Identities and phylogenetic comparisons of posttranscriptional modifications in 16 S ribosomal RNA from Haloferax volcanii.

Small subunit (16 S) rRNA from the archaeon Haloferax volcanii, for which sites of modification were previously reported, was examined using mass spectrometry. A census of all modified residues was taken by liquid chromatography/electrospray ionization-mass spectrometry analysis of a total nucleoside digest of the rRNA. Following rRNA hydrolysis by RNase T(1), accurate molecular mass values of oligonucleotide products were measured using liquid chromatography/electrospray ionization-mass spectrometry and compared with values predicted from the corresponding gene sequence. Three modified nucleosides, distributed over four conserved sites in the decoding region of the molecule, were characterized: 3-(3-amino-3-carboxypropyl)uridine-966, N(6)-methyladenosine-1501, and N(6),N(6)-dimethyladenosine-1518 and -1519 (all Escherichia coli numbering). Nucleoside 3-(3-amino-3-carboxypropyl)uridine, previously unknown in rRNA, occurs at a highly conserved site of modification in all three evolutionary domains but for which no structural assignment in archaea has been previously reported. Nucleoside N(6)-methyladenosine, not previously placed in archaeal rRNAs, frequently occurs at the analogous location in eukaryotic small subunit rRNA but not in bacteria. H. volcanii small subunit rRNA appears to reflect the phenotypically low modification level in the Crenarchaeota kingdom and is the only cytoplasmic small subunit rRNA shown to lack pseudouridine.

Posttranscriptional modification of transfer RNA in the submarine hyperthermophile Pyrolobus fumarii.

In the RNA of hyperthermophiles, which grow optimally between 80 degrees C and 106 degrees C, posttranscriptional modification has been identified as a leading mechanism of structural stabilization. Particularly in the Archaeal evolutionary domain these modifications are expressed as a structurally diverse array of modification motifs, many of which include ribose methylation. Using mass spectrometric techniques we have examined the posttranscriptional modifications in unfractionated tRNA from the remarkable organism Pyrolobus fumarii, which grows optimally at 106 degrees C, but up to 113 degrees C (Blöchl et al. (1997), Extremophiles, 1, 14-21). Twenty-six modified nucleosides were detected, 11 of which are methylated in ribose. A new RNA nucleoside, 1,2'-O-dimethylguanosine (m1Gm) was characterized and the structure confirmed by chemical synthesis.

Posttranscriptional modifications in 16S and 23S rRNAs of the archaeal hyperthermophile Sulfolobus solfataricus.

Posttranscriptional modification is common to many types of RNA, but the majority of information concerning structure and function of modification is derived principally from tRNA. By contrast, less is known about modification in rRNA in spite of accumulating evidence for its direct participation in translation. The structural identities and approximate molar levels of modifications have been established for 16S and 23S rRNAs of the archaeal hyperthermophile Sulfolobus solfactaricus by using combined chromatography-mass spectrometry-based methods. Modification levels are exceptionally high for prokaryotic organisms, with approximately 38 modified sites in 16S rRNA and 50 in 23S rRNA for cells cultured at 75 degrees C, compared with 11 and 23 sites, respectively, in Escherichia coli. We structurally characterized 10 different modified nucleosides in 16S rRNA, 64% (24 residues) of which are methylated at O-2' of ribose, and 8 modified species in 23S rRNA, 86% (43 residues) of which are ribose methylated, a form of modification shown in earlier studies to enhance stability of the polynucleotide chain. From cultures grown at progressively higher temperatures, 60, 75, and 83 degrees C, a slight trend toward increased ribose methylation levels was observed, with greatest net changes over the 23 degrees C range shown for 2'-O-methyladenosine in 16S rRNA (21% increase) and for 2'-O-methylcytidine (24%) and 2'-O-methylguanosine (22%) in 23S rRNA. These findings are discussed in terms of the potential role of modification in stabilization of rRNA in the thermal environment.

Structural characterization of U*-1915 in domain IV from Escherichia coli 23S ribosomal RNA as 3-methylpseudouridine.

Mass spectrometry-based methods have been used to study post-transcriptional modification in the 1900-1974 nt segment of domain IV in 23S rRNA of Escherichia coli, a region which interacts with domain V in forming the three- dimensional structure of the peptidyl transferase center within the ribosome. A nucleoside constituent of M r 258 (U*)which occurs at position 1915, within the highly modified oligonucleotide sequence 1911-psiAACU*Apsi-1917, was characterized as 3-methylpseudouridine (m3psi). The assignment was confirmed by chemical synthesis of m3psi and comparison with the natural nucleoside by liquid chromatography-mass spectrometry. 3-Methylpseudouridine is previously unknown in nature and is the only known derivative of the common modified nucleoside pseudouridine thus far found in bacterial rRNA.

Posttranscriptional modification of the central loop of domain V in Escherichia coli 23 S ribosomal RNA.

Knowledge of the sites, structures, and functional roles of posttranscriptional modification in rRNAs is limited, despite steadily accumulating evidence that rRNA plays a direct role in the peptidyl transferase reaction and that modified nucleotides are concentrated at the functional center of the ribosome. Using methods based on mass spectrometry, modifications have been mapped in Escherichia coli 23 S rRNA in the central loop of domain V, a region of established interaction between 23 S RNA and tRNA. Two segments of RNA were isolated following protection with oligodeoxynucleotides and nuclease digestion: residues 2423-2473 (51-mer) and 2481-2519 (39-mer). Dihydrouridine was located at position 2449, within the RNase T1 hydrolysis product 2448-ADAACAGp-2454, as evidenced by a molecular mass 2 daltons higher than the gene sequence-predicted mass. This nucleoside, which is nearly ubiquitous in tRNA (where it is involved in maintenance of loop structure), is two bases from A-2551, a previously determined site of interaction between 23 S RNA and the CCA-aminoacyl terminus of tRNA at the ribosomal P-site. The oligonucleotide 2496-CACmCUCGp-2502 was isolated and accurately mass measured, and its nucleoside constituents were characterized by high performance liquid chromatography-mass spectrometry; there was no evidence of modification at position 2501 as implied by earlier work. Using similar techniques, the modified adenosine at position 2503 was unambiguously determined to be 2-methyladenosine in the fragment 2503-m2A psi Gp-2505.

Differential prenylation of proteins as a function of mevalonate concentration in CHO cells.

The incorporation of [5-3H]mevalonate into prenylated proteins and polyisoprenoid lipids has been determined as a function of mevalonate concentration in Chinese hamster ovary (CHO) cells that are inhibited in mevalonate synthesis. The relative incorporation of mevalonate into the different end products of isoprenoid metabolism was markedly dependent upon the concentration of mevalonate in the medium. The synthesis of cholesterol was dominant at higher concentrations of mevalonate while higher molecular weight isoprenoids were favored at the lower concentrations. The relative incorporation of mevalonate into the different prenylcysteines of prenylated proteins was dependent upon mevalonate concentration with geranylgeranylcysteine being the principal product at higher concentrations. At low levels of mevalonate farnesylcysteine synthesis predominated and geranylcysteine was detected. Sodium dodecyl sulfate-polyacrylamide gel electrophoresis of proteins from CHO cells that had been radiolabeled at different concentrations of [3H]mevalonate had different patterns on fluorography with relatively few proteins labeled at low concentrations. A study of this effect on the prenylcysteines of a specific protein, Ras, showed considerably less sensitivity to mevalonate concentration than bulk protein. These results indicate that the specific proteins that are prenylated depend upon the availability of the isoprenyl diphosphate substrates.

5S rRNA modification in the hyperthermophilic archaea Sulfolobus solfataricus and Pyrodictium occultum.

The 5S rRNAs from Sulfolobus solfataricus and Pyrodictium occultum were digested to nucleosides and analyzed using directly-combined HPLC/mass spectrometry. P. occultum 5S rRNA contains two modified nucleoside species, N4-acetylcytidine (ac4C) and N4-acetyl-2'-O-methylcytidine (ac4Cm). Oligonucleotides were generated from P. occultum 5S rRNA by RNase T1 hydrolysis, and their molecular weights were determined using electrospray mass spectrometry and compared with those predicted from the P. occultum 5S RNA gene sequence. Deviation in mass between expected and observed molecular weights permitted ac4Cm to be located at position 35, in the nonanucleotide CAA-CACC[ac4Cm]G, and the ac4C in one or both of two (C,U)G trinucleotides. 2'-O-Methylcytidine is unambiguously characterized in S. solfataricus 5S rRNA, confirming earlier tentative assignments at the analogous sequence position (Stahl, D.A., Luehrsen, K.R., Woese, C.R., and Pace, N.R. (1981) Nucleic Acids Res., Vol. 9, pp. 6129-6137; Dams, E., Londei, P., Cammarano, P., Vandenberghe, A., and De Wachter, R. (1983) Nucleic Acids Res. Vol. 11, pp. 4667-4676). Potential effects of the presence of ac4C and ac4Cm on thermal stabilization of 5S rRNA in thermophiles are discussed.

Quantitation of prenylcysteines by a selective cleavage reaction.

The allylic thioether bond of the prenylcysteines of prenylated proteins has been shown to be cleaved by 2-naphthol under alkaline conditions to yield substituted naphthopyrans. These products are readily resolved from interfering materials by HPLC and have a strongly absorbing chromophore. Thus, this reaction is suitable for quantitative analysis of prenyl substituents of proteins, and we have examined a number of tissues for their content of prenylcysteines. These amino acids are present in mammalian tissues at a concentration of 0.36-1.4 nmol/mg of protein, with a ratio of geranylgeranylcysteine to farnesylcysteine in the range of 4 to 10. Prenylcysteines were also found in the cytosolic fraction of two mouse tissues at about one-third the concentration of the whole organ. The level of these modified amino acids was found to be significantly less in a yeast, a fungus, a brown alga, a higher plant, and an insect. Again, geranylgeranylcysteine is predominant. Prenylcysteines were absent from Escherichia coli but present in an archaebacterium. The prenylcysteine content of mammalian tissue is about 1% of that of cholesterol and about equal to that of ubiquinones and dolichols. Calculations indicate that about 0.5% of all proteins are prenylated.

Prenylated proteins: demonstration of a thioether linkage to cysteine of proteins.

Prenylated amino acid fragments have been isolated from prenylated proteins of Chinese hamster ovary cells. Gel-exclusion chromatography indicates that these proteins are modified by two different prenyl groups. The prenyl-amino acid fragments are labeled by 35S from cysteine, and this bond is cleaved by Raney-Ni, proving that the prenyl residue is linked to protein via a thioether to cysteine. Hydrazinolysis has been used to demonstrate that the cysteine is carboxy terminal.

Determination of isopentenyl diphosphate and farnesyl diphosphate in tissue samples with a comment on secondary regulation of polyisoprenoid biosynthesis.

A double-isotope dilution procedure is described for the determination of two isoprenoid precursors, isopentenyl and farnesyl diphosphate. Recovery of each is determined by the addition of the appropriate radioactive diphosphate to the tissue sample. After partial purification, each is coupled by a prenyltransferase with a cosubstrate of known specific activity. The products, doubly labeled farnesyl and geranylgeranyl diphosphates, are cleaved to the parent alcohols by alkaline phosphatase. The resulting polyprenols are isolated by reversed-phase thin-layer chromatography and their radioisotopic content is determined. The levels of these precursors have been measured in livers of rats and mice that have been maintained on several different diets. The concentration of each was about 0.5 mumol/g wet tissue and varied as much as 10-fold under the different test conditions. The levels of isopentenyl diphosphate isomerase, farnesyl diphosphate synthetase, and squalene synthetase were also measured in these animals. The changes in levels of these enzymes, in conjunction with the variation in substrate concentrations, are such that they could substantially influence the rate of cholesterol synthesis in liver.

Isopentenyl pyrophosphate isomerase:dimethylallyl pyrophosphate isomerase: isolation from Claviceps sp. SD 58 and comparison to the mammalian enzyme.

Isopentenyl pyrophosphate isomerase:dimethyl pyrophosphate isomerase (EC 5.3.3.2) has been purified to near homogeneity from Claviceps sp. A molecular weight of 35,000 was found by gel exclusion chromatography as well as by sodium dodecyl sulfate-polyacrylamide gel electrophoresis. This indicates that the enzyme consists of a single subunit and is in contrast to the Mr 22,000 that we have found for the enzyme from liver. The lability of isomerase from liver, often reported, has been found to be due to its susceptibility to proteolysis. Nine compounds have been tested as inhibitors of both isomerases. The binding of analogs requires the pyrophosphate moiety which may be substituted by a variety of alkyl groups. Inclusion of a polar function in the hydrocarbon portion of the analog greatly reduces interaction with the enzyme. Reversibility of the reaction was not found with a higher homolog of the substrate.

Prenylated proteins from kidney.

When [5-3H]mevalonate is injected into mice, it is incorporated into macromolecules in the kidney. The incorporated material is stable to treatment with RNase or DNase but not protease, indicating that the radioactivity is associated with protein. Electrophoresis in sodium dodecyl sulfate-containing polyacrylamide gels indicates a molecular weight of about 25,000. The incorporated radioactivity can be released from the polypeptide and extracted into organic solvents after hydrolysis with acid or base or by treatment with protease. The conditions required for hydrolysis strongly suggest that the linkage between the protein and the mevalonate-derived material is an allylic ether. The chromatographic mobility of the incorporated material in several systems is similar to that of dolichol C95.

Prenyltransferase and squalene synthetase in livers of neonate rats.

The liver of the newly born rat has approximately the same capacity for cholesterol biosynthesis as that of the adult animal. However, during nursing, the ability to synthesize cholesterol diminishes markedly during the early neonate period and by the end of the second week has essentially vanished. The level of the regulatory enzyme of cholesterol biosynthesis, 3-hydroxy-3-methylglutaryl-CoA reductase, closely follows this pattern (Hahn, P. and Walker, B. (1979) Can. J. Biochem. 57, 1216-1219). In contrast, we have found that two other enzymes of cholesterol biosynthesis, prenyltransferase and squalene synthetase, undergo changes in activity that provide three maxima - one on birth, one during midnursing, and one on weaning. Possible explanations for this pattern are presented.

Isolation and characterization of a photoaffinity-labeled peptide from the catalytic site of prenyltransferase.

Previously we presented evidence for the selective modification of the catalytic site of prenyltransferase by photoaffinity labeling with o-azidophenylethyl pyrophosphate [Brems, D. N., & Rilling, H. C. (1979) Biochemistry 18, 860]. In the present work, we report the isolation and characterization of a CNBr fragment of 30 amino acid residues from the photoaffinity-labeled enzyme. This CNBr fragment contains over 809% of the total label attached to prenyltransferase as a result of photoaffinity labeling. Several lines of evidence indicate that a number of residues in this CNBr fragment have been modified. First, Edman degradation of this labeled peptide demonstrates that at least 16 of the 30 amino acids have been modified by the photoaffinity reagent. The two most extensively modified amino acids are a specific arginine and alanine. Second, two-dimensional chromatography of Pronase digestions of the labeled CNBr fragment indicates that at least 11 different products resulted from photoaffinity labeling. Third, peptide maps of a trypsin digest of this CNBr fragment show that the attached affinity label is distributed among at least three of the resulting products of tryptic hydrolysis. Finally, comparison of amino acid analysis of this CNBr fragment with that of its counterpart isolated from native enzyme is consistent with the modification of a number of amino acids rather than a few y the photoaffinity labeling process.