Enzyme-catalysed deprotection of N-acetyl and N-formyl amino acids

To investigate the full potential of hydrolases for the removal of two amine-protecting groups, 15 different, commercially available lipases, acylases, proteases and esterases were studied for the hydrolyses of N-acetyl and N-formyl protecting groups. In addition to the well-known acylases from porcine kidney and Aspergillus melleus, this screening revealed that porcine liver esterase and the lipases from Rhizomucor miehei and Pseudomonas stutzeri are also catalysts for the hydrolysis of N-acetylalanine. The activity of lipases in this reaction was unexpected, since lipases are commonly believed not to hydrolyse amides. In addition, from these 15 enzymes, three were found to be active in the hydrolysis of N-formylalanine, i.e. porcine liver esterase and the two acylases. This is the first example where esterase is employed to deprotect N-formyl amides.     

Metal-ligated amino acids and peptides as substrates for proteases

Amino acids and peptides carrying a pentaamminecobalt(III) group at the carboxyl terminal have been prepared. It is shown that trypsin and papain accept such compounds as substrates provided the metal complex group is not too close to the enzyme-susceptible peptide bond. The possible applicability of this novel type of substrates in enzymatic peptide synthesis is discussed.     

Production of amino acids by Azotobacter vinelandii and Azotobacter chroococcum with phenolic compounds as sole carbon source under diazotrophic and adiazotrophic conditions

Summary. Azotobacter vinelandii strain ATCC 12837 and Azotobacter chroococcum strain H23 (CECT4435) were tested to grow in N-free or NH₄Cl amended chemically defined media, with protocatechuic acid or sodium p-hydroxybenzoate as sole carbon (C) sources at a concentration of 2 mmol/L. Both substrates supported grow at similar rates than bacteria grown in control media amended with 2 mmol/L sodium succinate as C source. The two strains produced aspartic acid, serine, glutamic acid, glycine, hystidine, threonine, arginine, alanine, proline, cysteine, tyrosine, valine, methionine, lysine, isoleucine, leucine and phenylalanine after 72 h of growth in chemically defined media with 2 mmol/L of phenolic compounds or sodium succinate as sole C source amended or unamended with 0.1% (w/v) NH₄Cl. Qualitative and quantitative production of all amino acids was not affected by the use of different C and N substrates.     

Mode of utilization of amino acids as growth substrates by Azospirillum brasilense

The study was undertaken to analyze the rate of uptake and utilization of various amino acids by Azospirillum brasilense Sp81 (RG) in a basal mineral salts solution under non-nitrogen fixing condition. These amino acids including other nitrogenous compounds were tested for both N- and C-sources. The kinetic constants (Km and Vmax) of uptake of some amino acids (e.g. lysine, arginine, proline, glutamine and glutamic acid) were exploited using a Hanes-Woolf plot, and discussed in the context of nitrogen starvation or both carbon and nitrogen starvation. To summarize all the kinetic data for these amino acids strongly suggested that the mode of these amino acids utilization in this bacterium followed the same general pattern, although the quantitative differences were there. A single amino acid was able to satisfy the nitrogen needs of this bacterium in basal mineral salts solution, and this possibility could be considered for the cost-effective growth medium for this bacterium in the biotechnological industry.     

Tetrazole analogs of amino acids as constituents of modifiers of carboxypeptidase A catalysis

The action of substrate analogs containing the tetrazolyl group instead of the C-terminal carboxy group on the peptidase activity of carboxypeptidase A is studied. The analogs compete with the substrate for the secondary binding site thus showing activation phenomena.     

Photoreactive bicyclic amino acids as substrates for mutant Escherichia coli phenylalanyl-tRNA synthetases

Unnatural amino acids carrying reactive groups that can be selectively activated under non-invasive biologically benign conditions are of interest in protein engineering as biological tools for the analysis of protein-protein and protein-nucleic acids interactions. The double ring system phenylalanine analogues benzofuranylalanine and benzotriazolylalanine were synthesized, and their photolability was tested by UV irradiation at 254, 320, and 365 nm. Although both showed photo reactivity, benzofuranylalanine appeared as the most promising compound because this amino acid was activated by UVA (long wavelength) irradiation. These amino acids were also tested for in vitro charging of tRNA(Phe) and for protein mutagenesis via the phenylalanyl-tRNA synthetase variant alphaA294G that is able to facilitate in vivo protein synthesis using a range of para-substituted phenylalanine analogues. The results demonstrate that benzofuranylalanine, but not benzotriazolylalanine, is a substrate for phenylalanine tRNA synthetase alphaA294G, and matrix-assisted laser desorption ionization time-of-flight analysis showed it to be incorporated into a model protein with high efficiency. The in vivo incorporation into a target protein of a bicyclic phenylalanine analogue, as described here, demonstrates the applicability of phenylalanine tRNA synthetase variants in expanding the scope of protein engineering.     

Protease-catalyzed dipeptide synthesis from N-protected amino acid carbamoylmethyl esters and free amino acids in frozen aqueous solutions

The kinetically controlled synthesis of N-benzyloxycarbonyl (Z)-dipeptides was investigated by the use of free amino acids as nucleophiles and a cysteine protease papain as catalyst. The coupling efficiency was significantly improved by the combined use of the carbamoylmethyl (Cam) ester of a Z-amino acid as acyl donor and frozen aqueous solution (ice, −16 or −24 °C) as reaction medium. The yield of peptide synthesis became high when both P₁- and P^′₁-positions were occupied by small non-polar amino acids (Z-Gly-Gly-OH, 76%; Z-Gly-Ala-OH, 75%; Z-Ala-Ala-OH, 72%). Similar results were observed by the use of ficin as catalyst instead of papain. Furthermore, this strategy was applied to the papain-catalyzed incorporation of a d-configured amino acid such as d-alanine into the resulting peptides. Although the coupling in aqueous solution (30 °C) afforded the desired Z-dipeptides in low yields, the freezing of reaction medium reduced significantly unfavorable hydrolysis of the acyl donors, resulting in improvement of the coupling efficiency (Z-Gly-d-Ala-OH, 80%; Z-Ala-d-Ala-OH, 45%; Z-d-Ala-Ala-OH, 22%).     

The capability of the algaeChlorella vulgaris andScenedesmus obliquus of utilizing amino acids as the sole nitrogen source

The capability of utilizing 20 amino acids and 2 amides as the sole nitrogen source for growth was studied in two green algae (Chlorophyceae). A comparison was made of the growth rate of algae in a mineral nutrient solution containing nitrate as the nitrogen source, with that in the same solution in which nitrogen in the form of nitrate was substituted by an equivalent nitrogen amount in the form of various amino acids. In addition to this, another series of experiments was carried out in whioh both culture media were supplied with glucose. The results show that both algae utilize a series of amino acids in dependence of their structure (mostly 3-carbon amino acids). The growth rate ofChlorella in the presence of these sources is the same as in nitrate, that ofScenedesmus even much higher. In the cultures containing glucose both algal species exhibit a higher growth rate in the media with the nitrate nitrogen source than in those with amino acids (with the exception of glycine inScenedesmus).     

Preparation of the N,N,N′,N′-tetramethylenediamine complex of hydridozinc chloride. Reactions of zinc hydrides with some organic substrates

Zinc hydride and zinc chloride react together in THF in the presence of TMEDA to form the title compound. The reactions of a range of zinc hydrides with a variety of organic substrates are described.     

Insight into the catalysis of hydrolysis of four newly synthesized substrates by papain: a proton inventory study

We synthesized the following four new peptide substrates, Suc-Phe-Leu-pNA, Suc-Phe-Leu-NMec, Suc-Phe-Leu-ONPh, and Pht-Phe-Leu-pNA, and we applied the proton inventory method to their hydrolysis by papain. Useful relationships between the rate constants of the catalytic reaction have been established and contributed to the elucidation of the hydrolytic mechanism of papain. For all amide substrates, the parameter K(S) and the rate constants k(1), k(-)(1), and k(2) were estimated. Moreover, it was found that k(cat)/K(m) = k(1) for all four substrates, while two exchangeable hydrogenic sites, one in the ground state and another in the transition state, generate an inverse isotope effect during the reaction governed by this parameter. The proton inventories of both k(2) and k(3) are essentially linear, whatever the acyl moiety and/or the leaving group of the substrate. The proton inventories of K(S) are also essentially linear for all amide substrates, while the observed large isotope effect of about 3 to 9 originates from a single hydrogenic site in the product state. This latter, in agreement to both the small transition state fractionation factors found for k(cat)/K(m) (or k(1)) and the unit ground-state fractionation factors found for k(2), argues for the formation of a tetrahedral adduct during the reaction governed by the k(1) parameter. Furthermore, papain acts as a one-proton catalyst during acylation or deacylation, both of which proceed through similar concerted reaction pathways, where a nucleophilic attack is accompanied by the movement of one proton.     

Modified amino acids and peptides as substrates for the intestinal peptide transporter PepT1.

The binding affinities of a number of amino-acid and peptide derivatives by the mammalian intestinal peptide transporter PepT1 were investigated, using the Xenopus laevis expression system. A series of blocked amino acids, namely N-acetyl-Phe (Ac-Phe), phe-amide (Phe-NH2), N-acetyl-Phe-amide (Ac-Phe-NH2) and the parent compound Phe, was compared for efficacy in inhibiting the uptake of the peptide [3H]-D-Phe-L-Gln. In an equivalent set of experiments, the blocked peptides Ac-Phe-Tyr, Phe-Tyr-NH2 and Ac-Phe-Tyr-NH2 were compared with the parent compound Phe-Tyr. Comparing amino acids and derivatives, only Ac-Phe was an effective inhibitor of peptide uptake (Ki = 1.81+/- 0.37 mM). Ac-Phe-NH2 had a very weak interaction with PepT1 (Ki = 16.8+/-5.64 mM); neither Phe nor Phe-NH2 interacted with PepT1 with measurable affinity. With the dipeptide and derivatives, unsurprisingly the highest affinity interaction was with Phe-Tyr (Ki = 0.10+/-0.04 mM). The blocked C-terminal peptide Phe-Tyr-NH2 also interacted with PepT1 with a relatively high affinity (Ki = 0.94+/-0.38 mM). Both Ac-Phe-Tyr and Ac-Phe-Tyr-NH2 interacted weakly with PepT1 (Ki = 8.41+/-0.11 and 9.97+/-4.01 mM, respectively). The results suggest that the N-terminus is the primary binding site for both dipeptides and tripeptides. Additional experiments with four stereoisomers of Ala-Ala-Ala support this conclusion, and lead us to propose that a histidine residue is involved in binding the C-terminus of dipeptides. In addition, a substrate binding model for PepT1 is proposed.     

Fluorescein-based amino acids for solid phase synthesis of fluorogenic protease substrates

An efficient synthesis of new type fluorescent amino acids is described. The Fmoc-protected dyes can be prepared in a four-step procedure with approximately 30% overall yield from aminofluoresceins and other inexpensive commercially available precursors. The dyes are much more photostable compared to fluorescein and exhibit constant pH-independent fluorescence that is advantageous in biological applications. The Fmoc-protected fluorescent amino acids are ready for use in solid phase peptide synthesis. As a proof of concept, a fluorogenic papain substrate was synthesized and employed for on-bead detection of the protease activity. By using a novel technique for quantitative analysis of bead fluorescence, a approximately 2.7-fold increase in mean bead brightness was measured and was attributed to substrate cleavage by papain. The new type fluorescent amino acids seem to be a promising tool for the synthesis of fluorescent peptide ligands and fluorogenic protease substrates.     

Non-coded amino acids as acyl donor substrates for peptide bond formation catalyzed by thermoase in toluene

The peptide bond formation of N-protected non-coded amino acids having different structures as acyl donor substrates that is catalyzed by thermoase in organic media was investigated. In these reactions, N-protected l--non-coded amino acids, including l-Orn, l-Cit, -aminobutyric acid (l--Abu) and phenylalanine homologues, were used as the acyl donors and phenylalanine derivatives were used as the acyl acceptors. This kind of enzymatic reactions cannot be carried out in an aqueous buffer due to the rigid specificity of proteases to coded amino acids in water. The results demonstrated that the substrate specificity of proteases could be broadened in organic solvents. In addition, the factors that influenced these protease-catalyzed reactions, including structures of the substrates, water content and the bases used, were systematically studied. Our work provided important evidence for broadening the application of protease in organic synthesis.     

Identification of unique amino acids that modulate CYP4A7 activity

A multifamily sequence alignment of the rabbit CYP4A members with the known structure of CYP102 indicates amino acid differences falling within the so-called substrate recognition site(s) (SRS). Chimeric proteins constructed between CYP4A4 and CYP4A7 indicate that laurate activity is affected by the residues within SRS1 and prostaglandin activity is influenced by SRS2-3. Site-directed mutant proteins of CYP4A7 found laurate and arachidonate activity markedly diminished in the R90W mutant (SRS1) and somewhat decreased in W93S. While PGE(1) activity was only slightly increased, the mutant proteins H206Y and S255F (SRS2-3), on the other hand, exhibited remarkable increases in laurate and arachidonate metabolism (3-fold) above wild-type substrate metabolism. Mutant proteins H206Y, S255F, and H206Y/S255F but not R90W/W93S, wild-type CYP4A4, or CYP4A7 metabolized arachidonic acid in the absence of cytochrome b(5). Stopped-flow kinetic experiments were performed in a CO-saturated environment performed to estimate interaction rates of the monooxygenase reaction components. The mutant protein H206Y, which exhibits 3-fold higher than wild-type substrate activity, interacts with CPR at a rate at least 10 times faster than that of wild-type CYP4A7. These experimental results provide insight regarding the residues responsible for modulation of substrate specificity, affinity, and kinetics, as well as possible localization within the enzyme structure based on comparisons with homologous, known cytochrome P450 structures.     

Bromination of regenerated chitin with N-bromosuccinimide and triphenylphosphine under homogeneous conditions in lithium bromide-N,N-dimethylacetamide

Chitin regenerated from LiCl-N,N-dimethylacetamide (DMA) was found to dissolve in 10 g/dL LiBr-DMA. The bromination of the regenerated chitin proceeded to a large extent (DS by bromine up to 0.94) with equimolar amounts of N-bromosuccinimide and triphenylphosphine under homogeneous conditions in LiBr-DMA at 50–90°C. ¹³C NMR spectroscopy of brominated products and GLC-MS analysis of their hydrolyzates showed that the bromine substitution took place regioselectively at C-6 of the chitin repeating units. Polymer chain scission occurred to some extent during the bromination, more extensively at higher temperatures with higher concentrations of reagents.