The mechanisms of amino acids synthesis by high temperature shock-waves

The mechanisms of amino acids syntheses behind high temperature shock-waves were elucidated and distinction was made between the steps occurring in the gas phase and those occurring in solution. In the presence of water vapor, aldehydes and NCN are formed separately in regions of different temperatures along the reacting gas. The aldehydes and ammonia condense to aldimines which add HCN to form α-amino nitriles, all in the gas phase. The hydrolysis to amino acids takes place in solution. In the absence of water vapor, aldimines and NCN are formed in the gas phase but condense to α-amino nitriles only in solution. A fair amount of oxygen only lowers the production of amino acids, which consequently could still be produced in the presence of oxygen in the Earth's primitive atmosphere. The waterless mechanism can operate in the Jovian atmosphere and supply it with ample amounts of amino acids, especially aspartic.     

Shock synthesis of amino acids II

The synthesis of amino acids behind shock waves in methane, ethane, ammonia, and water vapor was further investigated. Aldehydes and HCN and formed separately in the non-homogeneous gas during the high temperature period and recombine with ammonia during the thermal quench period, to form -amino nitriles. The -amino nitriles are either hydrolyzed by excess water vapor during the quench period or emerge as such after the reaction is completed. A combined gas chromatograph-mass spectrometer analysis of the reaction product showed identical amounts of D and L amino acids, thus confirming the absence of contaminants. Thunder shock waves were shown to be a suitable source of energy for the production of amino acids.     

Conversion of alpha-amino acids and peptides to nitriles and aldehydes by bromoperoxidase

Pure bromoperoxidase from the marine alga, Penicillus capitatus, converts alpha-amino acids and peptides to the corresponding decarboxylated nitriles and aldehydes in the presence of hydrogen peroxide and bromide ion. Thus, both valine and valylvaline are converted to isobutyronitrile and isobutyraldehyde while alanine is converted to acetonitrile and acetaldehyde. The reaction is nonstereospecific and can be catalyzed by bromoperoxidases obtained from different sources. Bromoperoxidase catalyzes the conversion of methoxytyrosine to p-methoxyphenylacetonitrile. This reaction is consistent with the involvement of bromoperoxidase in the formation of aeroplysinin-1, a brominated aromatic nitrile antibiotic produced by a marine sponge.     

HCN: A plausible source of purines,pyrimidines and amino acids on the primitive earth

Dilute (0.1 M) solutions of HCN condense to oligomers at pH 9.2. Hydrolysis of these oligomers yields 4,5-dihydroxypyrimidine, orotic acid, 5-hydroxyuracil, adenine, 4-aminoimidazole-5-carboxamide and amino acids. These results, together with the earlier data, demonstrate that the three main classes of nitrogen-containing biomolecules, purines, pyrimidines and amino acids may have originated from HCN on the primitive earth. The observation of orotic acid and 4-aminoimidazole-5-carboxyamide suggests that the contemporary biosynthetic pathways for nucleotides may have evolved from the compounds released on hydrolysis of HCN oligomers.     

Efficient protocols for the synthesis of enantiopure gamma-amino acids with proteinogenic side chains.

The synthesis of enantiopure gamma-substituted gamma-amino acids with proteinogenic side chains, starting from the corresponding natural alpha-amino acids, was studied. N-Protected amino aldehydes containing various protective groups were prepared from the corresponding amino alcohols by oxidation with NaOCl in the presence of AcNH-TEMPO and directly reacted with methyl, benzyl and tert-butyl phosphoranylidene acetate to produce alpha,beta-unsaturated gamma-amino esters. Simultaneous hydrogenation of the double bond and removal of either the benzyl or benzyloxycarbonyl group led to N- or C-protected gamma-amino acids in high yield. The enantiomeric purity was studied by 1H NMR analysis of Mosher amides and chiral HPLC analysis.     

Complexes of aspartate aminotransferase with hydroxylamine derivatives: spectral studies in solution and in the crystalline state

Hydroxylamine and its derivatives of general formula H2NOR react with aldehydes and aldimines to produce oximes. If R corresponds to the side chain of a natural amino acid, such compounds can be thought of as analogs of the corresponding amino acids, lacking the alpha-carboxylate group. Oximes formed between such compounds and pyridoxal phosphate in the active site of aspartate amino-transferase mimic external aldimine intermediates that occur during catalysis by this enzyme. The properties of oxime derivatives of mitochondrial aspartate aminotransferase with hydroxylamine and 6 compounds H2NOR were studied by absorption spectroscopy and circular dichroism in solution and by linear dichroism in crystals. Stable oximes, absorbing at lambda max congruent to 380 nm and exhibiting a negative Cotton effect, were obtained with the carboxylate-containing compounds. The oximes formed with carboxylate-free compounds showed somewhat different properties and stability. With H-Tyr a stable complex absorbing at lambda max congruent to 370 nm rather than at 380 nm, was obtained, H-Ala and H-Phe produced unstable oximes with the initial absorption band at lambda max congruent to 380 nm that was gradually replaced by a band at lambda max congruent to 340 nm. The species absorbing at 340 nm were shown to be coenzyme-inhibitor complexes which were gradually released from the enzyme. A similar 330-340 nm absorption band was observed upon reaction of the free coenzyme with all hydroxylamine inhibitors at neutral pH-values. The results of the circular dichroism experiments in solution and the linear dichroism studies in microcrystals of mAspAT indicate that the coenzyme conformation in these inhibitor/enzyme complexes is similar to that occurring in an external aldimine analogue, the 2-MeAsp/mAspAT complex. Co-crystallizations of the enzyme with the H2NOR compounds were also carried out. Triclinic crystals were obtained in all cases, suggesting that the "closed" structure cannot be stabilized by a single carboxylate group.     

Synthesis of biomolecules from N2, CO,and H2O by electric discharge

A model primitive gas containing a mixture of N₂, CO and water vapor over a water pool (300 mL, 37 °C) was subjected to electric discharges. The discharge vessel (7 L in volume) was equipped with a CO₂ absorber (The CO₂ being formed during the discharge), thus simulating possible absorption of CO₂ in the primitive ocean. The vessel also has a cold trap ( –15 °C), which protects the primary products against the further decomposition in the discharge phase by enabling these products to adhere to the trap. Since the partial pressures of CO and N₂ decreased at rates of 1.5–1.7 cmHg day^–1 and 0.1–0.2 cmHg day^–1, respectively, the gases were added at regular intervals. The solution was analyzed at regular intervals for HCN, HCHO and urea, and maximum concentrations of about 50, 2, and 140 mM were observed. The discharge phase was continued for 6 months. In the solution, glycine (5.6% yield based on the carbon), glycylglycine (0.64%), orotic acid (0.004%) and small amounts of the other amino acids were found.     

Interaction of pyridoxal-5-phosphate with human serum albumin and pancreatic ribonuclease

Pyridoxal-5-phosphate (in a lesser degree, pyridoxal) interacts with both non-protonated and protonated exposed epsilon-amino groups of lysine residues and with alpha-amino groups in human serum albumin and pancreatic ribonuclease A. The reaction of Schiff base formation proceeds within a wide pH range--from 3.0 to 12.0. At a great pyridoxal-5-phosphate excess in ribonuclease A in neutral or slightly acidic aqueous media all the ten epsilon-amino groups of lysine residues and the alpha-amino groups of Lys-1 become modified. The formation of aldimine bonds of pyridoxal-5-phosphate with protonated amino groups in acidic media is determined by ionization of its phenol hydroxyl and phosphate residues. Acetaldehyde, propionic aldehyde and pyridine aldehyde interact only with non-protonated amino groups of the proteins. The equilibrium constants of pyridoxal-5-phosphate and other aldehydes binding to proteins and amino acids were determined. The rate constants of Schiff base formation for pyridoxal-5-phosphates with some amino acids and primary sites of proteins for direct and reverse reactions were calculated.     

Reactions of aminomalononitrile with electrophiles

Aminomalononitrile (HCN trimer) reacts with electrophiles such as aldehydes and acrylonitrile under very mild conditions of temperature and pH to produce intermediates which, after acid hydrolysis, yield amino acids. The following amino acids have been identified and quantitated: glycine, D, L-erythro- and D, L-threo-beta - hydroxyaspartic acids, D, L glutamic acid, and D, L-threonine and allo-threonine. The mechanism of their formation and the possible significance of these reactions in prebiotic syntheses are discussed.     

Dynamic Co-evolution of Peptides and Chemical Energetics, a Gateway to the Emergence of Homochirality and the Catalytic Activity of Peptides

We propose a scenario for the dynamic co-evolution of peptides and energy on the primitive Earth. From a multi component system consisting of hydrogen cyanide, several carbonyl compounds, ammonia, alkyl amine, carbonic anhydride, borate and isocyanic acid, we show that the reversibility of this system leads to several intermediate nitriles, that irreversibly evolve to alpha-amino acids and N-carbamoyl amino acids via selective catalytic processes. On the primitive Earth these N-carbamoyl amino acids combined with energetic molecules (NOx) may have been the core of a molecular engine producing peptides permanently and assuring their recycling and evolution. We present this molecular engine, a production example, and its various selectivities. The perspectives for such a dynamic approach to the emergence of peptides are evoked in the conclusion.     

Synthesis of N-carboxyalkyl and N-aminoalkyl functionalized dipeptide building units for the assembly of backbone cyclic peptides.

To improve the assembly of backbone cyclic peptides, N-functionalized dipeptide building units were synthesized. The corresponding N-aminoalkyl or N-carboxyalkyl amino acids were formed by alkylation or reductive alkylation of amino acid benzyl or tert-butyl esters. In the case of N-aminoalkyl amino acid derivatives the aldehydes for reductive alkylation were obtained from N,O-dimethyl hydroxamates of N-protected amino acids by reduction with LiAlH4. N-carboxymethyl amino acids were synthesized by alkylation using bromoacetic acid ester and the N-carboxyethyl amino acids via reductive alkylation using aldehydes derived from formyl Meldrums acid. Removal of the carboxy protecting group leads to free N-alkyl amino acids of very low solubility in organic solvents, allowing efficient purification by extraction of the crude product. These N-alkyl amino acids were converted to their tetramethylsilane-esters by silylation with N,O-bis-(trimethylsilyl)acetamide and could thus be used for the coupling with Fmoc-protected amino acid chlorides or fluorides. To avoid racemization the tert-butyl esters of N-alkyl amino acids were coupled with the Fmoc-amino acid halides in the presence of the weak base collidine. Both the N-aminoalkyl and N-carboxyalkyl functionalized dipeptide building units could be obtained in good yield and purity. For peptide assembly on the solid support, the allyl type protection of the branching moiety turned out to be most suitable. The Fmoc-protected N-functionalized dipeptide units can be used like any amino acid derivative under the standard conditions for Fmoc-solid phase synthesis.     

Bronchoalveolar lavage examined by solid phase microextraction, gas chromatography--mass spectrometry and selected ion flow tube mass spectrometry

Samples (210 in total) of broncholaveolar lavages (BALs), obtained from patients hospitalized with pneumonia in various departments of two hospitals, were analysed using the method of solid phase microextraction-gas chromatography (SPME-GC) with FID detection. Up to 20% (9% unequivocally, 11% probably) of these samples was found to contain volatile fatty acids (VFAs) in the series from acetic acid to heptanoic acid. Importantly, the presence of these acids indicates the presence of fermenting anaerobic bacteria, which were not detected by the conventional microbiological examination. Other compounds, namely the heptanol and cyclohexanone, were also detected by this method in some samples. Cyclohexanone occurred almost exclusively in samples from patients receiving intensive care with mechanical ventilation, and is suspected to originate from plastic parts of ventilators. Selected representative samples were also analysed using further methods, namely gas chromatography-mass spectrometry (GC-MS) of native and silylated samples, and selected ion flow tube mass spectrometry (SIFT-MS). These methods confirmed the identities of above mentioned compounds, and detected numerous other compounds tentatively identified as various alcohols, aldehydes, ketones, esters and hydrogen cyanide, HCN. Most of these compounds occurred in small amounts and their origin and diagnostic significance remains uncertain, except, that is, for the HCN, which indicates the presence of Pseudomonas aeruginosa.     

On the formation of amino acids deriving from spermidine and spermine.

Evidence obtained from experiments with rats and mice is presented suggesting that the naturally occurring amino acids putreanine and N8-(2-carboxyethyl)spermidine, and most probably also related compounds deriving from the polyamines spermidine and spermine by oxidative metabolism, are formed within two anatomical compartments. In the first step polyamines are converted into aldehydes by serum spermine oxidase in the circulation. A certain portion of these aldehydes can be taken up by liver and other organs and transformed by aldehyde dehydrogenase into the corresponding amino acids. Putreanine is not only derived from spermidine, but can also be formed from N8-(2-carboxyethyl)spermidine by oxidative deamination, catalysed by serum spermine oxidase, and subsequent spontaneous elimination of acrolein.     

Mass spectra of alpha-amino acid oxazolidinones

2-Bis-(chlorodifluoromethyl)-4-substituted-1,3-oxazolidin-5-ones, a new type of alpha-amino acid derivative for gas chromatographic separation, have been studied by low resolution mass spectrometry. These derivatives are obtained by reacting alpha-amino acids with dichlorotetrafluoroacetone. Their structure has been established or confirmed for most protein amino acids and several non-protein alpha-amino acids. The mechanisms responsible for the mass spectral pattern have been rationalized. An interesting feature of this derivatization procedure is that it distinguishes aspartic and glutamic acid from the respective amides. The structure of asparagine and glutamine derivatives has been established. A survey of oxazolidinone mass spectra has provided a list of diagnostically useful ions. Each amino acid can be identified by one or two of its most abundant fragments.     

Role of Ferrocyanides in the Prebiotic Synthesis of α-Amino Acids

We investigated the synthesis of α-amino acids under possible prebiotic terrestrial conditions in the presence of dissolved iron (II) in a simulated prebiotic ocean. An aerosol-liquid cycle with a prebiotic atmosphere is shown to produce amino acids via Strecker synthesis with relatively high yields. However, in the presence of iron, the HCN was captured in the form of a ferrocyanide, partially inhibiting the formation of amino acids. We showed how HCN captured as Prussian Blue (or another complex compound) may, in turn, have served as the HCN source when exposed to UV radiation, allowing for the sustained production of amino acids in conjunction with the production of oxyhydroxides that precipitate as by-products. We conclude that ferrocyanides and related compounds may have played a significant role as intermediate products in the prebiotic formation of amino acids and oxyhydroxides, such as those that are found in iron-containing soils and that the aerosol cycle of the primitive ocean may have enhanced the yield of the amino acid production.     

Trace elements in chemical evolution

Electric discharge experiments have been performed in a plausible primitive earth atmosphere consisting of methane, nitrogen, and water over an aqueous phase of an ammonia-ammonium buffer solution. In some experiments, ions of metal elements, calcium, magnesium, zinc, iron and molybdenum were introduced. Gas phase products and amino acids in the liquid phase were analyzed by gas chromatography. With trace metal ions, less organic compounds in the gas phase and larger amounts of amino acids were obtained than without them. The results have shown the possible importance of trace elements in chemical evolution and the origin of life on the earth.     

2,3-butanedione as a photosensitizing agent: application to alpha-amino acids and alpha-chymotrypsin

2,3-Butanedione sensitized the rapid photodestruction of free alpha-amino acids, and the photoinactivation of alpha-chymotrypsin, in the presence of ultraviolet light and oxygen. These reactions showed "pseudo-first-order" kinetics at 2,3-butanedione concentrations approximating those employed for the chemical modification of arginine residues in proteins. The photoreactions were inhibited in anoxic media or in the presence of azide; findings were consistent with a singlet oxygen mechanism for these reactions. No enhancement in the rate of reaction was observed in D2O. The rate of 2,3-butanedione-sensitized photodestruction of free amino acids increased with increasing pH. However, the rate constants for the photosensitized inactivation of alpha-chymotrypsin, as well as those for the photodestruction of the tryptophan residues of this enzyme, decreased linearly with increasing pH.     

The transport of L-alanine by the hamster kidney cell line BHK-21-C13.

The uptake of L-alanine into BHK21-C13 cells in culture has been studied. This amino acid appears to be transported essentially via a relatively low affinity, high capacity, sodium ion dependent transport system. Inhibition studies using other amino acids or their analogues provided information about the specificity of this system. This alanine transport system was shown to exhibit a broad substrate specificity and appeared to be capable of transporting most naturally occurring neutral alpha-amino acids. Kinetic studies of the inhibition of L-alanine uptake also indicated the presence of a second neutral amino acid transport system capable of transporting this amino acid. However, it is unlikely that this second uptake system contributes greatly to L-alanine uptake. Inhibition of the uptake of L-leucine indicated that this transport system has a similar specificity to the "L"-system initially described for Ehrlich ascites carcinoma cells.     

Reactions of N-hydroxysulfosuccinimide active esters

N-Hydroxysulfosuccinimide esters are reactive functional groups employed in a variety of protein modification reagents, especially cross-linking reagents. For these compounds, hydrolysis is the most important reaction competing for reaction of the esters with nucleophilic groups in proteins. We have employed model compounds to investigate the rates of hydrolysis of N-hydroxysulfosuccinimide esters and their reactions with the alpha-amino group and the side chains of naturally occurring amino acids, under conditions comparable to those used for protein modification studies. The rats of hydrolysis observed were found to be very low, as compared with their rates of reaction with nitrogen nucleophiles found in proteins. Further, within the ranges investigated, the rate of aminolysis was observed to increase more rapidly than the rate of hydrolysis with increasing pH or with increasing temperature. Four amino acid side chains and the alpha-amino group were found to react measurably with N-hydroxysulfosuccinimide esters. At pH 7.4 and room temperature, the order of reactivity was found to be N alpha-Cbz-histidine greater than N alpha-Cbz-lysine approximately phenylalanine (alpha-amino group) much greater than N-acetylcysteine approximately N-acetyltyrosine; however, the acylimidazole adduct formed with the side chain of histidine was found to be a transient product, subject to hydrolysis or reaction with another nucleophile.     

Hepatic microsomal oxygenation of aldehydes to carboxylic acids

Hepatic microsomal oxygenation of aldehydes to carboxylic acids was investigated. Aldehydes (veratrum aldehyde, cinnamic aldehyde, myrtenal, cuminaldehyde, 3-phenylpropionaldehyde, perillaldehyde and 9-anthraldehyde) were incubated with hepatic microsomes of mice in the presence of an NADPH-generating system under 18O2 (97 atom%). The incorporation of oxygen-18 into carboxylic acids formed was determined by gas chromatography-mass spectrometry. Oxygen-18 was incorporated into the carboxylic acids formed from all aldehyde substrates examined. Hepatic microsomal formation of 3,4-dimethoxybenzoic acid and cumic acid from veratrum aldehyde and cuminaldehyde, respectively, was inhibited by CO and SKF 525-A. These results indicate that the oxygenation of aldehydes which may be catalyzed by cytochrome P450 is a common reaction in the biotransformation of xenobiotic aldehydes.