Multifunctional hydrolytic catalysis: II. Hydrolysis of p-nitrophenyl acetate by a polymer catalyst which contains hydroxamate and imidazole functions

A water-soluble polymer catalyst was prepared by radical polymerization of a protected hydroxamate monomer, 1-methyl-2-vinylimidazole and acrylamide, and by the subsequent NH₂NH₂ treatment of the polymer. The hydrolysis of p-nitrophenyl acetate by the bifunctional copolymer obeyed typical burst kinetics: rapid accumulation of acetyl hydroxamate group and its slow decomposition. The acetylation rate of the hydroxamate group was rather close to that of a polymer which does not contain the imidazole unit. However, the deacylation was markedly accelerated by the presence of the imidazole unit, and the difference in rate constants amounted to 60- to 80-fold at pH 8–9. These results indicate that the overall catalytic efficiency of the bifunctional polymer is enhanced due to the complementary action of the imidazole and hydroxamate functions.     

Bench scale production of benzohydroxamic acid using acyl transfer activity of amidase from Alcaligenes sp. MTCC 10674

The acyl transfer activity of the amidase of Alcaligenes sp. MTCC 10674 has been applied to the conversion of benzamide and hydroxylamine to benzohydroxamic acid. The unique features of the acyl transfer activity of this organism include its optimal activity at 50 °C and very high substrate (100 mM benzamide) and product (90 mM benzohydroxamic acid) tolerance among the hitherto reported enzymes. The bench scale production of benzohydroxamic acid was carried out in a fed-batch reaction (final volume 1 l) by adding 50 mM benzamide and 250 mM of hydroxylamine after every 20 min for 80 min in 0.1 M potassium phosphate buffer (pH 7.0) at 50 °C, using resting cells equal to 4.0 mg dcm/ml of reaction mixture. From 1 l of reaction mixture 33 g of benzohydroxamic acid was recovered with 24.6 g l^?1 h^?1 productivity. The acyl transfer activity of the amidase of Alcaligenes sp. MTCC 10674 and the process developed in the present study are of industrial significance for the enzyme-mediated production of benzohydroxamic acid.     

Metal-binding ability of histidine-containing peptidehydroxamic acids: Imidazole versus hydroxamate coordination

Three new peptidehydroxamic acids (l-alanyl-l-histidinehydroxamic acid, l-Ala-l-HisNHOH, l-alanyl-l-alanyl-l-histidinehydroxamic acid, l-Ala-l-Ala-l-HisNHOH and l-histidyl-l-alaninehydroxamic acid, l-His-l-AlaNHOH) were synthesized and their complexation with Cu(II), Ni(II) and Zn(II) were studied by pH-potentiometric, UV-Vis, CD, ¹H NMR, EPR and ESI-MS methods. Each of the studied peptide derivatives involves one side-chain imidazole unit and the effect of this group on the metal binding of the hydroxamic moiety is evaluated in the paper. The obtained results are compared to those of the complexes of some histidine-containing di- or tripeptides and also to those of hydroxamic derivatives of aliphatic peptides.A competition between the hydroxamate and imidazole functions occurs in all systems, but the extent differs from metal to metal, from ligand to ligand and depends very much on the pH. The imidazole was found to play the most determinant role in the Cu(II) complexes, somewhat less in the Ni(II)-containing ones, while (except the case of l-Ala-l-HisNHOH) negligible role was found in the Zn(II)-complexes. Common feature of the Ni(II)- and especially Cu(II)-containing systems is that if an imidazole-N is displaced by a hydroxamate, imidazole-bridged di- and polynuclear complexes are formed.     

Direct Detection of the Acetate-forming Activity of the Enzyme Acetate Kinase

Acetate kinase, a member of the acetate and sugar kinase-Hsp70-actin (ASKHA) enzyme superfamily^1-5, is responsible for the reversible phosphorylation of acetate to acetyl phosphate utilizing ATP as a substrate. Acetate kinases are ubiquitous in the Bacteria, found in one genus of Archaea, and are also present in microbes of the Eukarya⁶. The most well characterized acetate kinase is that from the methane-producing archaeon Methanosarcina thermophila^7-14. An acetate kinase which can only utilize PP_i but not ATP in the acetyl phosphate-forming direction has been isolated from Entamoeba histolytica, the causative agent of amoebic dysentery, and has thus far only been found in this genus^15,16.In the direction of acetyl phosphate formation, acetate kinase activity is typically measured using the hydroxamate assay, first described by Lipmann^17-20, a coupled assay in which conversion of ATP to ADP is coupled to oxidation of NADH to NAD⁺ by the enzymes pyruvate kinase and lactate dehydrogenase^21,22, or an assay measuring release of inorganic phosphate after reaction of the acetyl phosphate product with hydroxylamine²³. Activity in the opposite, acetate-forming direction is measured by coupling ATP formation from ADP to the reduction of NADP⁺ to NADPH by the enzymes hexokinase and glucose 6-phosphate dehydrogenase²⁴.Here we describe a method for the detection of acetate kinase activity in the direction of acetate formation that does not require coupling enzymes, but is instead based on direct determination of acetyl phosphate consumption. After the enzymatic reaction, remaining acetyl phosphate is converted to a ferric hydroxamate complex that can be measured spectrophotometrically, as for the hydroxamate assay. Thus, unlike the standard coupled assay for this direction that is dependent on the production of ATP from ADP, this direct assay can be used for acetate kinases that produce ATP or PP_i.     

Bioprocess development for nicotinic acid hydroxamate synthesis by acyltransferase activity of Bacillus smithii strain IITR6b2

In this work, acyltransferase activity of a new bacterial isolate Bacillus smithii strain IITR6b2 was utilized for the synthesis of nicotinic acid hydroxamate (NAH), a heterocyclic class of hydroxamic acid. NAH is an important pyridine derivative and has found its role as bioligand, urease inhibitor, antityrosinase, antioxidant, antimetastatic, and vasodilating agents. Amidase having acyltransferase activity with nicotinamide is suitable for nicotinic acid hydroxamate production. However, amidase can also simultaneously hydrolyze nicotinamide and nicotinic acid hydroxamate to nicotinic acid. Nicotinic acid is an undesirable by-product and thus any biocatalytic process involving amidase for nicotinic acid hydroxamate production needs to have high ratios of acyltransferase to amide hydrolase and acyltransferase to nicotinic acid hydroxamate hydrolase activity. Isolate Bacillus smithii strain IITR6b2 was found to have 28- and 12.3-fold higher acyltransferase to amide and hydroxamic acid hydrolase activities, respectively. This higher ratio resulted in a limited undesirable by-product, nicotinic acid (NA) synthesis. The optimal substrate/co-substrate ratio, pH, temperature, incubation time, and resting cells concentration were 200/250 mM, 7, 30 °C, 40 min, and 0.7 mg_DCW ml^?1, respectively, and 94.5 % molar conversion of nicotinamide to nicotinic acid hydroxamate was achieved under these reaction conditions. To avoid substrate inhibition effect, a fed-batch process based on the optimized parameters with two feedings of substrates (200/200 mM) at 40-min intervals was developed and a molar conversion yield of 89.4 % with the productivity of 52.9 g h^?1 g _DCW ^?1 was achieved at laboratory scale. Finally, 6.4 g of powder containing 58.5 % (w/w) nicotinic acid hydroxamate was recovered after lyophilization and further purification resulted in 95 % pure product.     

Spectroscopic characterisation of n-octanohydroxamic acid and potassium hydrogen n-octanohydroxamate

The crystal structure and spectroscopic characteristics of n-octanohydroxamic acid and the potassium compound of that acid have been investigated by XRD, XPS, FTIR and Raman spectroscopy. XRD revealed that the acid is in the keto Z conformation with the alkyl chains oriented along the z-direction and hydrogen bonding between hydroxamate moieties. Vibrational spectra confirm this conclusion. Chemical analysis, XRD and XPS established that the potassium compound is the acid salt KH(C₇H₉CONO)₂. The crystal structure showed that the hydroxamate groups are also in the keto Z conformation and this is supported by vibrational spectra. In the acid salt, the two hydroxamate moieties are connected by a symmetrical O-H-O short hydrogen bonded linkage between the two hydroxamate oxygen atoms and this explains the absence of a discernible O-H stretch band in the vibrational spectra. Identification of the vibrational bands displayed is supported by deuteration and ¹⁵N substitution.     

Appearance of an Alternate Pathway Cyanide-resistant during Germination of Seeds of Cicer arietinum

The combined action of the inhibitors antimycin A and cyanide with benzohydroxamic acid indicates the presence of a cyanide-resistant pathway of respiration in chick pea (Cicer arietinum L.) seeds. The appearance of this pathway takes place during germination. During the first 12 hours of germination, the respiration is predominantly cyanide-sensitive, showing after this time a shift to an “alternate” respiration which is sensitive to benzohydroxamic acid, reaching the maximal cyanide resistance between 72 and 96 hours of germination. The appearance of the alternate pathway is initiated by high O₂ concentrations and depends on cytoplasmic protein synthesis, since its appearance is inhibited by cycloheximide but not by chloramphenicol. Actinomycin D has no effect on the appearance of the alternate pathway. Our results indicate, in agreement with other authors, that the branching point is located between the flavoproteins and cytochromes b, probably at the level of ubiquinone, but the possibility of more than one branching point of the electron flow is also considered.     

Enzyme inhibitor modeling with TpZn complexes of functional hydroxamates and oximates

Salicylhydroxamic acid reacts with the enzyme model Tp^Ph,MeZn-OH to form the O,O-chelating hydroxamate complex 1. The hydrogen bonding capacity of zinc enzyme bound hydroxamates is reproduced by cocrystallization of two molecules if 1 with two molecules of methanol and by cocrystallization of one molecule of Tp^Ph,MeZn-acetohydroxamate with one molecule of 3-phenyl-5-methylpyrazole. The complex formed from Tp^Ph,MeZn-OH and N-tosylproline hydroxamic acid, according to its spectra, contains the hydroxamate as an N,N-chelating ligand. In contrast, the oximate derived from pyruvic aldehyde does not act as a chelating ligand, but is monodentate via the oximate oxygen.     

Iron-Dependent Production of Hydroxamate by Sodium-Dependent Azotobacter chroococcum

The sodium-dependent strain 184 of Azotobacter chroococcum was unable to grow significantly in iron-limited medium, but did produce iron-repressible outer membrane proteins. Siderophores were not produced under these conditions. Citric acid was excreted, but not in response to iron limitation. This strain, however, was able to grow in insoluble mineral iron sources, and under these conditions the cells produced a hydroxamate. Growth on minerals and hydroxamate production was dependent on a low level of freely exchangeable iron. Optimal hydroxamate production was observed with 0.75 μM ferric citrate, and hydroxamate production was repressed by >5 μM iron. Despite this iron requirement, hyroxamate was only formed during internal iron limitation of the cells. Iron-containing cells were able to grow in iron-limited medium but only produced hydroxamate when their iron-per-cellular-protein content was low. These results, the spectral changes observed upon Fe³⁺ addition, and iron-uptake coincident with hydroxamate production suggested that the hydroxamate was a siderophore.     

HSP-72 Accelerated Expression in Mononuclear Cells Induced In Vivo by Acetyl Salicylic Acid Can Be Reproduced In Vitro when Combined with H2O2

Background

Among NSAIDs acetyl salicylic acid remains as a valuable tool because of the variety of benefic prophylactic and therapeutic effects. Nevertheless, the molecular bases for these responses have not been complete understood. We explored the effect of acetyl salicylic acid on the heat shock response.

Results

Peripheral blood mononuclear cells from rats challenged with acetyl salicylic acid presented a faster kinetics of expression of HSP-72 messenger RNA and protein in response to in vitro heat shock. This effect reaches its maximum 2 h after treatment and disappeared after 5 h. On isolated peripheral blood mononuclear cells from untreated rats, incubation with acetyl salicylic acid was ineffective to produce priming, but this effect was mimicked when the cells were incubated with the combination of H₂O₂+ ASA.

Conclusions

Administration of acetyl salicylic acid to rats alters HSP-72 expression mechanism in a way that it becomes more efficient in response to in vitro heat shock. The fact that in vitro acetyl salicylic acid alone did not induce this priming effect implies that in vivo other signals are required. Priming could be reproduces in vitro with the combination of acetyl salicylic acid+H₂O₂.     

Impairment of Photorespiratory Carbon Flow into Rubber by the Inhibition of the Glycolate Pathway in Guayule (Parthenium argentatum Gray)

Cut shoots of guayule (Parthenium argentatum Gray) were treated with four inhibitors of the glycolate pathway (α-hydroxypyridinemethanesulfonic acid; isonicotinic acid hydrazide, glycine hydroxamate, and amino-oxyacetate, AOA) in order to evaluate the role of photorespiratory intermediates in providing precursors for the biosynthesis of rubber. Photorespiratory CO₂ evolution in guayule leaves was severely inhibited by AOA. Application of each of the four inhibitors has resulted in a significantly decreased incorporation of ¹⁴C into rubber fractions suggesting that the glycolate pathway is involved in the biosynthesis of rubber in guayule. However, the application of each of the glycolate pathway inhibitors showed no significant effect on photosynthetic CO₂ fixation in the leaves. The inhibitors individually also reduced the incorporation of labeled glycolate, glyoxylate, and glycine into rubber, while the incorporation of serine and pyruvate was not affected. The effective inhibition of incorporation of glycolate pathway intermediates in the presence of AOA was due to an inhibition of glycine decarboxylase and serine hydroxymethyltransferase. It is concluded that serine is a putative photorespiratory intermediate in the biosynthesis of rubber via pyruvate and acetyl coenzyme A.     

Modifications around the hydroxamic acid chelating group of fosmidomycin,an inhibitor of the metalloenzyme 1-deoxyxylulose 5-phosphate reductoisomerase (DXR)

Fosmidomycin derivatives in which the hydroxamic acid group has been replaced by several bidentate chelators as potential hydroxamic alternatives were prepared and tested against the DXR from Escherichia coli. These results illustrate the predominant role of the hydroxamate functional group as the most effective metal binding group in DXR inhibitors.     

Spectroscopic characterisation of copper acetohydroxamate and copper n-octanohydroxamate

The nature of the bonding in acetohydroxamic acid, copper acetohydroxamate and copper n-octanohydroxamate has been investigated by chemical analysis, XPS, FTIR and Raman spectroscopy. Vibrational spectra show the acid to be in the keto Z conformation as was previously established for the n-octano homologue. Chemical analysis established that the copper compounds have a copper:hydroxamate stoichiometry of 1:1. XPS confirms that they are Cu^II compounds. The absence of vibrational spectral bands that were previously identified with N-H vibrations for n-octanohydroxamic acid and its potassium compound, together with the presence of a CN stretch band that shifts when the nitrogen is labelled with ¹⁵N, confirms that the hydroxamate moieties in the Cu^II compounds are in the enol configuration. Some interaction between Cu and N is indicated by the spectra and could explain the 1:1 stoichiometry of the Cu^II hydroxamates investigated.     

Degradation of diazinon by 2,4-dihydroxy-7-methoxy-2h-1, 4-benzoxazin-3(4h)-one in maize

A cyclic hydroxamate, 2,4-dihydroxy-7-methoxy-2H- 1,4-benzoxazin-3(4H)-one (DIMBOA), was isolated and identified from shoots of 6-day-old corn seedlings grown in the dark. From 100 g of plant tissue 100 mg of DIMBOA were isolated. This hydroxamate was very effective in catalysing the hydrolysis of the pyrimidinyl organophosphate insecticide, diazinon (O, O-diethyl- O-[6- methyl-2-(1-methylethyl)-4-pyrimidinyl] phosphorothioate) to 6- methyl-2-(1-methylethyl)-4-hydroxypyrimidine and diethyl phosphorothioic acid. The optimum pH for hydrolytic activity was 5 and at pH values equal to or higher than the pK_a of the hydroxamic group (6.95) most of the activity was lost.     

Inhibition of glycine decarboxylation and serine formation in tobacco by glycine hydroxamate and its effect on photorespiratory carbon flow

Glycine hydroxamate is a competitive inhibitor of glycine decarboxylation and serine formation (referred to as glycine decarboxylase activity) in particulate preparations obtained from both callus and leaf tissue of tobacco. In preparations from tobacco callus tissues, the K_i for glycine hydroxamate was 0.24 ± 0.03 millimolar and the K_m for glycine was 5.0 ± 0.5 millimolar. The inhibitor was chemically stable during assays of glycine decarboxylase activity, but reacted strongly when incubated with glyoxylate. Glycine hydroxamate blocked the conversion of glycine to serine and CO₂in vivo when callus tissue incorporated and metabolized [1-¹⁴C]glycine, [1-¹⁴C]glycolate, or [1-¹⁴C]glyoxylate. The hydroxamate had no effect on glyoxylate aminotransferase activities in vivo, and the nonenzymic reaction between glycine hydroxamate and glyoxylate did not affect the flow of carbon in the glycolate pathway in vivo. Glycine hydroxamate is the first known reversible inhibitor of the photorespiratory conversion of glycine to serine and CO₂.     

Application of high-performance liquid chromatography to competitive labeling studies: The chemical properties of functional groups of glucaton

A competitive-labeling study of glucagon was carried out using [³H]- and [¹⁴C]-1-fluoro-2,4-dinitrobenzene to determine simultaneously the chemical properties of the α-amino and imidazole groups of the N-terminal histidine residue, and the lysine and tyrosine residues, under conditions where glucagon is in its physiologically active monomer form. The dinitrophenyl derivatives of these groups were purified by high-performance liquid chromatography which greatly simplified the separation steps of the procedure. The results showed the α-amino and tyrosine groups to have relatively normal behavior, with pK values of 7.98 and 10.22, respectively, while the lysine had a low pK of 8.46. The imidazole function had an apparent pK of 7.84, substantially higher than previous estimates. This difference may be accounted for by the effect of the charged form of the adjacent α-amino group on the nucleophilicity of the imidazole group.     

Degradation Pathway and Generation of Monohydroxamic Acids from the Trihydroxamate Siderophore Deferrioxamine B

Siderophores are avid ferric ion-chelating molecules that sequester the metal for microbes. Microbes elicit siderophores in numerous and different environments, but the means by which these molecules reenter the carbon and nitrogen cycles is poorly understood. The metabolism of the trihydroxamic acid siderophore deferrioxamine B by a Mesorhizobium loti isolated from soil was investigated. Specifically, the pathway by which the compound is cleaved into its constituent monohydroxamates was examined. High-performance liquid chromatography and mass-spectroscopy analyses demonstrated that M. loti enzyme preparations degraded deferrioxamine B, yielding a mass-to-charge (m/z) 361 dihydroxamic acid intermediate and an m/z 219 monohydroxamate. The dihydroxamic acid was further degraded to yield a second molecule of the m/z 219 monohydroxamate as well as an m/z 161 monohydroxamate. These studies indicate that the dissimilation of deferrioxamine B by M. loti proceeds by a specific, achiral degradation and likely represents the reversal by which hydroxamate siderophores are thought to be synthesized.     

Ionization constants and thermodynamic parameters of histidine and derivatives

The pK_a values for the proton dissociation of carboxyl, imidazolium, and ammonium groups for histidine and ten of its derivatives were determined electrometrically at seven temperatures in the range 10–40°C. The ΔH and ΔS values were estimated from the temperature dependence of the dissociation constants of histidine and its derivatives. These results and the pK_a values compared in terms of inductive effect suggest an ion-dipole interaction between the protonated amino group and the unprotonated imidazole ring. The charge and the solvation effects of the neighboring groups are the main factors that determine the imidazole group pK_a in histidine and its studied derivatives. The N^τ-H tautomer is favored over the N^π-H by 1.6 kcal/mol, indicating that the inductive substituent effect at position 4 of the imidazole ring is the major component in determining this tautomeric preference.     

Properties of leaf NAD malic enzyme from plants with C4 pathway photosynthesis

C₄ acid decarboxylation in one group of C₄-pathway species is mediated by an NAD malic enzyme. This paper reports on the partial purification and properties of this enzyme from three species of this group, Atriplex spongiosa, Amaranthus edulis, and Panicum miliaceum. Depending upon the conditions, the Atriplex spongiosa enzyme was 5–30% as active with NADP compared with NAD but the enzyme from the other species was specific for NAD. The enzyme from each species had an absolute requirement for Mn²⁺ that could not be replaced by Mg²⁺, and activity was increased several fold by low concentrations of either CoA or acetyl CoA. For the enzyme from Atriplex spongiosa and Amaranthus edulis, there was cooperativity for malate binding and the activators CoA and acetyl CoA functioned to increase the affinity of malate for the enzyme. The Hill coefficients for malate binding were approximately 2 and 4, respectively. However, with the enzyme from Panicum miliaceum, cooperative binding of malate was not apparent and activators operated by increasing V rather than the affinity for malate. Bicarbonate inhibited the enzyme from Atriplex spongiosa and Amaranthus edulis and its effect was inversely related to the concentrations of malate, NAD, and activators. The possible significance of these various allosteric effects on the regulation of the enzyme in vivo is discussed. Reactant concentrations and other conditions required for maximum activity are reported.     

The reactivity of imidazole nitrogens in histidine to alkylation

Copper(II)-histidine complex was allowed to react at pH 6.0–6.1 at 22°C with bromoacetic acid. The reaction was followed by means of amino acid analysis of the histidine and N^im-carboxymethylhistidine derivatives. The results of the alkylation study indicate that the nucleophilic, active histidine molecule is coordinated to the copper(II) ion through the amino nitrogen and a carboxylate oxygen with the imidazole group turned away from the copper. This model of copper-bound histidine permitted the determination of the intrinsic nucleophilic activity of the imidazole nitrogens through their respective rate constants for alkylation. The tele-nitrogen is three times more reactive than the pros-nitrogen in the histidine and in the pros-carboxymethylhistidine-tele-carboxymethylhistidine systems. The carboxymethylation of copper(II)-histidine and bovine pancreatic ribonuclease have some analogies, which suggest that in pros-carboxymethylhistidine-119 ribonuclease the carboxylate unit of the alkylated histidine residue points into the active site.