The prosthetic group of citrate-lyase acyl-carrier protein.

The acyl carrier protein of citrate lyase contains adenine, phosphate, sugar, cysteamine, beta-alanine and pantoic acid in a molar ratio of 1:2:2:1:1:1. Peptides containing these components in the same stoichiometric relationship were isolated after proteolytic digestion of acyl carrier protein. All components were linked together in a single prosthetic group. This was released from the peptide by mild alkaline hydrolysis. Under these conditions a phosphodiester bond is cleaved which links the prosthetic group to a serine residue of the peptide. Incubation of the prosthetic-group-containing peptide with phosphodiesterase I yielded 4'-phosphopantetheine and adenylic acid. The 5'-AMP was not free but was substituted by presumably an acidic sugar residue, which was released by mild acid hydrolysis yielding free 5'-AMP. It was concluded from these results that the prosthetic group of citrate lyase acyl carrier protein consists of a substituted isomeric dephospho-CoA. This is bound to the protein by the 5'-phosphate group of adenylic acid. The 4'-phosphopantetheine residue is bound by a phosphodiester linkage to the 2' or 3' position of ribose and the remaining hydroxyl group of ribose is substituted with presumably an acidic sugar residue. The structural similarities of this prothetic group and coenzyme A are discussed and related to the catalytic properties of citrate lyase.     

Identification of the active site of phosphoribosyl-dephospho-coenzyme A transferase and relationship of the enzyme to an ancient class of nucleotidyltransferases

Malonate decarboxylase from Klebsiella pneumoniae contains an acyl carrier protein (MdcC) to which a 2'-(5' '-phosphoribosyl)-3'-dephospho-CoA prosthetic group is attached via phosphodiester linkage to serine 25. We have shown in the preceding paper in this issue that the formation of this phosphodiester bond is catalyzed by a phosphoribosyl-dephospho-coenzyme A transferase MdcG with the substrate 2'-(5' '-triphosphoribosyl)-3'-dephospho-CoA that is synthesized from ATP and dephospho-coenzyme A by the triphosphoribosyl transferase MdcB. The reaction catalyzed by MdcG is related to nucleotidyltransfer reactions, and the enzyme indeed catalyzes unphysiological nucleotidyltransfer, e.g., adenylyltransfer from ATP to apo acyl carrier protein (ACP). These unspecific side reactions are favored at high Mg(2+) concentrations. A sequence motif including D134 and D136 of MdcG is a signature of all nucleotidyltransferases. It is known from the well-characterized mammalian DNA polymerase beta that this motif is at the active site of the enzyme. Site-directed mutagenesis of D134 and/or D136 of MdcG to alanine abolished the transfer of the prosthetic group to apo ACP, but the binding of triphosphoribosyl-dephospho-CoA to MdcG was not affected. Evidence is presented that similar to MdcG, MadK encoded by the malonate decarboxylase operon of Malonomonas rubra and CitX from the operon encoding citrate lyase in Escherichia coli are phosphoribosyl-dephospho-CoA transferases catalyzing the attachment of the phosphoribosyl-dephospho-CoA prosthetic group to their specific apo ACPs.     

Reactions of the UVRABC excision nuclease with DNA damaged by diamminedichloroplatinum(II).

Mutants of Escherichia coli, which are blocked in excision repair (uvrA6, uvrB5, or uvrC34) are exceptionally sensitive to the antitumor drug cis-Pt(II)(NH3)2Cl2 (cis-DDP) but not the trans isomer. Plasmid DNA, damaged by either the cis or trans compound and treated with the UVRABC excision nuclease was cut as shown by conversion of supercoiled DNA to relaxed forms. All three protein products of the uvrA, uvrB, and uvrC genes were required for incision. End-labeled fragments damaged with cis-DDP and reacted with the UVRABC nuclease were cut at the 8th phosphodiester bond 5' and at the 4th phosphodiester bond 3' to adjacent GG's. DNA treated with trans-DDP was not cut appreciably at adjacent GG's by the repair enzyme as subsequent analysis of reaction products after enzyme digestion gave a pattern similar to those obtained with control untreated fragments. The results indicate that the UVRABC nuclease may promote cell survival by the removal of adjacent GG's which are crosslinked by cis-Pt(II)(NH3)2Cl2.     

The nature of the 5''-linked 5'' nucleotide sequence at the 5'' end of rabbit globin messenger ribonucleic acid.

Poly(A)-containing messenger RNA isolated from rabbit reticulocytes as estimated by periodate oxidation and condensation with [3H]isoniazid has two oxidizable end groups per molecule of mol. wt. 220000. When the mRNA is subjected to stepwise degradation by beta-elimination, only one oxidizable end-group is found. This indicates that one of the 2',3' hydroxyl end-groups is linked through the normal 3'--5' phosphodiester bond, but that the other is linked in such a way that after stepwise degradation no new 2',3 hydroxyl group is revealed. This structure could be a 5'-linked 5'-phospho di- or tri-ester. On digestion with ribonuclease the isoniazid-labelled RNA produced oligonucleotide hydrazones consistent with a poly(A) sequence at the 3' end plus fragments that are not found after stepwise degradation. These fragments have a charge of --6 and --8 from pancreatic ribonuclease or --7 from ribonuclease T1 digestion. These charges are changed to --3.4 and --4.1 after pancreatic ribonuclease, ribonuclease T2 and alkaline phosphatase digestion. methyl-3H-labelled-poly(A)-containing RNA isolated from late erythroid cells contain a methyl-labelled fragment resistant to endonuclease and phosphodiesterase II digestion. After digestion with phosphodiesterase I this fragment produces methyl-3 H-labelled nucleotides with the electrophoretic mobility of pm7G and pAm. It is concluded that globin mRNA has the 5' sequences m7G(5')ppp'AmpYpGp ... and m7G(5')pppAmpApGpYp.     

Biosynthesis of the prosthetic group of citrate lyase

Citrate lyase (EC 4.1.3.6) catalyzes the cleavage of citrate to acetate and oxaloacetate and is composed of three subunits (alpha, beta, and gamma). The gamma-subunit serves as an acyl carrier protein (ACP) and contains the prosthetic group 2'-(5' '-phosphoribosyl)-3'-dephospho-CoA, which is attached via a phosphodiester linkage to serine-14 in the enzyme from Klebsiella pneumoniae. In this work, we demonstrate by genetic and biochemical studies with citrate lyase of Escherichia coli and K. pneumoniae that the conversion of apo-ACP into holo-ACP is dependent on the two proteins, CitX (20 kDa) and CitG (33 kDa). In the absence of CitX, only apo-ACP was synthesized in vivo, whereas in the absence of CitG, an adenylylated ACP was produced, with the AMP residue attached to serine-14. The adenylyltransferase activity of CitX could be verified in vitro with purified CitX and apo-ACP plus ATP as substrates. Besides ATP, CTP, GTP, and UTP also served as nucleotidyl donors in vitro, showing that CitX functions as a nucleotidyltransferase. The conversion of apo-ACP into holo-ACP was achieved in vitro by incubation of apo-ACP with CitX, CitG, ATP, and dephospho-CoA. ATP could not be substituted with GTP, CTP, UTP, ADP, or AMP. In the absence of CitG or dephospho-CoA, AMP-ACP was formed. Remarkably, it was not possible to further convert AMP-ACP to holo-ACP by subsequent incubation with CitG and dephospho-CoA. This demonstrates that AMP-ACP is not an intermediate during the conversion of apo- into holo-ACP, but results from a side activity of CitX that becomes effective in the absence of its natural substrate. Our results indicate that holo-ACP formation proceeds as follows. First, a prosthetic group precursor [presumably 2'-(5' '-triphosphoribosyl)-3'-dephospho-CoA] is formed from ATP and dephospho-CoA in a reaction catalyzed by CitG. Second, holo-ACP is formed from apo-ACP and the prosthetic group precursor in a reaction catalyzed by CitX.     

Biosynthesis of triphosphoribosyl-dephospho-coenzyme A, the precursor of the prosthetic group of malonate decarboxylase

Malonate decarboxylase from Klebsiella pneumoniae consists of four subunits MdcA, D, E, and C and catalyzes the cleavage of malonate to acetate and CO(2). The smallest subunit MdcC is an acyl carrier protein to which acetyl and malonyl thioester residues are bound via a 2'-(5' '-phosphoribosyl)-3'-dephospho-CoA prosthetic group and turn over during the catalytic mechanism. We report here on the biosynthesis of holo acyl carrier protein from the unmodified apoprotein. The prosthetic group biosynthesis starts with the MdcB-catalyzed condensation of dephospho-CoA with ATP to 2'-(5' '-triphosphoribosyl)-3'-dephospho-CoA. In this reaction, a new alpha (1' ' --> 2') glycosidic bond between the two ribosyl moieties is formed, and thereby, the adenine moiety of ATP is displaced. MdcB therefore is an ATP:dephospho-CoA 5'-triphosphoribosyl transferase. The second protein involved in holo ACP synthesis is MdcG. This enzyme forms a strong complex with the 2'-(5' '-triphosphoribosyl)-3'-dephospho-CoA prosthetic group precursor. This complex, called MdcG(i), is readily separated from free MdcG by native polyacrylamide gel electrophoresis. Upon incubation of MdcG(i) with apo acyl carrier protein, holo acyl carrier protein is synthesized by forming the phosphodiester bond between the 2'-(5' '-phosphoribosyl)-3'-dephospho-CoA prosthetic group and serine 25 of the protein. MdcG corresponds to a 2'-(5' '-triphosphoribosyl)-3'-dephospho-CoA:apo ACP 2'-(5' '-phosphoribosyl)-3'-dephospho-CoA transferase. In absence of the prosthetic group precursor, MdcG catalyzes at a low rate the adenylylation of apo acyl carrier protein using ATP as substrate. The adenylyl ACP thus formed is an unphysiological side product and is not involved in the biosynthesis of holo ACP. The 2'-(5' '-triphosphoribosyl)-3'-dephospho-CoA precursor of the prosthetic group has been purified and its identity confirmed by mass spectrometry and enzymatic analysis.     

The type of covalent bond in a natural complex of the bacteriophage phi X 174 protein A* and nucleotides

The 32P-labelled A* protein has been isolated from E. coli cells infected by phage phi X174 in the presence of [32P]orthophosphate. The snake venom phosphodiesterase treatment of the [32P]peptides obtained by the pronase digestion of the protein has revealed a phosphodiester bond between the protein and a nucleotide material of A, G base composition. The hydrolysis of nucleotide-peptides with a mixture of concentrated HCl and CF3COOH has yielded 4'O-phosphotyrosine.     

Purification and properties of citrate lyase from Escherichia coli

Citrate lyase (EC 4.1.3.6) has been purified from Escherichia coli and the homogeneity of the preparation established from the three-component subunits obtained on sodium dodecyl sulfate/polyacrylamide gel electrophoresis. The purified enzyme has a specific activity of 120 mumol min-1 mg-1 and requires optimally 10 mM Mg2+ and a pH of 8.0 for the cleavage reaction. The native enzyme is polydispersed in the ultracentrifuge and in polyacrylamide gel electrophoresis. The enzyme complex is composed of three different polypeptide chains of 85 000, 54 000, 32 000 daltons. An estimate of subunit stoichiometry indicates that 1 mol of the largest polypeptide chain is associated with 6 mol each of the smaller ones. The polypeptide subunits have been isolated in pure state and their biological functions characterize. The 54 000-dalton subunit functions as the acyltransferase alpha subunit catalyzing the formation of citryl coenzyme A from citrate in the presence of acetyl coenzyme A and ethylenediaminetetraacetic acid. The 32 000-dalton subunit functions as the acyllyase beta subunit catalyzing the cleavage of (3S)-citryl coenzyme A to oxal-acetate and acetyl coenzyme A. The 85 000-dalton subunit, which carries exclusively the prosthetic group components, functions as the acyl-carrier protein gamma subunit in the cleavage of citrate in the presence of mg2+ and the alpha and beta subunits. The presence of a large ACP subunit and the unusual stoichiometry of the different subunits distinguish the complex from other citrate lyases. A ligase which acetylates the deacetyl[citrate lyase] in the presence of acetate and ATP has ben shown to be present in the organism.(ABSTRACT TRUNCATED AT 250 WORDS)     

Isolation and restriction endonuclease analysis of mycobacterial DNA

A method for the isolation of DNA from mycobacteria propagated in vitro is described that utilizes organic solvents to extract lipoidal components from the outer membrane, and digestion with a protease (nagarse) and lysozyme to penetrate the cell wall. The mycobacterial cells were lysed by the addition of detergent and the DNA was purified by digestion with pronase, sequential phenol and chloroform extractions, and digestion with RNAase A. The isolated DNA, which was obtained in good yields, was of a relatively high Mr and could be readily digested by restriction endonucleases. By this method, the genomes of Mycobacterium avium, M. intracellulare, M. lepraemurium, 'M. lufu', M. marinum, M. phlei, M. scrofulaceum, M. smegmatis and M. tuberculosis were isolated and the restriction endonuclease digestion patterns analysed. Each species could be distinguished by the digestion patterns, indicating that this approach can be used for identifying mycobacterial species. This approach is also sufficiently sensitive to differentiate strains since we were able to distinguish two independently isolated strains of M. tuberculosis, H37 and H4. In addition, no evidence was obtained for the presence of methylcytosine residues in the sequences 5'.CCGG.3',5'.CCCGGG.3',5'.CC(A/T) GG.3' or for methyladenine at 5'.GATC.3' in the DNA of the nine mycobacterial species examined using pairs of restriction enzymes that recognize and cleave at the same nucleotide sequence but differ in their sensitivity to 5-methylcytosine or 6N-methyladenine.     

On the significance of the prosthetic group composition of citrate lyase.

1. Klebsiella aerogenes contains two different acyl carrier proteins, one specific for citrate lyase, the other for fatty acid synthetase. 2. The acyl carrier protein of fatty acid synthetase from K. aerogenes was isolated and compared with the corresponding protein from Escherichia coli and with the acyl carrier protein of citrate lyase from K. aerogenes. 3. As judged from prosthetic group compositions as well as amino acid and fingerprint analyses, the acyl carrier proteins of the two fatty acid synthetases are nearly identical but different from that of citrate lyase from K. aerogenes. 4. Therefore, the different prosthetic groups alone cannot be responsible for the different specificities of the acyl carrier proteins of fatty acid synthetase and citrate lyase in K. aerogenes. 5. The prosthetic group of citrate lyase, phosphoribosyl dephospho-CoA, apparently represents no incidental, phosphopantetheine-replacing aberration. The requirement of citrate lyase for the CoA-like prosthetic group may arise from the substrate requirement of both subunit enzymes of the enzyme complex.     

Mechanism of damage recognition by Escherichia coli DNA photolyase

Escherichia coli DNA photolyase binds to DNA containing pyrimidine dimers with high affinity and then breaks the cyclobutane ring joining the two pyrimidines of the dimer in a light- (300-500 nm) dependent reaction. In order to determine the structural features important for this level of specificity, we have constructed a 43 base pair (bp) long DNA substrate that contains a thymine dimer at a unique location and studied its interaction with photolyase. We find that the enzyme protects a 12-16-bp region around the dimer from DNase I digestion and only a 6-bp region from methidium propyl-EDTA-Fe (II) digestion. Chemical footprinting experiments reveal that photolyase contacts the phosphodiester bond immediately 5' and the 3 phosphodiester bonds immediately 3' to the dimer but not the phosphodiester bond between the two thymines that make up the dimer. Methylation protection and interference experiments indicate that the enzyme makes major groove contacts with the first base 5' and the second base 3' to the dimer. These data are consistent with photolyase binding in the major groove over a 4-6-bp region. However, major groove contacts cannot be of major significance in substrate recognition as the enzyme binds equally well to a thymine dimer in a 44-base long single strand DNA and protects a 10-nucleotide long region around the dimer from DNase I digestion. It is therefore concluded that the unique configuration of the phosphodiester backbone in the strand containing the pyrimidine dimer, as well as the cyclobutane ring of the dimer itself are the important structural determinants of the substrate for recognition by photolyase.     

Nucleotide sequence of U-2 ribonucleic acid. The sequence of the 5'-terminal oligonucleotide.

The nucleotide sequences were determined for the 5'-oligonucleotides obtained by complete pancreatic RNase digestion (P25) and complete T1 RNase digestion (T27) of U-2 RNA. Complete digestion of oligonucleotide P25 with snake venom phosphodiesterase produced pm3 2,2,7G, pAm, pUm, and pCp in approximately equimolar ratios. Partial digestion of these oligonucleotides with snake venom phosphodiesterase produced -Um-C-Gp and pAm-Um, indicating the sequence of the 3'-terminal portion of the 5'-oligonucleotide is pAm-Um-C-Gp. The 5'-terminal oligonucleotide did not contain a 5'-phosphate and no free nucleoside was released from the 5' end by venom phosphodiesterase digestion. Since free pm3 2,2,7G was released by digestion with nucleotide pyrophosphatase and limited digestion with snake venom phosphodiesterase, this nucleotide is apparently linked to pAm in a pyrophosphate linkage. Mass spectrometry and thin layer chromatography in borate systems showed the ribose of m3 2, 2, 7G contains no 2'O-methyl residue. Moreover, the finding that the ribose of m3 2, 2, 7G was oxidized by NaIO4 and reduced by KB3H4 in intact U-2 RNA rules out other linkages involving the 2' and 3' positions. Accordingly, it is concluded that the structure of the 5'-terminal pentanucleotide of U-2 RNA is(see article).     

Alkaline ribonuclease from rye germ cytosol.

1. Alkaline ribonuclease (pH optimum 7.6) was isolated from rye (Secale cereale L) germ cytosol and partially purified; the preparation was devoid of other nucleolytic activities. 2. The enzyme is a typical endonuclease hydrolysing all phosphodiester bonds in RNA, yielding ultimately purine and pyrimidine nucleoside 2',3'-cyclic phosphates and the corresponding 3'-phosphates. Upon extensive digestion of synthetic polyribonucleotides, pyrimidine, but not purine, nucleoside 3'-phosphates are formed. The enzyme does not hydrolyse synthetic purine cyclic nucleotides. 3. The enzyme does not depolymerize double-stranded complexes of poly(A) and poly(U). 4. Susceptibility to photooxidation and inhibition by 2-hydroxy-5-nitrobenzyl bromide and N-bromosuccinimide implies the involvement of tryptophan residue in the active centre of the enzyme.     

Crystal structure and conformation of 8-(2-hydroxyethylamino) and 8-(pyrrolidin-1-yl) adenosines

In the course of investigation of 8-alkylamino substituted adenosines, the title compounds were synthesized as potential partial agonists for adenosine receptors. The structure determination of these compounds was carried out with the X-ray crystallography study. Crystals of 8-(2-hydroxyethylamino)adenosine are monoclinic, space group P 2(1); a = 7.0422(2), b = 11.2635(3), c = 8.9215(2) A, beta = 92.261(1) degrees, V = 707.10(3) A3, Z = 2; R-factor is 0.0339. The nucleoside is characterized by the anti conformation; the ribose ring has the C(2')-endo conformation and gauche-gauche form across C(4')-C(5') bond. The molecular structure is stabilized by intramolecular hydrogen bond of N-HO type. Crystals of 8-(pyrrolidin-1-yl)adenosine are monoclinic, space group C 2; a = 19.271(1), b = 7.3572(4), c = 11.0465(7) A, beta = 103.254(2), V = 1524.4(2) degrees A3, Z = 4; R-factor is 0.0498. In this compound, there is syn conformation of the nucleoside; the ribose has the C(2')-endo conformation and gauche -gauche form across C(4')- C(5') bond. The molecular structure is stabilized by intramolecular hydrogen bond of O-HN type. For both compounds, the branching net of intermolecular hydrogen bonds occur in the crystal structures.     

The configuration and location of the ribosidic linkage in the prosthetic group of citrate lyase (Klebsiella aerogenes).

The structure of the prosthetic group of citrate lyase (Klebsiella aerogenes) was studied by nuclear magnetic resonance and mass spectrometry. The spectra at 360 MHz of the nucleoside moiety (2'-ribosyladenosine) show the absence of 2'-hydroxyl proton, thus confirming the 2' position as the site of attachment of the second ribose moiety to the dephospho-CoA. This glycosidic linkage is found to be alpha(1" leads to 2') and is identical to that of poly(ADP-ribose). Studies of permethylation products by mass spectrometry support the above conclusion regarding the location of the ribosidic linkage.     

Enzymatic analysis of isomeric trithymidylates containing ultraviolet light-induced cyclobutane pyrimidine dimers. I. Nuclease P1-mediated hydrolysis of the intradimer phosphodiester linkage

Our recent findings suggest that enzymatic hydrolysis of the intradimer phosphodiester bond may constitute the initial step in the repair of UV light-induced cyclobutane pyrimidine dimers in human cells. To examine the susceptibility of this phosphodiester linkage to enzyme-mediated hydrolysis, the trinucleotide d-Tp-TpT was UV-irradiated and the two isomeric compounds containing a cis-syn-cyclobutane dimer were isolated by high performance liquid chromatography and treated with various deoxyribonucleases. Snake venom phosphodiesterase hydrolyzed only the 3'-phosphodiester group in the 5'-isomer (d-T less than p greater than TpT) but was totally inactive toward the 3'-isomer (d-TpT less than p greater than T). In contrast, calf spleen phosphodiesterase only operated on the 3'-isomer by cleaving the 5'-internucleotide bond. Kinetic analysis revealed that (i) the activity of snake venom phosphodiesterase was unaffected by a dimer 5' to a phosphodiester linkage, (ii) the action of calf spleen phosphodiesterase was partially inhibited by a dimer 3' to a phosphodiester bond, and (iii) Escherichia coli phr B-encoded DNA photolyase reacted twice as fast with d-T less than p greater than TpT as with d-TpT less than p greater than T. Mung bean nuclease, nuclease S1, and nuclease P1 all cleaved the 5'-internucleotide linkage, but not the intradimer phosphodiester bond, in d-TpT less than p greater than T. Both phosphate groups in d-T less than p greater than TpT were refractory to mung bean nuclease or nuclease S1. Incubation of d-T less than p greater than TpT with nuclease P1, however, generated the novel compound dT less than greater than d-pTpT containing a severed intradimer phosphodiester linkage. Accordingly, nuclease P1 represents the first purified enzyme known to hydrolyze an intradimer phosphodiester linkage.     

Effect of 2'-5' phosphodiesters on DNA transesterification by vaccinia topoisomerase

Vaccinia topoisomerase forms a covalent DNA-(3'-phosphotyrosyl)-enzyme intermediate at a pentapyrimidine target site 5'-CCCTTp downward arrow in duplex DNA. By introducing single 2'-5' phosphodiesters in lieu of a standard 3'-5' phosphodiester linkage, we illuminate the contributions of phosphodiester connectivity to DNA transesterification. We find that the DNA cleavage reaction was slowed by more than six orders of magnitude when a 2'-5' linkage was present at the scissile phosphodiester (CCCTT(2')p downward arrow(5')A). Thus, vaccinia topoisomerase is unable to form a DNA-(2'-phosphotyrosyl)-enzyme intermediate. We hypothesize that the altered geometry of the 2'-5' phosphodiester limits the ability of the tyrosine nucleophile to attain a requisite, presumably apical orientation with respect to the 5'-OH leaving group. A 2'-5' phosphodiester located to the 3' side of the cleavage site (CCCTTp downward arrowN(2')p(5')N) reduced the rate of transesterification by a factor of 500. In contrast, 2'-5' phosphodiesters at four other sites in the scissile strand (TpCGCCCTpT downward arrowATpTpC) and five positions in the nonscissile strand (3'-GGGpApApTpApA) had no effect on transesterification rate. The DNAs containing 2'-5' phosphodiesters were protected from digestion by exonuclease III. We found that exonuclease III was consistently arrested at positions 1 and 2 nucleotides prior to the encounter of its active site with the modified 2'-5' phosphodiester and that the 2'-5' linkage itself was poorly hydrolyzed by exonuclease III.     

Properties of DNase I digestion of the deoxyoligonucleotide: 5''d(ATCGTACGAT)2(3'').

Deoxyribonuclease I digestion of the deoxyoligodecamer 5'd(ATCGTACGAT)2(3') has been examined in detail to study the kinetic and structural properties of this enzyme substrate system in solution. In addition, these studies have defined, in general, those DNase I conditions to be used in future drug-DNA footprinting experiments. Special attention has been taken of those properties of DNase I that are critical for quantitation of ligand binding to small DNA fragments, and that aid in designing oligomers to be used in footprinting experiments. Enzyme activity was observed at all phosphodiester bonds in the decamer studied with varying affinity, except for the first four bonds at the 5' end of the oligomer. The DNA substrate concentration is always in excess, in order to achieve conditions of no more than one DNase I cleavage per DNA molecule. Reactions were controlled so that 65% or more of the initial amount of decamer substrate remained after DNase I digestion. It was observed that the rate of enzyme reactivity decreases with digestion time and is sensitive to the experimental conditions.     

Characterization of Novikoff hepatoma mRNA methylation and heterogeneity in the methylated 5' terminus.

KOH digestion of methyl-labeled poly(A)+ mRNA purified by (dT)-cellulose chromatography produced mononucleotide and multiple peaks of a large oligonucleotide (-6 to -8 charge) when separated on the basis of charge by Pellionex-WAX high-speed liquid chromatography in 7 M urea. Heat denaturation of the RNA before application to (dT)-cellulose was required to release contaminants (mostly 18S rRNA) that persisted even after repeated binding to (dT)-cellulose at room temperature. Analysis of the purified poly(A)+ mRNA by enzyme digestion, acid hydrolysis, and a variety of chromatographic techniques has shown that the monucleotide (53%) is due entirely to N6-methyladenosine. The large oligonucleotides (47%) were found to contain 7-methylguanosine and the 2'-0-methyl derivatives of all four nucleosides. No radioactivity was found associated with the poly(A) segment. Periodate oxidation of the mRNA followed by beta elimination released only labeled 7-methylguanine consistent with a blocked 5' terminus containing an unusual 5'-5' bond. Alkaline phosphatase treatment of intact mRNA had no effect on the migration of the KOH produced oligonucleotides on Pellionex-WAX. When RNA from which 7-methylguanine was removed by beta elimination was used for the phosphatase treatment, distinct dinucleotides (NmpNp) and trinucleotides (NmpNmpNp) occurred after KOH hydrolysis and Pellionex-WAX chromatography. Thus Novikoff hepatoma poly(A)+ mRNA molecules can contain either one or two 2'-0-methylnucleotides linked by a 5'-5' bond to a terminal 7-methylguanosine and the 2'-0-methylation can occur with any of the four nucleotides. The 5' terminus may be represented by m7G5'ppp5' (Nmp)lor2Np, a general structure proposed earlier as a possible 5' terminus for all eucaryotic mRNA molecules (Rottman, F., Shatkin, A., and Perry, R. (1974), Cell 3, 197). The composition analyses indicate that there are 3.0 N6-methyladenosine residues, 1.0 7-methylguanosine residue, and 1.7 2'-0-methylnucleoside residues per average mRNA molecule.     

The formation of a 1-5 phosphodiester linkage in the spontaneous breakdown of 5-phosphoribosyl-alpha-1-pyrophosphate

The decomposition of 5-phosphoribosyl-alpha-1-pyrophosphate (PRPP) in the presence of Mg2+ at pH=7.8 yields a combination of products including ribose 5-phosphate, ribose 1-phosphate, 5-phosphoribosyl 1,2 cyclic phosphate, inorganic phosphate, and pyrophosphate. Hydrogen decoupled 31P NMR analysis of the product mixture also exhibits a sharp peak (+2.6 ppm from phosphocreatine) in a chemical shift region which includes phosphodiester bonds. Alkaline phosphatase treatment of the product mixture results in cleavage of monophosphate esters such as ribose 1-phosphate and ribose 5-phosphate, but does not affect the unidentified peak. Homonuclear (1H) correlation spectroscopy (COSY) of a partially purified sample was successful in identifying the hydrogen spectra of this compound. Combined with results from the splitting patterns of selectively decoupled 31P spectra, the COSY data indicate that several hydrogens are directly coupled to the unknown phosphate group with J value matches to the hydrogen on carbon one and to the two hydrogens on carbon five. Heteronuclear (1H-31P) chemical shift correlation studies confirm these couplings and further substantiate the formation of a ribose 1-5 phosphate linkage during the degradation of PRPP under these conditions. It is presently unknown whether this is an intramolecular or intermolecular phosphodiester linkage, although some spectroscopic evidence suggest the intramolecular bond formation, i.e. a ribose 1,5-cyclic phosphate (R-1,5cP). The formation of R-1,5cP helps explain the observation that the 5-phosphate group from PRPP becomes labile during the spontaneous degradation of PRPP.