Structural characterization of tatiopterin, a novel pterin isolated from Methanogenium tationis

Cofactor extracts of Methanogenium tationis were screened for the presence of pterin-derivatives. Methanopterin, sarcinapterin and 7-methylpterin were absent, while 2-amino-4-hydroxy-pteridine and another blue fluorescent compound with a pterin spectrum were detected. The latter pterin was purified by ion exchange and reversed-phase column chromatography. The structure of this compound was elucidated by combining spectrophotometry, amino acid analysis and 1H-NMR spectroscopy. The pterin, which we named tatiopterin, was identified as an aspartyl derivative of sarcinapterin with a 7-proton instead of a 7-methyl group in the pterin moiety. The IUPAC name is: N-[-1'-(2'-amino-4'-hydroxy-7'-proton-6'-pteridinyl)ethyl]-4- [2',3',4',5'-tetrahydroxypent-1'-yl(5'----1')O-alpha- ribofuranosyl-5'-phosphoric acid]aniline, in which the phosphate group is esterified with alpha-hydroxyglutarylglutamylaspartic acid.     

Methanogenesis involving a novel carrier of C1 compounds in Methanogenium tationis.

The pathway of CO2 reduction to methane in Methanogenium tationis and Methanogenium thermophilicum is similar to that observed in other methanogens. In M. tationis a novel pterin, tatiopterin, is present. This pterin appears to be a structural and functional analog of methanopterin and sarcinapterin. Folate could not substitute for tatiopterin.     

Comparative distribution of glutamyl and aspartyl aminopeptidase activities in mouse organs.

To evaluate the functional role of glutamyl and aspartyl aminopeptidases, their soluble and membrane-bound activities were measured simultaneously in several tissues of normal mice using arylamide derivatives as substrates. Although the soluble aspartyl aminopeptidase activity showed its highest levels in the testicle, the rest of the activities presented their highest levels in the kidney. Different patterns of distribution were observed for glutamyl and aspartyl aminopeptidase activities and also for soluble and membrane-bound aspartyl aminopeptidase activities. However no major differences were observed between soluble and membrane-bound glutamyl aminopeptidase activities. This unequal distribution suggests that the use of arylamide derivatives as substrates is a sensitive method that distinguishes between these enzymatic activities. The results also suggest different functions for soluble and membrane-bound aspartyl aminopeptidase activities, and for glutamyl and aspartyl aminopeptidase activities.     

The carboxyl methylation of aspartyl residues in eledoisin and tetragastrin by rabbit erythrocyte aspartyl β-carboxyl methyltransferase

Rabbit erythrocytes contain a soluble aspartyl β-carboxyl methyltransferase capable of specifically carboxyl methylating the β-carboxyl group of an internal aspartyl residue in the synthetic polypeptide eledoisin, a hypotensively active peptide from the cephalopodsEledone moschata andE. aldrovandi, and tetragastrin, the biologically active C-terminal tetrapeptide of human gastrin. However, the aspartyl residue in delta sleep-inducing peptide (DSIP) could not be carboxyl methylated, nor could glutamyl residues in any polypeptide tested.     

Biosynthesis of the 7-methylated pterin of methanopterin.

The incorporation of [15N]glycine and [U-methyl-2H]methionine into methanopterin by growing cells of a methanogenic bacterium was measured to establish the biosynthetic route of the methylated pterin in the structure. The tetrahydromethanopterin produced by the cells was oxidatively cleaved to produce 7-methylpterin, and the amount of label incorporated into this pterin was measured by gas chromatography-mass spectrometry of the ditrimethylsilyl derivative of this compound. Approximately 27% of the 7-methylpterin and the guanine present in the cell was derived from the fed [15N]glycine. [U-methyl-2H]methionine was incorporated with the initial retention of all three deuteriums. These results are consistent with the biosynthesis of the pterin of methanopterin originating from GTP and its 7-methyl group arising from the methyl group of methionine.     

Identification of a mammalian growth factor as a ribofolate peptide

Thymocyte growth peptide (TGP) promotes DNA synthesis of immature thymocytes. TGP has been purified from sheep, human and calf thymus and recently characterized as an N-terminally blocked nonapeptide. Evidence is presented here that the blocking moiety consists of a formylpteroyl group bound to the N-terminal glutamyl residue of the nonapeptide. The pterin part of the TGP molecule has a ribityl substituent in analogy with riboflavin, which explains the pronounced hydrophilic property of TGP in contrast to unsubstituted and unconjugated folates. The compound can be classified as a ribofolate peptide, a novel class of growth factor. Zn²⁺ counteracts degradation of the molecule and is required for full biological activity; mass spectrometric data confirm that native TGP contains zinc.     

P-O bond destabilization accelerates phosphoenzyme hydrolysis of sarcoplasmic reticulum Ca2+ -ATPase

The phosphate group of the ADP-insensitive phosphoenzyme (E2-P) of sarcoplasmic reticulum Ca2+ -ATPase (SERCA1a) was studied with infrared spectroscopy to understand the high hydrolysis rate of E2-P. By monitoring an autocatalyzed isotope exchange reaction, three stretching vibrations of the transiently bound phosphate group were selectively observed against a background of 50,000 protein vibrations. They were found at 1194, 1137, and 1115 cm(-1). This information was evaluated using the bond valence model and empirical correlations. Compared with the model compound acetyl phosphate, structure and charge distribution of the E2-P aspartyl phosphate resemble somewhat the transition state in a dissociative phosphate transfer reaction; the aspartyl phosphate of E2-P has 0.02 A shorter terminal P-O bonds and a 0.09 A longer bridging P-O bond that is approximately 20% weaker, the angle between the terminal P-O bonds is wider, and -0.2 formal charges are shifted from the phosphate group to the aspartyl moiety. The weaker bridging P-O bond of E2-P accounts for a 10(11)-10(15)-fold hydrolysis rate enhancement, implying that P-O bond destabilization facilitates phosphoenzyme hydrolysis. P-O bond destabilization is caused by a shift of noncovalent interactions from the phosphate oxygens to the aspartyl oxygens. We suggest that the relative positioning of Mg2+ and Lys684 between phosphate and aspartyl oxygens controls the hydrolysis rate of the ATPase phosphoenzymes and related phosphoproteins.     

Specificity of endoproteinase Asp-N (Pseudomonas fragi): cleavage at glutamyl residues in two proteins

Endoproteinase Asp-N, a metalloprotease from a mutant strain of Pseudomonas fragi, has been reported to specifically cleave on the N-terminal side of aspartyl and cysteic acid residues. We utilized this enzyme to generate fragments for determining the amino acid sequence of the D-aspartyl/L-isoaspartyl methyltransferase isozyme I from human erythrocytes. Surprisingly, we identified cleavage sites for this enzyme at the N-terminal side of several glutamyl residues in addition to the expected cleavage sites at aspartyl residues. The ability of this enzyme to cleave polypeptides at both glutamyl and aspartyl residues was confirmed by mapping additional sites on erythrocyte carbonic anhydrase I. These results indicate that a more appropriate name for this enzyme may be Endoproteinase Asp/Glu-N.     

Aspartyladenylate analog--effective inhibitor of asparagine synthetase

A number of earlier unknown phosphonate analogues of aspartyl adenylate with anhydride oxygen substituted by --CH2--, and the carbonyl group substituted by --CH(OH)- or --CH(NH2)-groups were synthesized. These compounds were used to study the reaction mechanism of asparagine synthetases from white lupine and E. coli. The aspartyl adenylate analogues proved to be powerful competitive inhibitors (Ki = 10(-7) M) of the bacterial enzyme. In the case of white lupine enzyme catalyzing the aspartate-independent ATP--[32P]PPi exchange, the above compounds displayed a non-competitive type of inhibition with respect to aspartate and ATP, Ki = 10(-4) M. It is likely that for the latter enzyme the first intermediate is different from an aspartyl adenylate derivative.     

Isolation and characterization of a second molybdopterin dinucleotide: molybdopterin cytosine dinucleotide

The pterin cofactor (bactopterin) in the molybdoenzyme CO dehydrogenase isolated from Pseudomonas carboxydoflava has previously been shown to differ from molybdopterin in molecular mass, phosphate content, stability, and other properties, implying a novel structure. The structure of the CO dehydrogenase pterin has been investigated in the present studies by alkylation and isolation of the carboxamidomethyl derivative. The alkylated pterin was identified as [di-(carboxamidomethyl)]molybdopterin cytosine dinucleotide on the basis of its absorption properties and by degradation with nucleotide pyrophosphatase yielding carboxamidomethylmolybdopterin and CMP. Further treatment of these products with alkaline phosphatase produced species with absorption and chromatographic properties identical to those of the corresponding dephospho compounds. Molybdopterin cytosine dinucleotide is the second molybdopterin variant to be structurally characterized. The fact that molybdopterin cytosine dinucleotide and molybdopterin guanine dinucleotide contain molybdopterin in their structure shows that the pterin moiety, with its unique dithiolene-containing sidechain, is a structural element which is common to the organic portion of the molybdenum cofactors of many molybdoenzymes.     

GLUTAMYL AND ASPARTYL MOIETIES OF CEREBRAL PROTEINS: ENRICHMENT IN MEMBRANE-CONTAINING MICROSOMAL SUBFRACTIONS

Abstract— The total mixed proteins (excluding proteolipids) were isolated from various tissues of the cat and from subcellular fractions of cat cerebral cortex and were compared for contents of total glutamyl and total aspartyl residues and total amide N. The proteins from renal cortex, testis and diaphragm were more acidic (proportionally more glutamyl and aspartyl residues with no increase of amide) than those from cerebral cortex, subcortical white matter and liver. Also the proteins isolated from cerebral cortical microsomes were more acidic than those from highly pure nuclear, mitochondrial and soluble subcellular fractions of cerebral cortex. Hepatic microsomal proteins gave very similar analyses.
Subfractionation of the microsomal preparations from cerebral cortex and liver into deoxycholate-insoluble (ribosomal) and deoxycholate-soluble ('membrane') fractions localized the acidic proteins to the latter, 'membrane' subtraction. The ribosomal proteins isolated from cerebral cortex (and liver) had an amino acid composition very similar to that reported previously for ribosomal proteins in a number of tissues from various species. Upon column chromatography on DEAE-celluIose, the deoxycholate-soluble ('membrane') subtraction of hepatic microsomes yielded a peak (eluted with 0-2 M-phosphate, pH 5-6, plus 0-5 M-NaCl) that contained an exceptionally high proportion (30 per cent) of glutamyl and aspartyl residues. We suggest that such acidic proteins may be characteristic of membranes and may subserve important metabolic functions therein.     

5-(p-aminophenyl)-1,2,3,4-tetrahydroxypentane, a structural component of the modified folate in Sulfolobus solfataricus.

The partial characterization of the modified folate present in Sulfolobus solfataricus has been carried out. Separation of ethanol-water extracts of these cells on a DEAE-Sephadex column led to the isolation of a small amount of intact oxidized cofactor, which, when subjected to reductive cleavage with Zn-HCl, produced 6-methylpterin. This indicated that the modified folate in these cells contained a nonmethylated pterin linked, via a methylene group at the C-6 position of the pterin, to an arylamine, as is found in folate. Oxidative cleavage of intact reduced cofactor produced pterin and a single arylamine. The azo dye derivative of this arylamine was prepared and purified by chromatography on a Bio-Gel P-6 column. The resulting purified compound was shown to be readily hydrolyzed in dilute acid to the azo dye derivative of 5-(p-aminophenyl)-1,2,3,4-tetrahydroxypantane, which was, in turn, readily cleaved to 5-(p-aminophenyl)-1,2,3,4- tetrahydroxypentane by Zn-HCl reduction. The stereochemistry of the resulting 5-(p-aminophenyl)-1,2,3,4-tetrahydroxypentane was shown to be ribo, the same as that of the 5-(p-aminophenyl)-1,2,3,4- tetrahydroxypentane moiety found in methanopterin. The complete arylamine side chain of the modified folate thus contains 5-(p-aminophenyl)-1,2,3,4-tetrahydroxypentane attached, via an acid-labile bond, to a currently unidentified substituent. The modified folate present in S. solfataricus thus contains structural features common to both folates and methanopterin.     

Disorder–order transitions induced in anionic homopolypeptides by cationic detergents

CD spectra have been obtained for poly(L -glutamic acid) and poly(L -aspartic acid) as functions of temperature and concentration of cationic detergents. Dodecylammonium chloride induces a coil–helix transition in fully ionized poly(L -glutamic acid). The interaction of the monomeric detergent with the polypeptide is responsible for the conformational transition. The detergent concentration required to produce the transition is independent of temperature. The CD of fully ionized poly(L -aspartic acid) is nearly unaffected by dodecylammonium chloride, in marked contrast to the situation found with poly(L -glutamic acid). However, these results do not imply that dodecylammonium chloride interacts differently with aspartyl and glutamyl residues. The observed results can be accounted for by the well-known fact that the glutamyl residue has a higher helix-forming tendency that the aspartyl residue. Cetyltrimethylammonium chloride destabilizes the helical form of poly(L -glutamic acid). This detergent presents an exception to the usual ability of ionic detergents to promote formation of ordered structures in oppositely charged homopolypeptides.     

DNA photorepair: chromophore composition and function in two classes of DNA photolyases

DNA photolyase catalyzes the repair of pyrimidine dimers in UV-damaged DNA in a reaction which requires visible light. Class I photolyases (Escherichia coli, yeast) contain 1,5-dihydroFAD (FADH2) plus a pterin derivative (5,10-methenyltetrahydropteroylpolyglutamate). In class II photolyases (Streptomyces griseus, Scenedesmus acutus, Anacystis nidulans, Methanobacterium thermoautotrophicum) the pterin chromophore is replaced by an 8-hydroxy-5-deazaflavin derivative. The two classes of enzymes exhibit a high degree of amino acid sequence homology, suggesting similarities in protein structure. Action spectra studies show that both chromophores in each enzyme tested act as sensitizers in catalysis. Studies with E. coli photolyase show that the pterin chromophore is not required when FADH2 acts as the sensitizer but that FADH2 is required when the pterin chromophore acts as sensitizer. FADH2 is probably the chromophore that directly interacts with substrate in a reaction which may be initiated by electron transfer from the excited singlet state (1FADH2*) to form a flavin radical plus an unstable pyrimidine dimer radical. Pterin, the major chromophore in E. coli photolyase, may act as an antenna to harvest light energy which is then transferred to FADH2.     

Assay of proteins in the presence of interfering materials.

Glycinamidation of aminoethylated α, β, and γ chains of adult and fetal human hemoglobins results in the attachment of a glycinamide residue to each free carboxyl group. The peptides which result from tryptic hydrolysis of such modified chains can be separated by column chromatography or filter-paper finger-printing. Glycinamidation improves the yield of several tryptic peptides and is useful in determining the number and position of aspartyl and glutamyl residues in hemoglobins.     

Zinc and copper bind to unique sites of histatin 5

Metal binding has been suggested to be relevant in the antifungal and antibacterial mechanism of histatin 5, a human salivary protein. Proton nuclear magnetic resonance (NMR) spectra were obtained to investigate the specificity of metal binding to the seven histidyl, one aspartyl and one glutamyl amino acid side-chains of histatin 5 in aqueous solutions. Three C(epsilon1)-H histidyl and the C(gamma)-H glutamyl resonances of histatin 5 were selectively altered in spectra of solutions containing three equivalents of zinc. Copper binding to histatin 5 resulted in a reduced intensity of C(beta)-H aspartyl resonances, while no evidence for calcium binding was found. These results indicate that zinc binding to histatin 5 involves His-15 present within the -H-E-X-X-H- zinc binding motif, and copper binding occurs within the N-terminal D-S-H-, ATCUN motif.     

Reconstitution of Escherichia coli DNA photolyase with various folate derivatives

DNA photolyase from Escherichia coli contains both flavin and pterin. However, the isolated enzyme is depleted with respect to the pterin chromophore (0.5 mol of pterin/mol of flavin). The extinction coefficient of the pterin chromophore at 360 nm is underestimated by a method used in earlier studies which assumes stoichiometric amounts of pterin and flavin. The extinction coefficient of the pterin chromophore, determined on the basis of its (p-aminobenzoyl)polyglutamate content (epsilon 360 = 25.7 x 10(3) M-1 cm-1), is in good agreement with that expected for a 5,10-methenyltetrahydrofolate derivative. Also consistent with this structure, the pterin chromophore could be reversibly hydrolyzed to yield a 10-formyltetrahydrofolate derivative or reduced to yield a 5-methyltetrahydrofolate derivative. The isolated enzyme could be reconstituted with various folate derivatives to yield enzyme that contained equimolar amounts of pterin and flavin. Similar results were obtained in reconstitution studies with the natural pterin chromophore, with 5,10-methenyltetrahydrofolate, and with 10-formyltetrahydrofolate. The results show that the polyglutamate moiety, previously identified in the natural chromophore, is not critical for binding. Reconstitution with the natural pterin chromophore did not affect catalytic activity. The latter is consistent with our previous studies which show that, although the pterin chromophore acts as a sensitizer in native enzyme, it is not essential for dimer repair which can occur at the same rate under saturating light with flavin (1,5-dihydro-FAD) as the only chromophore.     

The structure of the molybdenum cofactor. Characterization of di-(carboxamidomethyl)molybdopterin from sulfite oxidase and xanthine oxidase

A di-(carboxamidomethyl) derivative of molybdopterin, the organic component of the molybdenum cofactor, has been prepared under conditions favoring retention of all of the structural features of the molecule. The specific radioactivity of [1-14C]iodoacetamide incorporated relative to the amount of phosphate indicated two alkylation sites per pterin. Energy-dispersive x-ray analysis of the derivative showed the presence of 2 sulfurs in the derivative. An exact mass corresponding to the molecular formula C14H18N7O5S2 was obtained for the MH+ ion of the alkylated, dephosphorylated compound by fast atom bombardment mass spectroscopy. 1H NMR spectra of the phosphorylated and dephosphorylated forms of alkylated molybdopterin, in conjunction with the other data, have provided strong corroboration of the validity of the proposed structure of molybdopterin (Johnson, J. L., and Rajagopalan, K. V. (1982) Proc. Natl. Acad. Sci. U. S. A. 79, 6856-6860) as a 6-alkylpterin with a 4-carbon side chain containing an enedithiol on C-1' and C-2', a secondary alcohol on C-3', and a phosphorylated primary alcohol on C-4'. As isolated, the di-(carboxamido-methyl)molybdopterin was found to be a 5,6,7,8-tetrahydropterin.     

The primary electron acceptor of green sulfur bacteria,bacteriochlorophyll 663, is chlorophyll a esterified with Δ 2,6-phytadienol

The primary electron acceptor of green sulfur bacteria, bacteriochlorophyll (BChl) 663, was isolated at high purity by an improved purification procedure from a crude reaction center complex, and the molecular structure was determined by fast atom bombardment mass spectroscopy (FAB-mass), ¹H- and ¹³C-NMR spectrometry, double quantum filtered correlation spectroscopy (DQF-COSY), heteronuclear multiple-quantum coherence (HMQC) and heteronuclear multiple-bond correlation (HMBC) spectral measurements. BChl 663 was 2.0 mass units smaller than plant Chl a. The NMR spectra showed that the macrocycle was identical to that of Chl a. In the esterifying alcohol, a singlet P7¹ signal was observed at the high-field side of the singlet P3¹ signal in BChl 663, while a doublet peak of P7¹ overlapped that of P11¹ in Chl a. A signal of P7-proton, seen in Chl a, was lacking, and the P6-proton appeared as a triplet signal near the triplet P2-proton signal in BChl 663. These results indicate the presence in BChl 663 of a C=C double bond between P6 and P7 in addition to that between P2 and P3. The structure of BChl 663 was hence concluded to be Chl a esterified with 2,6-phytadienol instead of phytol. In addition to BChl 663, two molecules of the 13²-epimer of BChl a, BChl a′, were found to be present per reaction center, which may constitute the primary electron donor. This revised version was published online in June 2006 with corrections to the Cover Date.