, S3, S7, S14, and S19, are included, along with 16S rRNA bases 920-1396, in one of the major domains of the 30S subunit.     

Mapping labeled sites in Escherichia coli ribosomal RNA: distribution of methyl groups and identification of a photoaffinity-labeled RNA region putatively at the peptidyltransferase center

We have developed a method for the rapid localization of sites of ribosomal RNA labeling to limited regions (approximately 200 bases). The method is based on the formation and polyacrylamide gel electrophoretic separation of hybrids between restriction fragments of rrnB DNA and isotopically labeled rRNA and the subsequent determination of radioactivity across the gel. Using [3H]adenine-labeled rRNA as a control sample, we optimized experimental conditions with respect to a number of variables, including rRNA:DNA stoichiometric ratio, temperature of the annealing step, and levels of nucleases. An important result is that different rRNA X DNA hybrid fragments are obtained in different yields. The method was then applied to analyses of C3H3-labeled rRNA, giving results in good accord with known and proposed sites of rRNA methylation, and of rRNA that has been photoaffinity-labeled with 5-azido-2-nitrobenzoyl-[3H]Phe-tRNAPhe, a probe directed toward the peptidyltransferase center. The latter study showed a single major site of RNA labeling, falling within bases 2445-2668 of 23S rRNA. The extent of labeling was shown to be dependent on light-induced formation of a reactive intermediate and to be decreased in the absence of poly(uridylic acid) or in the presence of puromycin. The location of this major site of labeling is consistent with recent results obtained with an analogous tRNA photoaffinity label [Barta, A., Steiner, G., Brosius, J., Noller, H. F., & Kuechler, E. (1984) Proc. Natl. Acad. Sci. U.S.A. 81, 3607-3611] and with related genetic and biochemical studies of antibiotic interaction with ribosomes suggesting that the peptidyltransferase center falls within region V (bases 2043-2625) of 23S rRNA.     

A photolabile oligodeoxyribonucleotide probe of the peptidyltransferase center: identification of neighboring ribosomal components

In this work we report the synthesis of a radioactive, photolabile oligodeoxyribonucleotide probe and its exploitation in identifying 50S ribosomal subunit components neighboring its target site in 23S rRNA. The probe is complementary to 23S rRNA nucleotides 2497-2505, a single-stranded sequence that has been shown to fall within the peptidyltransferase center of Escherichia coli ribosomes [Cooperman, B. S., Weitzmann, C. J., & Fernandez, C. L. (1990) in The Ribosome: Structure, Function, & Evolution (Hill, W. E., Dahlberg, A., Garrett, R. A., Moore, P. B., Schlesinger, D., & Warner, J. R., Eds.) pp 491-501, American Society of Microbiology, Washington]. On photolysis in the presence of 50S ribosomes, it site-specifically incorporates into protein L3 (identified by both SDS-PAGE and immunological methods) and into three separate 23S rRNA regions: specifically, nucleotides 2454; 2501, 2502, 2505, 2506; and 2583, 2584. These results provide clear evidence that G-2505 in 23S rRNA is within 24 A (the distance between G-2505 and the photogenerated nitrene) of protein L3 and of each of the nucleotides mentioned above and are of obvious importance in the construction of detailed three-dimensional models of ribosomal structure. The approach we present is general and can be applied to determining ribosomal components neighboring regions of rRNA that are susceptible to binding by complementary oligodeoxyribonucleotides, both in intact 30S and 50S subunits and in subunits at various stages of reconstitution.     

Identification of sites of 4'-(hydroxymethyl)-4,5',8-trimethylpsoralen cross-linking in Escherichia coli 23S ribosomal ribonucleic acid

The reagent 4'-(hydroxymethyl)-4,5',8-trimethylpsoralen (HMT) was used to cross-link 23S rRNA from Escherichia coli under 50S ribosomal subunit reconstitution conditions. Following partial digestion of the RNA with ribonuclease T1, two-dimensional diagonal electrophoresis in denaturing polyacrylamide gels was used to isolate fragments derived from the cross-linked sites. These fragments were analyzed by digestion with ribonucleases T1 and A and their positions in the 23S RNA sequence identified. Fragment a1 (positions 1325-1426) is cross-linked to a2 (positions 1574-1623); fragment b1 (positions 1700-1731) is cross-linked to b2 (positions 1732-1753); and a cross-link is formed within fragment c (or c') (positions 863-916). In the latter case, the cross-link was located precisely, linking residues C867 and U913. All three HMT-mediated cross-links are consistent with a proposed secondary structure model for 23S RNA [Noller, H. F., Kop, J., Wheaton, V., Brosius, J., Gutell, R. R., Kopylov, A. M., Dohme, F., Herr, W., Stahl, D. A., Gupta, R., & Woese, C. R. (1981) Nucleic Acids Res. 9, 6167-6189].     

Mechanism of ribosomal subunit association: oligodeoxynucleotides as probes.

From the kethoxal treatment data [Herr, W.; Chapman, N.M.; Noller, H.F. (1979) J. Mol. Biol. 130, 433-439] some regions of ribosomal RNAs are thought to be responsible for the association of 30S and 50S ribosomes of E. coli to form 70S ribosomes. In order to test this possibility about a dozen oligodeoxynucleotides complementary to the suspected regions of rRNAs were synthesised. Their association with ribosomes and naked rRNAs was tested by the gel filtration technique. In order to check the effects on the ribosomal subunit association or rRNA association either intact 30S and 50S ribosomes or naked 16S and 23S rRNAs were preincubated with the individual oligodeoxynucleotide and its effect was checked by density gradient centrifugation followed by UV absorbance monitoring. Some oligodeoxynucleotides interfered with either subunit association or 16S RNA and 23S RNA association, some with both. These data clearly indicate that RNA-RNA interaction plays the major role in ribosomal subunit association.     

Puromycin photoaffinity labels small- and large-subunit proteins at the A site of the Drosophila ribosome

[3H]Puromycin covalently incorporates into the protein and to a much lesser extent into the RNA components of Drosophila ribosomes in the presence of 254-nm light. The photoincorporation reaction takes place with a small number of large- (L2 and L17) and small- (S8 and S22) subunit proteins as determined by two-dimensional gel analysis. More quantitative one-dimensional gel results show that puromycin reacts with each of these proteins in a functional site specific manner. The small percentage of the total labeling that occurs with rRNA also appears to be site specific. The rRNA labeling arises from a puromycin-mediated cross-linking of ribosomal protein and rRNA. Ionic conditions shift the pattern of puromycin-labeled ribosomal proteins. These results suggest that puromycin can occupy two distinct sites on Drosophila 80S ribosomes. The pattern of ribosomal proteins labeled by puromycin is affected by the presence of other antibiotics such as emetine, anisomycin, and trichodermin.     

The hydrophobic photoreagent 3-(trifluoromethyl)-3-m-([125I] iodophenyl) diazirine is a novel noncompetitive antagonist of the nicotinic acetylcholine receptor

We have shown previously that the lipophilic photoreagent 3-(trifluoromethyl)3-m-([125I]iodophenyl)-diazirine ([125I]TID) photolabels all four subunits of the Torpedo nicotinic acetylcholine receptor (AChR) and that greater than 70% of this photoincorporation is inhibited by cholinergic agonists and some noncompetitive antagonists, including histrionicotoxin (HTX), but not phencyclidine (PCP; White, B.H., and Cohen, J.B. (1988) Biochemistry 27, 8741-8751). We have now examined the effects of nonradioactive TID on (a) AChR photoincorporation of [125I]TID, (b) AChR-mediated ion transport, and (c) AChR binding of several cholinergic ligands. We find that TID inhibits [125I]TID photoincorporation into the AChR to the same extent as carbamylcholine. The saturable component of [125I]TID photolabeling is half-maximal at 4 microM [125I]TID with 0.5 mol specifically incorporated per mol of AChR after 30 min photolysis with 60 microM [125I]TID. Repeated labeling of membranes at a fixed [125I]TID concentration gave results consistent with a maximal incorporation of one [125I]TID molecule per AChR. Nonradioactive TID also noncompetitively inhibits agonist-stimulated 22Na+ efflux from Torpedo vesicles with an IC50 of 1 microM. Furthermore, TID inhibits allosterically the binding of [3H]HTX, decreasing its affinity for the AChR 5-fold both in the presence and absence of agonist. In contrast, TID has little effect on [3H]PCP binding in the absence of agonist but completely inhibits it in the presence of agonist. TID enhances the cooperativity of [3H]nicotine binding. [125I]TID is thus a photoaffinity label for a novel noncompetitive antagonist binding site on the AChR that is linked allosterically to the binding sites of both agonists and other noncompetitive antagonists. The [125I]TID site is presumably located within the central pore of the AChR.     

Probing the conformation of 18S rRNA in yeast 40S ribosomal subunits with kethoxal

Yeast 40S ribosomal subunits have been reacted with kethoxal to probe the conformation of 18S rRNA. Over 130 oligonucleotides were isolated by diagonal electrophoresis and sequenced, allowing identification of 48 kethoxal-reactive sites in the 18S rRNA chain. These results generally support a secondary structure model for 18S rRNA derived from comparative sequence analysis. Significant reactivity at positions 1436 and 1439, in a region shown to be base paired by comparative analysis, lends support to the earlier suggestion [Chapman, N.M., & Noller, H.F. (1977) J. Mol. Biol 109, 131-149] that part of the 3'-major domain of 16S-like rRNAs may undergo a biologically significant conformational rearrangement. Modification of positions in 18S rRNA analogous to those previously found for Escherichia coli 16S rRNA argues for extensive structural homology between 30S and 40S ribosomal subunits, particularly in regions thought to be directly involved in translation.     

Nucleotide sequences of accessible regions of 23S RNA in 50S ribosomal subunits.

Nucleotide sequences around kethoxal-reactive guanine residues of 23S RNA in 50S ribosomal subunits have been determined. By use of the diagonal paper electrophoresis method )Noller, H.F. (1974), Biochemistry 13, 4694-4703), 41 ribonuclease T1 oligonucleotides, originating from about 25 sites, were identified and sequenced. These sites are single stranded and accessible in free 50S subunits, and are thus potential sites for interaction with functional ligands during protein synthesis. Examination of these sequences for potential intermolecular base-pairing reveals the following: (1) There are 19 possible complementary combinations between exposed sequences in 16S and 23S RNA containing more than 4 base pairs: 15 containing 5 base pairs and 4 containing 6 base pairs. Nine of these complementary combinations contain 16S RNA sequences which we have previously shown to be protected from kethoxall by 50S subunits (Chapman, N.M., and Noller, H.F. (1977), J. Mol. Biol. 109, 131-149). (2) One of the exposed sites in 23S RNA has a sequence which is complementary to the invariant GT psi CR sequence in tRNA.     

5 K extended X-ray absorption fine structure and 40 K 10-s resolved extended X-ray absorption fine structure studies of photolyzed carboxymyoglobin

A previous extended X-ray absorption fine structure (EXAFS) study of photolyzed carboxymyoglobin (MbCO) [Chance, B., Fischetti, R., & Powers, L. (1983) Biochemistry 22, 3820-3829; Powers, L., Sessler, J. L., Woolery, G. L., & Chance, B. (1984) Biochemistry 23, 5519-5523] has provoked much discussion on the heme structure of the photoproduct (MbCO). The EXAFS interpretation that the Fe-CO distance increases by no more than 0.05 A following photodissociation has been regarded as inconsistent with optical, infrared, and magnetic susceptibility studies [Fiamingo, F. G., & Alben, J. O. (1985) Biochemistry 24, 7964-7970; Sassaroli, M., & Rousseau, D. L. (1986) J. Biol. Chem. 261, 16292-16294]. The present experiment was performed with well-characterized dry film samples in which MbCO molecules were embedded in a poly(vinyl alcohol) matrix [Teng, T. Y., & Huang, H. W. (1986) Biochim. Biophys. Acta 874, 13-18]. The sample had a high protein concentration (12 mM) to yield adequate EXAFS signals but was very thin (40 micron) so that complete photolysis could be easily achieved by a single flash from a xenon lamp. Although the electronic state of MbCO resembles that of deoxymyoglobin (deoxy-Mb), direct comparison of EXAFS spectra indicates that structurally MbCO is much closer to MbCO than to deoxy-Mb.(ABSTRACT TRUNCATED AT 250 WORDS)     

Puromycin binding to the small subunit of Escherichia coli ribosomes. Localization of the antibiotic in subunits reconstituted with puromycin-modified components

Small (30 S) ribosomal subunits from Escherichia coli strain TPR 201 were photoaffinity-labeled with [3H]puromycin in the presence of chloramphenicol under conditions in which more than 1 mol of antibiotic was incorporated per mol of ribosomes. The subunits were than washed with 3 M NH4Cl to yield core particles and a split protein fraction; the split proteins were further fractionated with ammonium sulfate. Subunits were then reconstituted using one fraction (core, split proteins, or ammonium sulfate supernatant) from photoaffinity-modified subunits and other components from unmodified (control) subunits. The distribution of [3H]puromycin in ribosomal proteins was monitored by one-dimensional polyacrylamide gel electrophoresis, and the sites of puromycin binding were visualized by immunoelectron microscopy. Two areas of puromycin binding were identified. A high affinity puromycin site, found on the upper third of the subunit and distant from the platform, is identical to the primary site previously identified (Olson, H. M., Grant, P. G., Glitz, D. G., and Cooperman, B. S. (1980) Proc. Natl. Acad. Sci. U. S. A. 77, 890-894). Binding at this site is maximal in subunits reconstituted with high levels of puromycin-modified protein S14, and is decreased when unmodified S14 is incorporated. Because the percentage of antibody binding at the primary site always exceeds the percentage of puromycin label in protein S14, the primary site must include components other than S14. A secondary puromycin site of lower affinity is found on the subunit platform. This site is enriched in subunits reconstituted from puromycin-modified core particles and may include protein S7. Our results demonstrate the feasibility of localizing specifically modified components in reconstituted ribosomal subunits.     

Conservation of RNA sequence and cross-linking ability in ribosomes from a higher eukaryote: photochemical cross-linking of the anticodon of P site bound tRNA to the penultimate cytidine of the UACACACG sequence in Artemia salina 18S rRNA

The complex of Artemia salina ribosomes and Escherichia coli acetylvalyl-tRNA could be cross-linked by irradiation with near-UV light. Cross-linking required the presence of the codon GUU, GUA being ineffective. The acetylvalyl group could be released from the cross-linked tRNA by treatment with puromycin, demonstrating that cross-linking had occurred at the P site. This was true both for pGUU- and also for poly(U2,G)-dependent cross-linking. All of the cross-linking was to the 18S rRNA of the small ribosomal subunit. Photolysis of the cross-link at 254 nm occurred with the same kinetics as that for the known cyclobutane dimer between this tRNA and Escherichia coli 16S rRNA. T1 RNase digestion of the cross-linked tRNA yielded an oligonucleotide larger in molecular weight than any from un-cross-linked rRNA or tRNA or from a prephotolyzed complex. Extended electrophoresis showed this material to consist of two oligomers of similar mobility, a faster one-third component and a slower two-thirds component. Each oligomer yielded two components on 254-nm photolysis. The slower band from each was the tRNA T1 oligomer CACCUCCCUVACAAGp, which includes the anticodon. The faster band was the rRNA 9-mer UACACACCGp and its derivative UACACACUG. Unexpectedly, the dephosphorylated and slower moving 9-mer was derived from the faster moving dimer. Deamination of the penultimate C to U is probably due to cyclobutane dimer formation and was evidence for that nucleotide being the site of cross-linking. Direct confirmation of the cross-linking site was obtained by "Z"-gel analysis [Ehresmann, C., & Ofengand, J. (1984) Biochemistry 23, 438-445].(ABSTRACT TRUNCATED AT 250 WORDS)     

Comparison of the data, analysis, and results of X-ray absorption studies of cytochrome c oxidase

Differences in the methods of analysis of X-ray absorption data used by Powers et al. [Powers, L., Blumberg, W. E., Chance, B., Barlow, C., Leigh, J., Jr., Smith, J., Yonetani, T., Vik, S., & Peisach, J. (1979) Biochim. Biophys. Acta 547, 520-538; Powers, L., Chance, B., Ching, Y., & Angiolillo, P. (1981) Biophys. J. 34, 465-498] and Scott et al. [Scott, R., Schwartz, J., & Cramer S. (1986) Biochemistry 25, 5546-5555] are clarified. In addition, we compare the X-ray absorption data and results for resting cytochrome c oxidase reported by both groups using the same analysis method and conclude apart from any assumptions that the data are not identical.     

Mechanism of inactivation of gamma-aminobutyrate aminotransferase by 4-amino-5-fluoropentanoic acid. First example of an enamine mechanism for a gamma-amino acid with a partition ratio of 0

The mechanism of inactivation of pig brain gamma-aminobutyric acid aminotransferase (GABA-T) by (S)-4-amino-5-fluoropentanoic acid (1, R = CH2CH2COOH, X = F) previously proposed [Silverman, R. B., & Levy, M. A. (1981) Biochemistry 20, 1197-1203] is revised. apo-GABA-T is reconstituted with [4-3H]pyridoxal 5'-phosphate and inactivated with 1 (R = CH2CH2COOH, X = F). Treatment of inactivated enzyme with base followed by acid denaturation leads to the complete release of radioactivity as 6-[2-hydroxy-3-methyl-6-(phosphonoxymethyl)-4-pyridinyl]-4-oxo-5-+ ++hexenoic acid (4, R = CH2CH2COOH). Alkaline phosphatase treatment of this compound produces dephosphorylated 4 (R = CH2CH2COOH). These results support a mechanism that was suggested by Metzler and co-workers [Likos, J. J., Ueno, H., Feldhaus, R. W., & Metzler, D. E. (1982) Biochemistry 21, 4377-4386] for the inactivation of glutamate decarboxylase by serine O-sulfate (Scheme I, pathway b, R = COOH, X = OSO3-).