Evidence of amino acids in hydrolysates of compounds formed by ionizing radiations. II. Aqueous solutions of CH3CN and C2H5CN

It has been shown that the action of ionizing radiations on dilute, oxygen-free, aqueous solutions of acetonitrile and propionitrile leads to the formation of oligomers, which upon hydrolyses release amino acids. The presence of nine amino acids, the same as those found in irradiated aqueous cyanides, has been established. those amino acids with asymmetric carbon atoms separated by GC method, appeared to consist of nearly equal amounts of D and L isomers. Glycine is the most abundant amino acid in hydrolysates of acetonitrile, while alanine appears in the samples of propionitrile. A comparison of all amino acids, identified in hydrolysates of various cyanides and nitriles, suggests that it is the cyano group, and a free-radical initiated mechanism, that is primarily involved in these radiation-chemical changes of potential interest to prebiotic chemistry.     

Evidence for amino acids in hydrolysates of compounds formed by ionizing radiations

Dilute, O₂-free aqueous cyanides were exposed to multikilorad doses of a radioactive cobalt source. After the removal of unreacted cyanides and of volatile radiolytic products, the residue was ydrolyzed and the resulting material analyzed for amino acids. The results show the presence of five protein amino acids and five amino acids which do not occur in natural proteins. The amino acids of enantiomeric derivatives separated on an optically active column, appeared to consist of approximately equal amounts of D and L isomers. Radiation-chemical yields of amino acids were determined at various radiation doses. The results obtained support the previous findings that the free-radical initiated process is the source of oligomers which on hydrolysis release the amino acids.     

Formation of amino acids from aliphatic nitriles and aliphatic amines by contact glow discharge electrolysis

Contact glow discharge electrolyses (CGDE) were carried out relative to the prebiotic formation of amino acids by amination of aliphatic nitrile in aqueous ammoniacal solution, and by cyanization of aliphatic amine by sodium cyanide. The CGDE of propionitrile by amination followed by hydrolysis resulted in the formation of glycine, alanine and β-alanine. The reaction of ethylamine by cyanization, gave glycine, alanine, β-alanine, aspartic acid, and serine. In these reactions, a relatively high ratio of glycine was observed. This could be explained by the cleavage of the α,β-carbon bond, which was broken easily, due to the strong electron-attracting property of the nitrile group of propionitrile and the resulting α-aminopropionitrile.     

Enzymatic degradation of nitriles by Klebsiella oxytoca

Klebsiella oxytoca, isolated from cyanide-containing wastewater, was able to utilize many nitriles as sole source of nitrogen. The major objective of this study was to explore the ability of K. oxytoca to utilize some nitriles and then further evaluate the pathways of transformation of cyanide compounds by K. oxytoca. Results from this study indicate that succinonitrile and valeronitrile were the most optimal sources of nitrogen for the growth of K. oxytoca. The biodegradation of acetonitrile proceeded with the formation of acetamide followed by acetic acid. The production of ammonia was also detected in this biodegradation experiment. Similar results were observed in the propionitrile biodegradation experiments. Collectively, this study suggests that the breakdown of acetonitrile or propionitrile by this bacterium was via a two-step enzymatic hydrolysis with amides as the intermediates and organic acids plus with ammonia as the end products.     

On the nitrile effect in L-rhamnopyranosylation

It is shown that the use of 5% acetonitrile or propionitrile in dichloromethane functions to increase the beta-selectivity of a number of L-rhamnopyranosylation reactions conducted by the thioglycoside method with activation by the 1-benzenesulfinyl piperidine/trifluoromethanesulfonic anhydride couple. The use of more significant quantities of acetonitrile or propionitrile results in the formation of complex reaction mixtures containing little coupled product, but from which Ritter-type products can be isolated.     

Papain in organic solvents: determination of conditions suitable for biocatalysis and the effect on substrate specificity and inhibition

Synthesis of N-CBZ-(N-Carbobenzoxy)-1-amino-acid methyl esters from N-CBZ-amino acids and methanol has been used as an assay to examine the properties of papain in organic solvents containing small amounts of water. Papain is active in solvents ranging in polarity from acetonitrile to tetrachloromethane. The optimal activity in each solvent varied only about three to four fold, but the amount of added water required to achieve it varied from 4% (v/v) in acetonitrile to 0.05% (v/v) in tetrachloromethane. The enzyme was generally more stable in hydrophobic solvents and at lower water contents. The apparent K(m) value of CBZ-glycine was 26 times higher in acetonitrile than in toluene due to differential partitioning of the substrate between aqueous and organic phases. The substrate specificity of the enzyme was qualitatively little different from that in aqueous solution, with amino acid derivatives still the best substrates. Nitrile analogs of substrates inhibited the enzyme, as they do in aqueous solution, and inhibition by a variety of substituted aromatic hydrocarbons showed that the main specificity of papain for hydrophobic side chains at its S(2) subsite, was little affected. The results show that papain can catalyze reactions under a variety of conditions in organic solvents but its substrate specificity is little changed from that in aqueous media.     

Protease-catalyzed incorporation of non-protein amino acids into peptides via the kinetically controlled approach

Through the kinetically controlled approach, employing the methyl ester as an acyl donor, non-protein aliphatic amino acids were incorporated into peptides using papain in an aqueous buffer, while the incorporation of non-protein aromatic amino acids was achieved by exploiting -chymotrypsin in an aqueous buffer or acetonitrile with low water content. © Rapid Science Ltd. 1998     

Amino acid analysis at the picomole level. Application to the C-terminal sequence analysis of polypeptides.

Amino acids labelled with dimethylaminoazobenzenesulphonyl chloride can be separated by reversed-phase high-pressure liquid chromatography and detected in the visible region (436 nm). All 19 naturally occurring amino acids can be separated on a Zorbax ODS column by employing two different gradient systems consisting of an acetonitrile/aqueous buffer mixture. As little as 2--5 pmol of an individual dimethylaminoazobenzenesulphonyl-amino acid can be quantitatively analysed with reliability, and only 10--30 ng of the dimethylaminoazobenzenesulphonylated protein hydrolysate is needed for each complete amino acid analysis. This new technique is as sensitive as any of the current amino acid analysis methods involving ion-exchange separation plus fluorescence detection, and is technically much simpler. By the combination of this sensitive amino acid-analysing technique with carboxypeptidase, we have been able to determine the C-terminal sequence of polypeptides at the picomole level.     

Utilization of aliphatic nitrile by Paracoccus sp. SKG isolated from chemical waste samples

A bacterial strain Paracoccus sp. SKG capable of utilizing acetonitrile as a sole source of carbon and nitrogen was isolated from the chemical waste samples. The molecular phylogram generated using the complete sequence of 16S rDNA of the strain SKG showed close links to the bacteria grouped under Brucellaceae family, that belongs to the class alphaproteobacteria. Specifically, the 16S rDNA sequence of strain SKG has shown 99% similarity to Paracoccus sp. This bacterium has also shown impressive growth on aliphatic nitriles like acetonitrile, propionitrile, acrylonitrile, valeronitrile and their corresponding amides. The nitriles degradation has led to the accumulation of ammonia and respective carboxylic acids. The acetonitrile grown cells showed the release of ammonia that contributes to the increase in pH of the medium. However, glucose grown cells failed to produce ammonia, thus indicating the inducible nature of acetonitrile degrading enzymes in Paracoccus sp. SKG. Nitrile hydratase and amidase are the two key enzymes involved in the degradation of acetonitrile. Degradation of acetonitrile in Paracoccus sp. SKG follows the bi-enzymatic pathway. Further, this strain is capable of degrading acetonitrile in the presence of other organic solvents such as methanol, ethanol and dimethylformamide. Therefore, this strain is efficiently used for the treatment of HPLC waste stream containing acetonitrile in the presence of other organic solvents.     

The cyanide hydratase enzyme of Fusarium lateritium also has nitrilase activity

The filamentous fungus Fusarium lateritium produces cyanide hydratase when grown in the presence of cyanide. The cyanide hydratase protein produced at a high level in Escherichia coli shows a low but significant nitrilase activity with acetonitrile, propionitrile and benzonitrile. The nitrilase activity is sufficient for growth of the recombinant strain on acetonitrile, propionitrile or benzonitrile as the sole source of nitrogen. The recombinant enzyme shows highest nitrilase activity with benzonitrile. Site-directed mutagenesis of the F. lateritium cyanide hydratase gene indicates that mutations leading to a loss of cyanide hydratase activity also lead to a loss of nitrilase activity. This suggests that the active site for cyanide hydratase and nitrilase activity in the protein is the same. This is the first evidence of cyanide hydratase having nitrilase activity.     

Constitutive acetonitrile hydrolysing activity of Nocardia globerula NHB-2: Optimization of production and reaction conditions

Nocardia globerula NHB-2 exhibited an intracellular acetonitrile hydrolysing activity (AHA) when cultivated in nutrient broth supplemented with glucose (10.0 g/l) and yeast extract (1.0 g/l), at pH 8.0, 30 degrees C for 21 hr. Maximum AHA was recorded in the culture containing 0.1 M of sodium phosphate buffer, (pH 8.8) at 45 degrees C for 15 min with 600 micromol of acetonitrile and resting cells of N. globerula NHB-2 equivalent to 1.0 ml culture broth. This activity was stable up to 40 degrees C and was completely inactivated at or above 60 degrees C. About five-fold increase in AHA was observed after optimization of culture and reaction conditions. Under the optimized conditions, this organism hydrolyzed various nitriles and amides such as propionitrile, benzonitrile. acetamide, and acrylamide to corresponding acids. This nitrile/amide hydrolysing activity of N. globerula NHB-2 has potential applications in enzymatic synthesis of organic acids and bioremediation of nitriles and amides contaminated soil and water system.     

Metabolism of acetonitrile and propionitrile by Nocardia rhodochrous LL100-21.

Six nitrile compounds and two amide derivatives were degraded by Nocardia rhodochrous LL100-21. Acetonitrile, hydroacrylonitrile, and propionitrile were the best sources of carbon and nitrogen for growth, whereas butenenitrile, succinonitrile, and acetamide supported less growth. Acrylonitrile and acrylamide supported growth but only as a source of nitrogen. Gas chromatography of the culture medium revealed a decrease in acetonitrile with the sequential formation of acetamide and acetic acid. Ammonia was also detected by colorimetric procedures. The enzyme system responsible for the hydrolysis of acetonitrile was shown to be intracellular and inducible. The breakdown of acetonitrile by a crude bacterial extract was a two-step enzymatic hydrolysis with acetamide as the intermediate product and acetic acid and ammonia as the final products. Product formation was stoichiometric with substrate disappearance. When propionitrile was the growth substrate, there was complete conversion of the nitrile to propionic acid and ammonia as the major products. The enzymatic breakdown of the propionitrile, although slower than acetonitrile, yielded the corresponding carboxylic acid and ammonia. Propionamide was produced in very small amounts as an intermediate product.     

Aneuploidy in Drosophila, IV. Inhalation studies on the induction of aneuploidy by nitriles

The Drosophila ZESTE system was used to monitor the induction of sex chromosome aneuploidy following inhalation exposure of adult females to four nitriles: acetonitrile, propionitrile, acrylonitrile and fumaronitrile. Acetonitrile and propionitrile were highly effective aneuploidogens, inducing both chromosome loss and chromosome gain following brief exposures to low concentrations of these chemicals, and these nitriles also induced rapid paralysis. Acrylonitrile-induced chromosome loss only but did not induce paralysis. Fumaronitrile, in contrast with the results reported in yeast, was ineffective in inducing chromosome loss or gain. Virtually all exceptional offspring induced by acetonitrile and propionitrile were recovered in the first sampled eggs, corresponding to treated mature oocytes. Additionally, the time interval between treatment and sampling was shown to be important, suggesting rapid loss or detoxification of the nitriles. Genetic analysis demonstrated that most aneuploids resulted from induced segregation errors during the first division of meiosis. Cold treatments were found to be ineffective in enhancing the effects of acetonitrile, suggesting important differences between the Drosophila and yeast aneuploidy detection systems. Possible mechanisms by which nitriles may disrupt chromosome segregation in Drosophila oocytes are considered.     

Chloroformates in gas chromatography as general purpose derivatizing agents

Chloroformates with simplest alkyls, i.e. methyl, ethyl or isobutyl, already known as favourable reagents for treating amino groups in gas chromatography for years, were revealed randomly as exceptionally rapid esterification agents. Unlike the rather poor results achieved with chloroformate-mediated ester formation in organic chemistry, the pyridine-catalyzed esterification of carboxylic acids appeared to proceed at the analytical microscale smoothly. Along with the catalyzer, an alcohol should also be present in the medium, accompanied by acetonitrile or water, according to the character of the compounds treated. Reaction conditions were optimized for various classes of carboxylic acids and a uniquely rapid derivatization of amino acids in aqueous ethanol was shown to be possible. Most of the analytes, e.g. acidic metabolites in physiological fluids, could be treated directly in the aqueous matrix. A simultaneous analysis of, e.g., amino and fatty acids or amines and their acidic catabolytes was proven to be possible. Along with the low-molecular-mass reagents, still some others, i.e. the hexyl, menthyl or pentafluorobenzyl ones, found their application fields. Results of optimized reaction conditions and a wide range of applications of chloroformate-mediated derivatization in various disciplines have been summarized in this review.     

Utilization of nitriles by yeasts isolated from a Brazilian gold mine

Yeast strains from the genera Candida, Debaryomyces, Aureobasidium, Geotrichum, Pichia, Rhodotorula, Tremella, Hanseniaspora, and Cryptococcus were isolated from samples of a gold mine from liquid extraction circuit. These strains were tested for their ability to utilize acetonitrile at 12 mM as the sole nitrogen source. The yeasts that grew using acetonitrile at 12 mM were tested in the presence of acetonitrile, isobutyronitrile, methacrylnitrile, and propionitrile at concentrations of 12, 24, 48, 97, and 120 mM. One strain was selected for each nitrile and the concentration of nitrile in which the best growth occurred. Cryptococcus sp. strain UFMG-Y28 had a better growth on 120 mM propionitrile and 97 mM acetonitrile, Rhodotorula glutinis strain UFMG-Y5 on 48 mM methacrylnitrile, and Cryptococcus flavus strain UFMG-Y61 on 120 mM isobutyronitrile. The utilization of different nitriles and amides by yeast strains involves hydrolysis in a two-step reaction mediated by both inducible and intracellular nitrile hydratase and amidase.     

Substrate specificity of alpha-chymotrypsin-catalyzed esterification in organic media.

11 amino acid derivatives were tested as alpha-chymotrypsin substrates in the esterification reaction with methanol in organic media. The reactions were carried out in water-saturated ethyl acetate and in acetonitrile containing 4% water. alpha-Chymotrypsin adsorbed on Celite was used as a catalyst. From initial reaction rate measurements, the Michaelis-Menten parameters Vmax and KM were determined. All the amino acid derivatives tested were esterified, and the highest values of kcat/KM were obtained with the N-acylated aromatic amino acids. Correlations between Michaelis-Menten parameters and physical properties of the substrates such as molar refractivity (MR) and log P were deduced. The results show that the specificity of the alpha-chymotrypsin towards the side chain of the amino acids in organic media is the same as that in aqueous media. However, the specificity towards the N-protecting group is opposite to that in water, so the reaction medium affects the interaction of this part of the molecule with the enzyme to a large extent.     

Optimization of acetonitrile co-solvent and copper stoichiometry for pseudo-ligandless click chemistry with nucleic acids

The copper(I) catalyzed azide-alkyne cycloaddition 'click' reaction yields a specific product under mild conditions and in some of the most chemically complex environments. This reaction has been used extensively to tag DNA, proteins, glycans and only recently RNA. Click reactions in aqueous buffer typically include a ligand for Cu(I), however we find that acetonitrile as a minor co-solvent can serve this role. Here we investigate the click labeling of RNA and DNA in aqueous buffer to determine the relationship between the stoichoimetry of Cu(I) and the acetonitrile co-solvent that affects nucleic acid stability. We find that very low concentrations of acetonitrile perform equally well and obviate the need for any additional Cu(I) stabilizing ligand. These pseudo-ligandless reaction conditions are optimal for nucleic acids click conjugations.     

Partial molar volumes of some alpha-amino acids in aqueous sodium acetate solutions at 308.15 K

The apparent molar volumes V(2,phi) have been determined for glycine, DL-alpha-alanine, DL-alpha-amino-n-butyric acid, DL-valine and DL-leucine in aqueous solutions of 0.5, 1.0, 1.5 and 2.0 mol kg(-1) sodium acetate by density measurements at 308.15 K. These data have been used to derive the infinite dilution apparent molar volumes V(0)(2,phi) for the amino acids in aqueous sodium acetate solutions and the standard volumes of transfer, Delta(t)V(0), of the amino acids from water to aqueous sodium acetate solutions. It has been observed that both V(0)(2,phi) and Delta(t)V(0) vary linearly with increasing number of carbon atoms in the alkyl chain of the amino acids. These linear correlations have been utilized to estimate the contributions of the charged end groups (NH(3)(+), COO(-)), CH(2) group and other alkyl chains of the amino acids to V(0)(2,phi) and Delta(t)V(0). The results show that V(0)(2,phi) values for (NH(3)(+), COO(-)) groups increase with sodium acetate concentration, and those for CH(2) are almost constant over the studied sodium acetate concentration range. The transfer volume increases and the hydration number of the amino acids decreases with increasing electrolyte concentrations. These facts indicate that strong interactions occur between the ions of sodium acetate and the charged centers of the amino acids. The volumetric interaction parameters of the amino acids with sodium acetate were calculated in water. The pair interaction parameters are found to be positive and decreased with increasing alkyl chain length of the amino acids, suggesting that sodium acetate has a stronger dehydration effect on amino acids which have longer hydrophobic alkyl chains. These phenomena are discussed by means of the co-sphere overlap model.     

Amphipathic control of the 3(10)-/alpha-helix equilibrium in synthetic peptides.

A series of short, amphipathic peptides incorporating 80% C(alpha),C(alpha)-disubstituted glycines has been prepared to investigate amphipathicity as a helix-stabilizing effect. The peptides were designed to adopt 3(10)- or alpha-helices based on amphipathic design of the primary sequence. Characterization by circular dichroism spectroscopy in various media (1 : 1 acetonitrile/water; 9 : 1 acetonitrile/water; 9 : 1 acetonitrile/TFE; 25 mM SDS micelles in water) indicates that the peptides selectively adopt their designed conformation in micellar environments. We speculate that steric effects from ith and ith + 3 residues interactions may destabilize the 3(10)-helix in peptides containing amino acids with large side-chains, as with 1-aminocyclohexane-1-carboxylic acid (Ac(6)c). This problem may be overcome by alternating large and small amino acids in the ith and ith + 3 residues, which are staggered in the 3(10)-helix.     

Application of statistical design for the optimization of amino acid separation by reverse-phase HPLC

Modified resolution and overall separation factors used to quantify the separation of complex chromatography systems are described. These factors were proven to be applicable to the optimization of amino acid resolution in reverse-phase (RP) HPLC chromatograms. To optimize precolumn derivatization with phenylisothiocyanate, a 2^5-1 fractional factorial design in triplicate was employed. The five independent variables for optimizing the overall separation factor were triethylamine content of the aqueous buffer, pH of the aqueous buffer, separation temperature, methanol/acetonitrile concentration ratio in the organic eluant, and mobile phase flow rate. Of these, triethylamine concentration and methanol/acetonitrile concentration ratio were the most important. The methodology captured the interaction between variables. Temperature appeared in the interaction terms; consequently, it was included in the hierarchic model. The preliminary model based on the factorial experiments was not able to explain the response curvature in the design space; therefore, a central composite design was used to provide a quadratic model. Constrained nonlinear programming was used for optimization purposes. The quadratic model predicted the optimal levels of the variables. In this study, the best levels of the five independent variables that provide the maximum modified resolution for each pair of consecutive amino acids appearing in the chromatograph were determined. These results are of utmost importance for accurate analysis of a subset of amino acids.