Spectroscopic investigation of nickel cation binding with adenine mononucleotides: stability and structure of the 1:2 complex with adenosine 5′-monophosphate

 The interaction of Ni(II) ions with adenine mononucleotides (5′-AMP, 3′-AMP, 2′-AMP, 2′,3′-cAMP, 3′,5′-cAMP) was studied in aqueous solution using Raman spectroscopy and ¹³C and ³¹P NMR paramagnetic relaxation measurements. Macrochelate structures were observed to form for all non-cyclic AMPs, with increasing stability in the series: 3′-AMP < 2′-AMP < 5′-AMP. N7 of adenine was found to be the key site of the Ni(II)-adenine interaction for all non-cyclic AMPs. For 2′-AMP, an alternative binding to the pyrimidine ring may also exist. The dependence of Raman spectra on AMP and Ni(II) concentration confirmed the existence of a stable 1 : 2 Ni(II)-(5′-AMP) complex, besides the 1 : 1 complexes. In this complex, the adenine moieties of both 5′-AMP molecules are situated close to Ni(II), and their relative orientations with respect to the cation are very similar. The paramagnetic relaxation enhancements of the carbons indicate that the nickel ion is not located in the plane of the adenine units, but that the line connecting Ni(II) and N7 deviates strongly from the adenine planes. Phosphates are outer-sphere coordinated by the cation. Findings from both methods have led us to propose possible global architectures of the complex. Received: 26 June 1998 / Accepted: 22 July 1998     

Deoxyribosyl analogues of methionyl and isoleucyl sulfamate adenylates as inhibitors of methionyl-tRNA and isoleucyl-tRNA synthetases

2'-Deoxy, 3'-deoxy, and 2',3'-dideoxyribosyl surrogates of isoleucyl and methionyl sulfamate adenylates have been investigated to identify the pharmacophoric importance of the ribose group for the inhibition of Escherichia coli methionyl-tRNA (MRS) and isoleucyl-tRNA (IRS) synthetases. Molecular modeling of 2',3'-dideoxyribosyl Met-NHSO2-AMP (9) with the crystal structure of E. coli MRS revealed that the lack of the two hydroxyl groups on ribose was compensated by the formation of an extra hydrogen bond between the ring oxygen and His24, resulting in a small activity reduction.     

N-Acetyl-D and L-esters of 5′-AMP hydrolyze at different rates

Studies of the properties of aminoacyl derivatives of 5′-AMP are aimed at understanding the origin of the process of protein synthesis. Aminoacyl (2′,3′) esters of 5′-AMP can serve as models of the 3′-terminus of aminoacyl tRNA. We report here on the relative rates of hydrolysis of AC -D - and L -Phe AMP esters as a function of pH. At all pHs above 3, the rate constant of hydrolysis of the AC -L -Phe ester is 1.7 to 2.1 times that of AC -D -Phe ester. The D -isomer seems partially protected from hydrolysis by a stronger association with the adenine ring of the 5′-AMP. © 1993 Wiley-Liss, Inc.     

Studies on 5′-Nucleotidase-Lacking Mutants Derived from Bacillus subtilis

Two 5′-nucleotidase-lacking mutants, R–42 and A–1, were derived from an adenine-requiring mutant, B. subtilis 1145–2–83, which has productivity of both inosine and hypoxanthine. Strain A–1 accumulated 5′-IMP as well as inosine and hypoxanthine, and strain R–42 accumulated 5′-IMP and 5′-GMP as well as inosine and hypoxanthine in their culture fluids. These mutants responded to either adenine or adenosine, but did not to 5′-AMP. This fact suggests that adenine or adenosine may be incorporated into the cells, but 5′-AMP may neither be incorporated into the cells nor be degraded during culture. 5′-GMP was converted to 5′-IMP, and 5′-AMP was phosphrylated to ADP in the growing culture of strain A–1.     

Modes of Binding of 2′-AMP to RNase T1 A Computer Modeling Study

Abstract

The modes of binding of adenosine 2′-monophosphate (2′-AMP) to the enzyme ribonuclease (RNase) T₁ were determined by computer modelling studies. The phosphate moiety of 2′-AMP binds at the primary phosphate binding site. However, adenine can occupy two distinct sites - (1) The primary base binding site where the guanine of 2′-GMP binds and (2) The subsite close to the N1 subsite for the base on the 3′-side of guanine in a guanyl dinucleotide. The minimum energy conformers corresponding to the two modes of binding of 2′-AMP to RNase T₁ were found to be of nearly the same energy implying that in solution 2′-AMP binds to the enzyme in both modes. The conformation of the inhibitor and the predicted hydrogen bonding scheme for the RNase T₁ - 2′-AMP complex in the second binding mode (S) agrees well with the reported x-ray crystallographic study. The existence of the first mode of binding explains the experimental observations that RNase T₁ catalyses the hydrolysis of phosphodiester bonds adjacent to adenosine at high enzyme concentrations. A comparison of the interactions of 2′-AMP and 2′-GMP with RNase T₁ reveals that Glu58 and Asn98 at the phosphate binding site and Glu46 at the base binding site preferentially stabilise the enzyme - 2′-GMP complex.     

Purification, characterization, and sequencing of antimicrobial peptides, Cy-AMP1, Cy-AMP2, and Cy-AMP3, from the Cycad (Cycas revoluta) seeds

Novel antimicrobial peptides (AMP), designated Cy-AMP1, Cy-AMP2, and Cy-AMP3, were purified from seeds of the cycad (Cycas revoluta) by a CM cellulofine column, ion-exchange HPLC on SP COSMOGEL, and reverse-phase HPLC. They had molecular masses of 4583.2 Da, 4568.9 Da and 9275.8 Da, respectively, by MALDI–TOF MS analysis. Half of the amino acid residues of Cy-AMP1 and Cy-AMP2 were cysteine, glycine and proline, and their sequences were similar. The sequence of Cy-AMP3 showed high homology to various lipid transfer proteins. For Cy-AMP1 and Cy-AMP2, the concentrations of peptides required for 50% inhibition (IC₅₀) of the growth of plant pathogenic fungi, Gram-positive and Gram-negative bacteria were 7.0–8.9 μg/ml. The Cy-AMP3 had weak antimicrobial activity. The structural and antimicrobial characteristics of Cy-AMP1 and Cy-AMP2 indicated that they are a novel type of antimicrobial peptide belonging to a plant defensin family.     

Synthesis of a reactive ATP analog and its preliminary application as an affinity labeling reagent

A reactive ATP analog, N6-(6-bromoacetamidohexyl)-AMP.PCP, was synthesized in an attempt to covalently label the binding sites for adenine nucleotides, especially ATP, of various enzymes which utilize adenine nucleotides as substrates, cofactors, inhibitors or allosteric effectors. This reagent rapidly inactivated rabbit muscle glyceraldehyde 3-phosphate dehydrogenase (GPD), myokinase (MK), and creatine kinase (CK) under very mild conditions. Adenine nucleotide substrates prevented the inactivation. In the case of GPD, complete inactivation was observed when 1 mol of the reagent per mol of enzyme subunit was incorporated into the enzyme. These results indicate that the present ATP analog may be useful as an affinity labeling reagent for various adenine nucleotide-dependent enzymes.     

Separation of cyclic AMP from adenine and hypoxanthine, their nucleosides and nucleotides by high voltage paper electrophoresis.

A simple and rapid technique which permits the separation of cyclic AMP, adenine, adenosine, hypoxanthine, inosine, 5′-AMP, IMP, ADP, and ATP by the use of unidirectional high-voltage paper electrophoresis has been described. The separation of these compounds based on their charge difference utilizes the following properties: (1) the protonation of the NH₂ group of the adenine, (2) the primary and secondary ionization of the phosphate group of the nucleotides, and (3) the formation of the chelated oxyderivative of boron with the two cis (OH) groups of the ribose moieties of nucleosides and nucleotides.     

Proofreading in trans by an aminoacyl-tRNA synthetase: a model for single site editing by isoleucyl-tRNA synthetase.

Editing of errors in amino acid selection by an aminoacyl-tRNA synthetase prevents attachment of incorrect amino acids to tRNA, thereby greatly enhancing accuracy of translation of the genetic code. Editing of the non-protein amino acid homocysteine, a frequent type of an error-correcting process, involves reaction of the side chain sulfhydryl group of homocysteine with its activated carboxyl group forming a cyclic thioester, homocysteine thiolactone. Here, it is shown that isoleucyl-tRNA synthetase (IleRS), which occasionally misactivates homocysteine in vitro and in vivo, catalyzes reactions of activated isoleucine with organic thiols (analogues of the side chain of homocysteine). That these enzymatic reactions occur between Ile-tRNAIle or Ile-AMP (bound in the synthetic sub-site) and a thiol (an analogue of the side chain of homocysteine, bound in the editing sub-site), indicates that the two sub-sites are physically close on the surface of IleRS, forming a single synthetic/editing active site of the enzyme. Although IleRS.Val-AMP undergoes thiolysis as efficiently as do IleRS.Ile-AMP and IleRS.Ile-tRNAIle, IleRS.Val-tRNAIle does not react with thiols. These and other data suggest that the mischarged valine residue in IleRS.Val-tRNAIle is, most likely, positioned off the enzyme.     

Extracellular 2��,3��-cAMP Is a Source of Adenosine

We discovered that renal injury releases 2′,3′-cAMP (positional isomer of 3′,5′-cAMP) into the interstitium. This finding motivated a novel hypothesis: renal injury leads to activation of an extracellular 2′,3′-cAMP-adenosine pathway (i.e. metabolism of extracellular 2′,3′-cAMP to 3′-AMP and 2′-AMP, which are metabolized to adenosine, a retaliatory metabolite). In isolated rat kidneys, arterial infusions of 2′,3′-cAMP (30 μmol/liter) increased the mean venous secretion of 3′-AMP (3,400-fold), 2′-AMP (26,000-fold), adenosine (53-fold), and inosine (adenosine metabolite, 30-fold). Renal injury with metabolic inhibitors increased the mean secretion of 2′,3′-cAMP (29-fold), 3′-AMP (16-fold), 2′-AMP (10-fold), adenosine (4.2-fold), and inosine (6.1-fold) while slightly increasing 5′-AMP (2.4-fold). Arterial infusions of 2′-AMP and 3′-AMP increased secretion of adenosine and inosine similar to that achieved by 5′-AMP. Renal artery infusions of 2′,3′-cAMP in vivo increased urinary excretion of 2′-AMP, 3′-AMP and adenosine, and infusions of 2′-AMP and 3′-AMP increased urinary excretion of adenosine as efficiently as 5′-AMP. The implications are that 1) in intact organs, 2′-AMP and 3′-AMP are converted to adenosine as efficiently as 5′-AMP (previously considered the most important adenosine precursor) and 2) because 2′,3′-cAMP opens mitochondrial permeability transition pores, a pro-apoptotic/pro-necrotic process, conversion of 2′,3′-cAMP to adenosine by the extracellular 2′,3′-cAMP-adenosine pathway would protect tissues by reducing a pro-death factor (2′,3′-cAMP) while increasing a retaliatory metabolite (adenosine).     

Purification,Characterization, and Sequencing of a Novel Type of Antimicrobial Peptides,Fa-AMP1 and Fa-AMP2, from Seeds of Buckwheat (Fagopyrum esculentum Moench.)

Novel antimicrobial peptides (AMP), designated Fa-AMP1 and Fa-AMP2, were purified from the seeds of buckwheat (Fagopyrum esculentum Moench.) by gel filtration on Sephadex G75, ion-exchange HPLC on SP COSMOGEL, and reverse-phase HPLC. They were basic peptides having isoelectric points of over 10. Fa-AMP1 and Fa-AMP2 had molecular masses of 3,879 Da and 3,906 Da on MALDI-TOF MS analysis, and their extinction coefficients in 1% aqueous solutions at 280 nm were 42.8 and 38.9, respectively. Half of all amino acid residues of Fa-AMP1 and Fa-AMP2 were cysteine and glycine, and they had continuous sequences of cysteine and glycine. The concentrations of peptides required for 50% inhibition (IC₅₀) of the growth of plant pathogenic fungi, and Gram-positive and -negative bacteria were 11 to 36 μg/ml. The structural and antimicrobial characteristics of Fa-AMPs indicated that they are a novel type of antimicrobial peptides belonging to a plant defensin family.     

精胺对牛肝tRNA~(lle)氨基酰化的刺激作用

本实验用纯化的牛肝异亮氨酸tRNA(tRNA~(Ile))和异亮氨酰tRNA合成酶(IleRS),研究了精胺对Ile-tRNA复合物形成及IleRS活性的作用。结果表明:精胺能特异地促使牛肝tRNA~(Ile)氨基酰化反应;对IleRS活性无影响;能明显地增加形成Ile-tRNA复合物反应的Vmax和tRNA~(Ile)的Km值。     

Affinity labeling of adenine nucleotide-related enzymes with reactive adenine nucleotide analogs. I. Affinity labeling of glyceraldehyde 3-phosphate dehydrogenase and myokinase with a reactive AMP analog.

Rabbit muscle glyceraldehyde 3-phosphate dehydrogenase (GPD) and myokinase (MK) were rapidly inactivated by a reactive AMP analog, N6-(p-bromoacetaminobenzyl)-AMP, under mild conditions. Complete inactivation was observed when 4 and 0.3 mol of the reagent with respect to enzyme were reacted with GPD and MK, respectively. The inactivation of both enzymes were favored at higher pH and the enzymes were protected by addition of adenine nucleotide substrate. Modified GPD or MK had no affinity for AMP-Sepharose, in contrast to the native enzymes. From these results, the inactivation of GPD and MK by the reactive AMP analog can be regarded as an affinity labeling. The posibility that the present AMP analog may be used as a general affinity labeling reagent for various adenine nucleotide-related enzymes is discussed based on the results obtained.     

Purification and Some Properties of Adenosine (Phosphate) Deaminase from the Liver of the Squid Todarodes pacificus

An enzyme that catalyzed the deamination of adenosine 3′-phenylphosphonate was purified from squid liver to homogeneity as judged by SDS-PAGE. The molecular weight of the enzyme was estimated to be 60,000 by SDS-PAGE and 140,000 by Sephadex G-150 gel filtration. The enzyme deaminated adenosine, 2′-deoxyadenosine, 3′-AMP, and 2′,3′-cyclic AMP, but not adenine, 5′-AMP, 3′,5′-cyclic AMP, ADP, or ATP. The apparent K_m and V_max at pH 4.0 for these substrates were comparable (0.11-0.34mM and 179-295 μmol min^?1 mg^?1, respectively). The enzyme had maximum activity at pH 3.5-4.0 for adenosine 3′-phenylphosphonate, at pH 5.5 for adenosine and 2′-deoxyadenosine, and at pH 4.0 for 2′,3′-cyclic AMP and 3′-AMP when the compounds were at concentration of 0.1 mM. The K_m at 4.0 and 5.5 for each substrate varied, but the Vmax were invariant. These results indicated that the squid enzyme was a novel adenosine (phosphate) deaminase with a unique substrate specificity.     

The interactions between nucleic acids and polyamines: I. High resolution carbon-13 and hydrogen-1 nuclear magnetic resonance studies of spermidine and 5'-AMP

In 0.5 M solution at pH 7.6, interaction of spermidine and 5'-AMP is demonstrated by downfield proton NMR shifts. Shifts of ribose and adenine protons support a model in which triprotonated spermidine engages the phosphate, anion with the C-3 diamine segment in a conformation to maximize interaction and the C-4 ammo segment extended to interact with adenine N-7 (base anti, 2'endo, g'g' and gg nucleoside conformation). Changes in carbon-13 chemical shifts for ribose C-5' (downfield), C-2' C-3', and C-4' (upfield) and for adenine C-6 and C-8 (upfield) support this model. In 0.006 M solution no significant changes in proton shifts and therefore no evidence for interaction was found. Spermidine and 5'-UMP (0.006 M) showed interaction at pH 10.5 (small upfield shifts in the proton nmr) interpreted as changing conformation by solvent interaction. In 0.006 M 3'-UMP at pH 10.5 small downfield proton shifts induced by spennidine are attributed to interactions with phosphate anion.     

Crystal structures of the CP1 domain from Thermus thermophilus isoleucyl-tRNA synthetase and its complex with L-valine

Isoleucyl-tRNA synthetase (IleRS) links tRNA(Ile) with not only its cognate isoleucine but also the nearly cognate valine. The CP1 domain of IleRS deacylates, or edits, the mischarged Val-tRNA(Ile). We determined the crystal structures of the Thermus thermophilus IleRS CP1 domain alone, and in its complex with valine at 1.8- and 2.0-A resolutions, respectively. In the complex structure, the Asp(328) residue, which was shown to be critical for the editing reaction against Val-tRNA(Ile) by a previous mutational analysis, recognizes the valine NH(3)(+) group. The valine side chain binding pocket is only large enough to accommodate valine, and the placement of an isoleucine model in this location revealed that the additional methylene group of isoleucine would clash with His(319). The H319A mutant of Escherichia coli IleRS reportedly deacylates the cognate Ile-tRNA(Ile) in addition to Val-tRNA(Ile), indicating that the valine-binding mode found in this study represents that in the Val-tRNA(Ile) editing reaction. Analyses of the Val-tRNA(Ile) editing activities of T. thermophilus IleRS mutants revealed the importance of Thr(228), Thr(229), Thr(230), and Asp(328), which are coordinated with water molecules in the present structure. The structural model for the Val-adenosine moiety of Val-tRNA(Ile) bound in the IleRS editing site revealed some interesting differences in the substrate binding and recognizing mechanisms between IleRS and T. thermophilus leucyl-tRNA synthetase. For example, the carbonyl oxygens of the amino acids are located opposite to each other, relative to the adenosine ribose ring, and are differently recognized.     

Nonprotein amino acid furanomycin, unlike isoleucine in chemical structure, is charged to isoleucine tRNA by isoleucyl-tRNA synthetase and incorporated into protein

Nonprotein amino acid furanomycin was found to bind with Escherichia coli isoleucyl-tRNA synthetase (IleRS) almost as tightly as the substrate L-isoleucine. The conformation of furanomycin bound to the enzyme was determined by NMR analyses including the transferred nuclear Overhauser effect method. The conformation of IleRS-bound furanomycin was similar to that of L-isoleucine, although the chemical structure of furanomycin is unlike that of L-isoleucine. By E. coli IleRS, E. coli tRNAIle was charged with furanomycin as efficiently as with L-isoleucine. Furthermore, furanomycyl-tRNAIle was bound to polypeptide chain elongation factor Tu as tightly as isoleucyl-tRNAIle. Furanomycin was found to be incorporated into beta-lactamase precursor by in vitro protein biosynthesis. A newly designed amino acid will probably be incorporated into proteins, provided that the new amino acid takes a similar conformation as a protein-constituting amino acid in the active site of an aminoacyl-tRNA synthetase.     

NMR analyses of the conformations of L-isoleucine and L-valine bound to Escherichia coli isoleucyl-tRNA synthetase

The 400-MHz 1H NMR spectra of L-isoleucine and L-valine were measured in the presence of Escherichia coli isoleucyl-tRNA synthetase (IleRS). Because of chemical exchange of L-isoleucine or L-valine between the free state and the IleRS-bound state, a transferred nuclear Overhauser effect (TRNOE) was observed among proton resonances of L-isoleucine or L-valine. However, in the presence of isoleucyl adenylate tightly bound to the amino acid activation site of IleRS, no TRNOE for L-isoleucine or L-valine was observed. This indicates that the observed TRNOE is due to the interaction of L-isoleucine or L-valine with the amino acid activation site of IleRS. The conformations of these amino acids in the amino acid activation site of IleRS were determined by the analyses of time dependences of TRNOEs and TRNOE action spectra. The IleRS-bound L-isoleucine takes the gauche+ form about the C alpha-C beta bond and the trans form about the C beta-C gamma 1 bond. The IleRS-bound L-valine takes the gauche- form about the C alpha-C beta bond. Thus, the conformation of IleRS-bound L-valine is the same as that of IleRS-bound L-isoleucine except for the delta-methyl group. The side chain of L-isoleucine or L-valine lies in an aliphatic hydrophobic pocket of the active site of IleRS. Such hydrophobic interaction with IleRS is more significant for L-isoleucine than for L-valine. The TRNOE analysis is useful for studying the amino acid discrimination mechanism of aminoacyl-tRNA synthetases.