Identification and structural characterization of O-beta-ribosyl-(1"----2'')-adenosine-5"-phosphate in yeast methionine initiator tRNA.

We report in this paper on the complete structure determination of the modified nucleotide A*, now called Ar(p), that was previously identified in yeast methionine initiator tRNA as an isomeric form of O-ribosyl-adenosine bearing an additional phosphoryl-monoester group on its ribose2 moiety. By using the chemical procedure of periodate oxidation and subsequent beta-elimination with cyclohexylamine on mono- and dinucleotides containing Ar(p), we characterized the location of the phosphate group on the C-5" of the ribose2 moiety, and the linkage between the two riboses as a (1"----2')-glycosidic bond. Since the structural difference between phosphatase treated Ar(p) and authentic O-alpha-ribosyl-(1"----2')-adenosine from poly(ADP-Ribose) was previously assigned to an isomeric difference in the ribose2-ribose1 linkage, the (1"----2')-glycosidic bond of Ar(p) was deduced to have a beta-spatial configuration. Thus, final chemical structure for Ar(p) at the position 64 in yeast initiator tRNA(Met) has been established as O-beta-ribosyl-(1"----2')-adenosine-5"-phosphate. This nucleotide is linked by a 3',5'-phosphodiester bond to G at the position 65.     

Metabolism of Lignin Model Compounds of the Arylglycerol-beta-Aryl Ether Type by Pseudomonas acidovorans D(3)

A natural bacterial isolate that we have classified as Pseudomonas acidovorans grows on the lignin model compounds 1-(3,4-dimethoxyphenyl)-2-(2-methoxyphenoxy)propane-1,3-diol (compound 1) and 1-(4-hydroxy-3-methoxyphenyl)-2-(2-methoxyphenoxy)propane-1,3-diol (compound 1'), as well as on the corresponding 1-oxo compounds (2 and 2') as sole sources of carbon and energy. Metabolic intermediates present in cultures growing on compound 1 included compound 2, 2-methoxyphenol (guaiacol [compound 3]), beta-hydroxypro-pioveratrone (compound 4), acetoveratrone (compound 5), and veratric acid (compound 6). Also identified were compounds 1', 2', beta-hydroxypropiovanillone (compound 4'), and acetovanillone (compound 5'), indicating that 4-O demethylation also occurs. The phenolic intermediates were the same as those found in cultures growing on compound 1'. Compounds 2 and 2' were in part also reduced to compounds 1 and 1', respectively. Compound 3 was shown to be derived from the 2-methoxyphenoxy moiety. A suggested degradation scheme is as follows: compound 1-->2-->(3 + 4)-->5-->6 (and similarly for 1'). In this scheme, the key reaction is cleavage of the ether linkage between C-2 (C(beta)) of the phenylpropane moiety and the 2-methoxyphenoxy moiety in compounds 2 and 2' (i.e., beta-aryl ether cleavage). On the basis of compounds identified, viz., 3 and 4 (4'), cleavage appears formally to be reductive. Because this is unlikely, the initial cleavage products probably were not detected. The implications of these results for the enzyme(s) responsible are discussed.     

Synthesis and properties of ApA analogues with shortened phosphonate internucleotide linkage

A complete series of the 2 '-5 ' and 3 '-5 ' regioisomeric types of r(ApA) and 2 '-d(ApA) analogues with the α-hydroxy-phosphonate C3 '-O-P-CH(OH)-C4 ″ internucleotide linkage, isopolar but non-isosteric with the phosphodiester one, were synthesized and their hybridization properties with polyU studied. Due to the chirality on the 5 '-carbon atom of the modified internucleotide linkage bearing phosphorus and hydroxy moieties, each regioisomeric type of ApA dimer is split into epimeric pairs. To examine the role of the 5 '-hydroxyl of the α-hydroxy-phosphonate moiety during hybridization, the appropriate r(ApA) analogues with 3 '(2 ')-O-P-CH(2)-C4 ″ linkage lacking the 5 '-hydroxyl were synthesized. Nuclear magnetic resonance (NMR) spectroscopy study on the conformation of the modified sugar-phosphate backbone, along with the hybridization measurements, revealed remarkable differences in the stability of complexes with polyU, depending on the 5 '-carbon atom configuration. Potential usefulness of the α-hydroxy-phosphonate linkage in modified oligoribonucleotides is discussed.     

Phycobiliprotein-bilin linkage diversity. I. Structural studies on A- and D-ring-linked phycocyanobilins

Phycocyanobilin (PCB) peptides alpha-1 PCB and beta-2T PCB were obtained by proteolytic degradation of Synechococcus 6301 C-phycocyanin. These peptides were found to have the following sequences. alpha-1 PCB Cys(PCB)-Ala-Arg beta-2T PCB Ile-Thr-Gln-Gly-Asp-Cys(PCB)-Ser-Ala. The peptides were examined by 1H NMR, circular dichroism spectroscopy, and secondary ion mass spectrometry. The 1H NMR data confirmed that in each case the bilin was attached through a single linkage, a thioether bond between the cysteinyl residue and the tetrapyrrole moiety. Comparison of the 1H NMR spectra of these peptides with those of appropriate model compounds showed that the thioether linkage in alpha-1 PCB was to the C-3' position and that in beta-2T PCB to the C-18' position on the bilin. Refluxing in neutral methanol under nitrogen led to the release of PCB from alpha-1 PCB but did not release the D-ring-linked tetrapyrrole from beta-2T. The above results together with those of an earlier study (Lagarias, J. C., Glazer, A. N., and Rapoport, H. (1979) J. Am. Chem. Soc. 101, 5030-5037) complete the determination of the mode of linkage of each of the three bilins on C-phycocyanin; two are linked through ring A and one through ring D. This is the first documented report of a singly D-ring-linked bilin.     

Derivatives of methanopterin, a coenzyme involved in methanogenesis

Degradational studies of methanopterin, a coenzyme involved in methanogenesis, are reported. The results of these studies are in full accordance with the proposed structure of methanopterin as N-[1'-(2'-amino-4'-hydroxy-7' -methyl-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-hydroxyglutaric acid. Acid hydrolysis of methanopterin cleaved the 5'----1' glycosidic bond and yielded a 'hydrolytic product' which was identified as N-[1'-(2'-amino-4'-hydroxy-7' -methyl-6'-pteridinyl)ethyl]-4-[2', 3', 4', 5'-tetrahydroxypent-1'-yl]aniline. Alkaline permanganate oxidation of methanopterin yielded 7-methylpterin-6-carboxylic acid. Catalytic (or enzymatic) hydrogenation of methanopterin gave a mixture of 6-ethyl-7-methyl-7,8-dihydropterin, 6-ethyl-7-methylpterin and a third compound, named methaniline which was identified as 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-hydroxyglutaric acid. Methanosarcina barkeri contains a closely related coenzyme called sarcinapterin, which was identified as a L-glutamyl derivative of methanopterin, where the glutamate moiety is attached to the alpha-carboxylic acid group of the alpha-hydroxyglutaric acid moiety of methanopterin via an amide linkage.     

Formation of lysosulfatide, 3',6'-anhydropsychosine, ceramide, and sphingosine by saponification of cerebroside sulfate. Effect of the sulfate group on the hydrolysis.

Saponification of cerebroside sulfate (sulfatide) by refluxing with 1 N KOH in 90% n-butanol for 1 h yielded ceramide, sphingosine, lysosulfatide (psychosine-3'-sulfate ester) and a hitherto unknown compound. The latter compound was identified as 3,6-anhydrogalactosyl sphingosine (3',6'-anhydropsychosine) from its mass spectrum. The structure of lysosulfatide was confirmed by reacylating it to sulfatide by condensing it with lignoceroyl chloride. The resulting sulfatide, which was chromatographically identical to control sulfatides, was not oxidized by periodate. The sulfatide was also permethylated and methanolyzed. The sugar moiety obtained was identified as methyl 2,4,6-tri-O-methylgalactoside by gas-liquid chromatography and thin-layer chromatography. The presence of the sulfate group in lysosulfatide was further confirmed by IR spectroscopy and the presence of radioactivity when it was prepared from [35S]sulfatide. The effect of the sulfate group on cleavage of the galactoside linkage and on the formation of the 3,6-anhydro derivative is discussed.     

Flexibility in the phosphorylase catalytic reaction. Glucosyltransfer from pyridoxal (5')-triphospho(1)-alpha-D-glucose to glycogen catalyzed by phosphorylase

When rabbit muscle phosphorylase reconstituted with pyridoxal (5')-diphospho(1)-alpha-D-glucose is incubated with glycogen, its glucosyl moiety is transferred to the nonreducing end of glycogen with the formation of a new alpha-1,4-glucosidic linkage. This finding provided the first evidence for the direct phosphate-phosphate interaction between the coenzyme pyridoxal 5'-phosphate and the substrate alpha-D-glucose 1-phosphate in the phosphorylase catalytic reaction (Takagi, M., Fukui, T., and Shimomura, S. (1982) Proc. Natl. Acad. Sci. U. S. A. 79, 3716-3719). We have examined whether pyridoxal(5')triphospho(1)-alpha-D-glucose can act in a similar manner to the diphospho compound or not. In the absence of glucan the enzyme-bound triphospho compound was stable for 1 day at pH 6-9. In the presence of glucan, however, its glucosidic linkage was cleaved, and the glucosyl moiety liberated was transferred to glycogen with the formation of a new alpha-1,4-glucosidic linkage. Allosteric activator AMP accelerated the reaction and allosteric inhibitor glucose 6-phosphate showed the reverse effect. The pH optimum of the reaction was pH 8.1-8.4. Mg2+ slightly but significantly accelerated the reaction, whereas Mn2+ and Ca2+ inhibited the reaction. These results indicate that the glucosyltransfer from the triphospho compound occurs in an identical manner to that from the diphospho compound. Based on the present and previous data, we discuss the catalytic mechanism of phosphorylase, especially in comparison with that of phosphoryltransferases.     

Investigations of the MceIJ-catalyzed posttranslational modification of the microcin E492 C-terminus: linkage of ribosomal and nonribosomal peptides to form "trojan horse" antibiotics

MceIJ is a two protein complex responsible for attachment of a C-glycosylated and linearized derivative of enterobactin, an iron scavenger (siderophore) and product of nonribosomal peptide synthetase machinery, to the C-terminal serine residue of microcin E492 (MccE492), an 84 aa ribosomal antibiotic peptide produced by Klebsiella pneumoniae RYC492. The MceIJ-catalyzed formation of the glycosyl ester linkage between MccE492 and the siderophore requires ATP and Mg(II) as cofactors. This work addresses the ATP utilization, mechanism of C-terminal carboxylate activation, and substrate scope of MceIJ. Formation of the ribosomal peptide-nonribosomal peptide linkage between the MccE492 C-terminal decapeptide and monoglycosylated enterobactin (MGE) requires cleavage of the alpha,beta bond of ATP and formation of a putative peptidyl-CO-AMP intermediate. Attack of the peptidyl-CO-AMP carbonyl by the deprotonated C4' hydroxyl of the glucose moiety forms a glycosyl ester linkage with release of AMP. Site-directed mutagenesis of the three cysteines and five histidines in MceI to alanines reveals that these residues are not required structurally or catalytically. MceIJ recognizes all glycosylated enterobactin derivatives formed by the MccE492 gene cluster members MceC ( C-glycosyltransferase) and MceD (esterase) in vitro and a MGE derivative lacking the C6' hydroxyl moiety. The protein complex also accepts and modifies the C-terminal decapeptide substrate fragments of the structurally related microcins H47, I47, and M. MccE492 C-terminal decapeptides bearing fluorescein and biotin moieties on the N-terminus are also substrates for MceIJ, which provides a route for the chemoenzymatic synthesis of enterobactin conjugates with peptide linkages.     

An outer membrane enzyme that generates the 2-amino-2-deoxy-gluconate moiety of Rhizobium leguminosarum lipid A

The structures of Rhizobium leguminosarum and Rhizobium etli lipid A are distinct from those found in other Gram-negative bacteria. Whereas the more typical Escherichia coli lipid A is a hexa-acylated disaccharide of glucosamine that is phosphorylated at positions 1 and 4', R. etli and R. leguminosarum lipid A consists of a mixture of structurally related species (designated A-E) that lack phosphate. A conserved distal unit, comprised of a diacylated glucosamine moiety with galacturonic acid residue at position 4' and a secondary 27-hydroxyoctacosanoyl (27-OH-C28) as part of a 2' acyloxyacyl moiety, is present in all five components. The proximal end is heterogeneous, differing in the number and lengths of acyl chains and in the identity of the sugar itself. A proximal glucosamine unit is present in B and C, but an unusual 2-amino-2-deoxy-gluconate moiety is found in D-1 and E. We now demonstrate that membranes of R. leguminosarum and R. etli can convert B to D-1 in a reaction that requires added detergent and is inhibited by EDTA. Membranes of Sinorhizobium meliloti and E. coli lack this activity. Mass spectrometry demonstrates that B is oxidized in vitro to a substance that is 16 atomic mass units larger, consistent with the formation of D-1. The oxidation of the lipid A proximal unit is also demonstrated by matrix-assisted laser desorption ionization time-of-flight mass spectrometry in the positive and negative modes using the model substrate, 1-dephospho-lipid IV(A). With this material, an additional intermediate (or by product) is detected that is tentatively identified as a lactone derivative of 1-dephospho-lipid IV(A). The enzyme, presumed to be an oxidase, is located exclusively in the outer membrane of R. leguminosarum as judged by sucrose gradient analysis. To our knowledge, an oxidase associated with the outer membranes of Gram-negative bacteria has not been reported previously.     

(1)H NMR studies of hydroxy protons of the V[beta-Gal(1-->3)-alpha-GalNAc(1-->O)]THPGY glycopeptide.

The hydroxy protons of the disaccharide moiety in the glycopeptide Val-[beta-Gal(1-->3)-alpha-GalNAc(1-->O)]-Thr-His-Pro-Gly-Tyr (1) have been investigated in aqueous solution using (1)H NMR spectroscopy. The chemical shifts (delta), coupling constants ((3)J(CH,OH)), temperature coefficients (d delta/dT), exchange rates (k(ex)), and NOEs have been measured. The data show that the O(2')H of Gal has a reduced contact with water due to steric interference caused by the 2-acetamido group of GalNAc. No interaction, in terms of hydrogen bonding exists between the disaccharide and the peptide moieties, but the rotation around the sugar-peptide linkage is restricted.     

Development of functional imidazole derivatives: the influence of alkaline metal cations on the rates of CL reactions of 2-(phenyl and 4-dimethylaminophenyl)-4-hydroperoxy-4-3',4'-(15-crown-5)phenyl-5-3'-4'-(15-crown-5)phenyl-4H-isoimidazoles.

Although several investigations have focused on luminescence modulation by chelation with metal cations using bidentate ligands or crown ether systems, a bis(crown ether) system has not yet been used for modulation of chemiluminescence (CL) reactions. In the CL reaction of 2-(phenyl and 4-dimethylaminophenyl)-4-hydroperoxy-4-3',4'-(15-crown-5)phenyl-5-3',4'(15-crown-5)phenyl-4H-isoimidazoles 2a and b possessing a bis(15-crown-5 ether) moiety, the rate acceleration was observed in the presence of K(+), Rb(+) and Cs(+) due to the holding effect of the bis-crown moiety, but no rate acceleration was observed by Li(+) and Na(+) due to the template effect of the crown moiety. The acceleration of the CL reaction rates is ascribable to the conformational change induced by the scissor-like motion of the bis-crown moiety assisted by the holding effect.     

Synthesis and properties of a novel bridged nucleic acid analogue, 5'-amino-3',5'-BNA

An oligonucleotide P3'-->N5' phosphoramidate (5'-amino-DNA) attracts much attention because of its potential for application to DNA sequencing; however, its ability to hybridize with complementary strands is low. To overcome this drawback of the 5-amino-DNA, we have designed and successfully synthesized a novel nucleic acid analogue having a P3'-->N5' phosphoramidate linkage and a constrained sugar moiety, 5'-amino-3'-C,5'-N-methylene bridged nucleic acid (5'-amino-3',5'-BNA). The binding affinity of the 5'-amino-3',5'-BNA towards complementary DNA and RNA strands was investigated by UV melting experiments. The melting temperature (Tm) of the duplex comprising the 5'-amino-3',5'-BNA and its complementary strand was much higher than that of the duplex containing the corresponding 5-amino-DNA.     

Nucleosides and nucleotides. 192. Toward the total synthesis of cyclic ADP-carbocyclic-ribose. Formation of the intramolecular pyrophosphate linkage by a conformation-restriction strategy in a syn-form using a halogen substitution at the 8-position of the adenine ring

The synthesis of cyclic ADP-carbocyclic-ribose (2), as a stable mimic for cyclic ADP-ribose, was investigated. Construction of the 18-membered backbone structure was successfully achieved by condensation of the two phosphate groups of 19, possibly due to restriction of the conformation of the substrate in a syn-form using an 8-chloro substituent at the adenine moiety. SN2 reactions between an optically active carbocyclic unit 8, which was constructed by a previously developed method, and 8-bromo-N6-trichloroacetyl-2',3'-O-isopropylideneadenosine 9c gave N-1-carbocyclic derivative, which was deprotected to give 5'-5"-diol derivatives 18. When 18 was treated with POCl3 in PO(OEt)3, the bromo group at the 8-position was replaced to give N-1-carbocyclic-8-chloroadenosine 5',5"-diphosphate derivative 19 in 43% yield. Treatment of 19 with 1-(3-dimethylaminopropyl)-3-ethylcarbodiimide hydrochloride gave the desired intramolecular condensation product 20 in 10% yield. This is the first chemical construction of the 18-membered backbone structure containing an intramolecular pyrophosphate linkage of a cADPR-related compound with an adenine base.     

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.     

Why do all lariat RNA introns have adenosine as the branch-point nucleotide? Conformational study of naturally-occurring branched trinucleotides and its eleven analogues by 1H-, 31P-NMR and CD spectroscopy

1H-NMR conformational studies of six branched triribonucleotides where the branch-point nucleotide was either U, C or G (4-9) have been carried out by assigning 1H resonances through 2D NMR and then observing the temperature-dependent (i) chemical shifts of the aromatic and the anomeric protons, and (ii) shifts of the equilibrium of N and S pseudorotamer populations of each sugar moiety. The data have been compared with those of 2'----5' dimers (1-3) and other branched trimers (10-16). It emerged that all the branched trimers (4-16) adopt a conformational state closer to the corresponding 2'----5' dimers than the corresponding 3'----5' dimers. A temperature-dependent 31P chemical shift study confirmed that the conformational constraint is mainly associated with the 2'----5' phosphate linkage. Although, it appeared with the CD data that when C or especially when U is at the branch-point the overall constraint is weak. This suggests that even if these trimers adopt a 2'----5' dimer geometry, there is a lack of stabilization by strong stackings within the molecule. This is in sharp contrast with the results found for A (10-16) and to a smaller extent for G (8, 9) at the branch-point.     

Synthesis and biological evaluation of some novel triazol-3-ones as antimicrobial agents

A new series of triazol-3-one derivatives bearing 4-methyl-4H-thieno[3',2': 5,6]thiopyrano[4,3-d][1,3]thiazolyl or 4-(thiophene-3-yl) thiazolyl moiety at 4-position and alkyl substitution at 2-position are synthesized. All the synthesized compounds are characterized by elemental analysis, IR, (1)H NMR, (13)C NMR, and mass spectral data. The newly synthesized compounds are screened for antifungal and antibacterial activities.     

Human low-molecular-mass kininogen. Amino-acid sequence of the light chain; homology with other protein sequences

The chemical structure of the polysaccharide moiety of the lipopolysaccharide Rhodopseudomonas sphaeroides ATCC 17023 was established. Mild acetic acid hydrolysis of isolated lipopolysaccharide, followed by preparative high-voltage paper electrophoresis afforded three oligosaccharides. They were characterized by chemical and physicochemical studies to be: GlcA(alpha 1----4)dOclA8P, Thr(6') GlcA(alpha 1----4)GlcA and GlcA(alpha 1----4)dOclA, where GlcA is D-glucuronic acid and dOc1A is 3-deoxy-D-manno-octulosonic acid. Carboxyl-reduction of the lipopolysaccharide followed by acid hydrolysis gave a trisaccharide: GlcA(alpha 1----4)Glc(alpha 1----4)Glc, showing the presence of three residues of glucuronic acids in the O-specific chain and indicating that only two of them are reducible by NaBH4. The linkage between the polysaccharide and lipid A was shown to be through a single 1,4-linked residue of dOc1A attached by a 2,6'-linkage to the lipid A moiety.     

On the structural significance of the linkage region constituents of N-glycoproteins: an X-ray crystallographic investigation using models and analogs

The linkage region constituents, namely, 2-acetamido-2-deoxy-beta-D-glucopyranose and asparagine are conserved in the N-glycoproteins of all the eukaryotes. The present work is aimed at understanding the reasons for the occurrence of GlcNAc and Asn as the linkage region constituents. A total of six sugar amides have been designed as models and analogs of the linkage region and their crystal structures have been solved. This is the first report on the X-ray crystallographic investigation of the effect of systematic changes in the linkage sugar as well as its aglycon moiety on the N-glycosidic torsion, psi(N) (O5-C1-N1-C1(')). This also forms the first report on the crystal structure of a model of L-RhabetaAsn, a variant linkage found in the surface layer glycoprotein of Bacillus stearothermophillus. Among the models and analogs examined, the acetamido derivatives of Man and Xyl, the linkage sugars of O-glycoproteins, show a psi(N) value of -114.5 degrees and -121.2 degrees, respectively, deviating maximum from the value of -89.8 degrees reported for the model compound GlcNAcbetaNHAc. The L-Rha and Gal derivatives also show noticeable deviations. The psi(N) values, -89.5 degrees and -91.0 degrees, of the propionamide derivatives of Glc and GlcNAc (analogs of GlcbetaGln and GlcNAcbetaGln, respectively) agree well with those (-93.8 degrees and -89.8 degrees ) reported for their corresponding acetamide derivatives suggesting Gln could serve as well as Asn as the linkage region amino acid. However, the rotational freedom about the additional C-C bond would lead to altered rigidity of the linkage region. An analysis of packing reveals that the molecular assembly of these compounds is driven by different infinite and finite chains of hydrogen bonds. The double pillaring of hydrogen bonds involving the amide groups at C1 and C2 is seen as a unique packing feature characteristic of beta-1-N-acyl derivatives of GlcNAc. Based on the findings of the present study, it is speculated that the linkage region constituents of the eukaryotic N-glycoproteins appear to fulfill three essential structural requirements: rigidity, planarity, and linearity and these are met by the trisaccharide core and Asn at the linkage region.     

Specificity of elongation factor Tu from Escherichia coli with respect to attachment to the amino acid to the 2' or 3'-hydroxyl group of the terminal adenosine of tRNA.

Modified Tyr-tRNATyr and Phe-tRNAPhe species from yeast having the aminoacyl residue bound specifically to the 2' and 3' position of the terminal adenosine, respectively, were investigated for their ability to form ternary complexes with Escherichia coli elongation factor Tu and GTP. Both Tyr-tRNATyr-CpCpA (2'd) and Tyr-tRNATyr-CpCpA(3' d) derivatives which are esterified with the amino acid on the 3' and 2' position respectively and which lack the vicinal hydroxyl were able to form ternary complexes. The stability of these ternary complexes was lower than in the case of native Tyr-tRNATyr-CpCpA. Tyr-tRNATyr-CpCpA(3' d) having the amino acid attached to the 2' position interacted considerably more strongly with EF-Tu - GTP than Tyr-tRNATyr-CpCpA(2' d). Ternary complex formation was observed with neither Phe-tRNAPhe-CpCpA(2'NH2) nor Phe-tRNAPhe-CpCpA(3'NH2). It is concluded that 2' as well as 3' isomers of native aminoacyl-tRNA can be utilized for ternary complex formation but in a following step a uniform 2'-aminoacyl-tRNA - EF-Tu - GTP complex is formed. Although the free vicinal hydroxyl group of the terminal adenosine is not absolutely required, replacement of the ester linkage through with the amino acid is attached to tRNA by an amide linkage leads to loss of ability to interact with elongation factor Tu.