Enzymes of aldoxime–nitrile pathway for organic synthesis

Aldoxime–nitrile pathway is one of the important routes of carbon and nitrogen metabolism in many life forms and a key interface for plant–microbe interactions. This pathway starts with transformation of amino acids to aldoximes, which are converted to nitriles and the later are ultimately hydrolyzed to acids and ammonia. Understanding and engineering of the enzymes involved in this pathway viz. cytochrome P450/CYP79, aldoxime dehydratase, nitrilase, nitrile hydratase, amidase and hydroxynitrile lyase, presents unprecedented opportunities in biocatalysis and green chemistry. Co-expressing these enzymes in prokaryotic and eukaryotic microbial hosts and tailoring their properties i.e. activity, specificity, stability and enantioselectivity may lead to develop sustainable bioprocesses for the synthesis of industrially important nitriles, amides and acids.     

Biotransformation of benzonitrile herbicides via the nitrile hydratase–amidase pathway in rhodococci

The aim of this work was to determine the ability of rhodococci to transform 3,5-dichloro-4-hydroxybenzonitrile (chloroxynil), 3,5-dibromo-4-hydroxybenzonitrile (bromoxynil), 3,5-diiodo-4-hydroxybenzonitrile (ioxynil) and 2,6-dichlorobenzonitrile (dichlobenil); to identify the products and determine their acute toxicities. Rhodococcus erythropolis A4 and Rhodococcus rhodochrous PA-34 converted benzonitrile herbicides into amides, but only the former strain was able to hydrolyze 2,6-dichlorobenzamide into 2,6-dichlorobenzoic acid, and produced also more of the carboxylic acids from the other herbicides compared to strain PA-34. Transformation of nitriles into amides decreased acute toxicities for chloroxynil and dichlobenil, but increased them for bromoxynil and ioxynil. The amides inhibited root growth in Lactuca sativa less than the nitriles but more than the acids. The conversion of the nitrile group may be the first step in the mineralization of benzonitrile herbicides but cannot be itself considered to be a detoxification.     

Expression of the Alcaligenes eutrophus poly(β-hydroxybutyric acid)-synthetic pathway in Pseudomonas sp.

The 12.5-kb EcoRI restriction fragment PP1 of Alcaligenes eutrophus strain H16, which encodes for -ketothiolase, NADP-dependent acetoacetyl-CoA reductase and poly(-hydroxybutyric acid)-synthase was mobilized to six different species of the genus Pseudomonas belonging to the rRNA homology group I. Pseudomonas aeruginosa, P. fluorescens, P. putida, P. oleovorans, P. stutzeri and P. syringae, which are unable to synthesize and accumulate poly(-hydroxybutyric acid), PHB, were employed as recipients. Whereas the A. eutrophus PHB-synthetic enzymes were only marginally expressed in P. stutzeri, they were readily expressed in the other species. For example, the specific activity of PHB-synthase was 1.8 U/g protein in transconjugants of P. stutzeri but was between 21 and 77 U/mg protein in transconjugants of the other species. All recombinant strains harboring plasmid pVK101::PP1 except those of P. stutzeri accumulated PHB; the PHB content of the cells grown on gluconate under nitrogen limitation varied between 8 and 24.3% of the cellular dry mass.Abbreviations PHB poly(-hydroxybutyric acid) - PHA poly(hydroxyalkanoic acid)     

Molecular and practical aspects of the enzymatic properties of human serum albumin and of albumin–ligand complexes

Background

Human serum albumin and some of its ligand complexes possess enzymatic properties which are useful both in vivo and in vitro.

Scope of review

This review summarizes present knowledge about molecular aspects, practical applications and potentials of these properties.

Major conclusions

The most pronounced activities of the protein are different types of hydrolysis. Key examples are esterase-like activities involving Tyr411 or Lys199 and the thioesterase activity of Cys34. In the first case, hydrolysis involves water and both products are released, whereas in the latter cases one of the products is set free, and the other stays covalently bound to the protein. However, the modified Cys34 can be converted back to its reduced form by another compound/enzymatic system. Among the other activities are glucuronidase, phosphatase and amidase as well as isomerase and dehydration properties. The protein has great impact on the metabolism of, for example, eicosanoids and xenobiotics. Albumin with a metal ion-containing complex is capable of facilitating reactions involving reactive oxygen and nitrogen species.

General significance

Albumin is useful in detoxification reactions, for activating prodrugs, and for binding and activating drug conjugates. The protein can be used to construct smart nanotubes with enzymatic properties useful for biomedical applications. Binding of organic compounds with a metal ion often results in metalloenzymes or can be used for nanoparticle formation. Because any compound acting as cofactor and/or the protein can be modified, enzymes can be constructed which are not naturally found and therefore can increase, often stereospecifically, the number of catalytic reactions. This article is part of a Special Issue entitled Serum Albumin.     

An angiosperm-wide analysis of the gynodioecy–dioecy pathway

Background and Aims

About 6 % of an estimated total of 240 000 species of angiosperms are dioecious. The main precursors of this sexual system are thought to be monoecy and gynodioecy. A previous angiosperm-wide study revealed that many dioecious species have evolved through the monoecy pathway; some case studies and a large body of theoretical research also provide evidence in support of the gynodioecy pathway. If plants have evolved through the gynodioecy pathway, gynodioecious and dioecious species should co-occur in the same genera. However, to date, no large-scale analysis has been conducted to determine the prevalence of the gynodioecy pathway in angiosperms. In this study, this gap in knowledge was addressed by performing an angiosperm-wide survey in order to test for co-occurrence as evidence of the gynodioecy pathway.

Methods

Data from different sources were compiled to obtain (to our knowledge) the largest dataset on gynodioecy available, with 275 genera that include at least one gynodioecious species. This dataset was combined with a dioecy dataset from the literature, and a study was made of how often dioecious and gynodioecious species could be found in the same genera using a contingency table framework.

Key Results

It was found that, overall, angiosperm genera with both gynodioecious and dioecious species occur more frequently than expected, in agreement with the gynodioecy pathway. Importantly, this trend holds when studying different classes separately (or sub-classes, orders and families), suggesting that the gynodioecy pathway is not restricted to a few taxa but may instead be widespread in angiosperms.

Conclusions

This work complements that previously carried out on the monoecy pathway and suggests that gynodioecy is also a common pathway in angiosperms. The results also identify angiosperm families where some (or all) dioecious species may have evolved from gynodioecious precursors. These families could be the targets of future small-scale studies on transitions to dioecy taking phylogeny explicitly into account.     

Molecular sieves provoke multiple substitutions in the enzymatic synthesis of fructose oligosaccharide–lauryl esters

The cause of discrepancies in the literature regarding the specificity of immobilized Candida antarctica lipase B in the acylation of oligosaccharides was examined. Molecular sieves, generally used to control the water content during acylation reactions, turned out to have an important role in this. It was proven that molecular sieves alone can catalyze the acylation of fructose oligomers using vinyl laurate, leading to multiple substitution of the oligomers. This effect was the most profound at conditions unfavorable for the enzyme, because this resulted in a relatively high concentration of the chemically produced adducts. The enzyme alone catalyzed the formation of monosubstituted oligomers. It was proven that even solvent pre-drying by molecular sieves already causes the release of catalyzing compounds to the liquid, leading to subsequent catalysis. These findings should be taken into account when applying molecular sieves in this type of reactions in the future. Molecular sieves could, moreover, be used as a catalyst when multiple substitution is desired.     

Changes in Root Exudates and Root Proteins in Groundnut–Pseudomonas sp. Interaction Contribute to Root Colonization by Bacteria and Defense Response of the Host

Journal of Plant Growth Regulation - Selection and application of rhizobacteria, for improved plant health will benefit from a complete understanding of the plant–bacteria interaction. Root...     

Purification and Some Properties of the Endo α-1,4 Polygalactosaminidase from Pseudomonas sp.

The endo α-1,4 polygalactosaminidase from Pseudomonas sp. 881 was purified from the culture nitrate by ethanol precipitation and sequential column chromatographies on CM-Sephadex C-25, Sephadex G-50 and Phenyl-Sepharose CL-4B. The purified enzyme was electrophoretically homogeneous and its molecular weight and isoelectric point were 31,000 and 6.7, respectively. The optimum pH and temperature for hydrolysis of polygalactosamine were 5.0 and 55°C, respectively. The enzyme was stable up to 45°C for 15min and from pH 4.0 to 7.6 at 37°C for 1 hr.

The Km value was 0.05% α-1,4 polygalactosamine and the V was 0.154μmol reducing sugar (galactosamine)/min/μg protein. This polygalactosaminidase was inhibited by Sn²⁺ , Fe²⁺ , Fe³⁺ , Hg²⁺, Cu²⁺ ions and SDS. The enzyme did not hydrolyze oligo galactosamines (n < tetramer) or N-acetyl-polygalactosamines. It acted only on oligo galactosamine (n > trimer) and polygalactosamine endogeneously so far tested.     

Structural analysis, enzymatic characterization, and catalytic mechanisms of β-galactosidase from Bacillus circulans sp. alkalophilus

Crystal structures of native and α-D-galactose-bound Bacillus circulans sp. alkalophilus β-galactosidase (Bca-β-gal) were determined at 2.40 and 2.25 ? resolutions, respectively. Bca-β-gal is a member of family 42 of glycoside hydrolases, and forms a 460 kDa hexameric structure in crystal. The protein consists of three domains, of which the catalytic domain has an (α/β)(8) barrel structure with a cluster of sulfur-rich residues inside the β-barrel. The shape of the active site is clearly more open compared to the only homologous structure available in the Protein Data Bank. This is due to the number of large differences in the loops that connect the C-terminal ends of the β-strands to the N-terminal ends of the α-helices within the (α/β)(8) barrel. The complex structure shows that galactose binds to the active site as an α-anomer and induces clear conformational changes in the active site. The implications of α-D-galactose binding with respect to the catalytic mechanism are discussed. In addition, we suggest that β-galactosidases mainly utilize a reverse hydrolysis mechanism for synthesis of galacto-oligosaccharides.     

Sequence analysis and structure prediction of type II Pseudomonas sp. USM 4–55 PHA synthase and an insight into its catalytic mechanism

Background  

Polyhydroxyalkanoates (PHA), are biodegradable polyesters derived from many microorganisms such as the pseudomonads. These polyesters are in great demand especially in the packaging industries, the medical line as well as the paint industries. The enzyme responsible in catalyzing the formation of PHA is PHA synthase. Due to the limited structural information, its functional properties including catalysis are lacking. Therefore, this study seeks to investigate the structural properties as well as its catalytic mechanism by predicting the three-dimensional (3D) model of the Type II Pseudomonas sp. USM 4–55 PHA synthase 1 (PhaC1_{P.sp USM 4–55}).     

Biodegradation and metabolic pathway of β-chlorinated aliphatic acid in Bacillus sp. CGMCC no. 4196

In this study, a bacterial Bacillus sp. CGMCC no. 4196 was isolated from mud. This strain exhibited the ability to degrade high concentration of 3-chloropropionate (3-CPA, 120 mM) or 3-chlorobutyrate (30 mM), but not chloroacetate or 2-chloropropionate (2-CPA). The growing cells, resting cells, and cell-free extracts from this bacterium had the capability of 3-CPA degradation. The results indicated that the optimum biocatalyst for 3-CPA biodegradation was the resting cells. The 3-CPA biodegradation pathway was further studied through the metabolites and critical enzymes analysis by HPLC, LC-MS, and colorimetric method. The results demonstrated that the metabolites of 3-CPA were 3-hydroxypropionic acid (3-HP) and malonic acid semialdehyde, and the critical enzymes were 3-CPA dehalogenase and 3-HP dehydroxygenase. Thus, the mechanism of the dehalogenase-catalyzed reaction was inferred as hydrolytic dehalogenation which was coenzyme A-independent and oxygen-independent. Finally, the pathway of β-chlorinated aliphatic acid biodegradation could be concluded as follows: the β-chlorinated acid is first hydrolytically dehalogenated to the β-hydroxyl aliphatic acid, and the hydroxyl aliphatic acid is oxidized to β-carbonyl aliphatic acid by β-hydroxy aliphatic acid dehydroxygenase. It is the first report that 3-HP was produced from 3-CPA by β-chlorinated aliphatic acid dehalogenase.     

The purification of cellulase and exo-laminaranase and their role in the formation ofPythium sp. “protoplasts”

A cellulase and a laminaranase have been purified from a Streptomyces lytic enzyme complex. Lipase and protease were separated from glucanases. A combination of the purified glucanases produced protoplasts fromPythium sp. PRL 2142. Lipase was shown to act as an adjuvant in this process.National Research Council of Canada Postdoctorate Fellow 1965–67.     

Role of the pentose phosphate pathway and the Entner–Doudoroff pathway in glucose metabolism of Gluconobacter oxydans 621H

Glucose catabolism by the obligatory aerobic acetic acid bacterium Gluconobacter oxydans 621H proceeds in two phases comprising rapid periplasmic oxidation of glucose to gluconate (phase I) and oxidation of gluconate to 2-ketogluconate or 5-ketogluconate (phase II). Only a small amount of glucose and part of the gluconate is taken up into the cells. To determine the roles of the pentose phosphate pathway (PPP) and the Entner–Doudoroff pathway (EDP) for intracellular glucose and gluconate catabolism, mutants defective in either the PPP (Δgnd, Δgnd zwf*) or the EDP (Δedd–eda) were characterized under defined conditions of pH 6 and 15 % dissolved oxygen. In the presence of yeast extract, neither of the two pathways was essential for growth with glucose. However, the PPP mutants showed a reduced growth rate in phase I and completely lacked growth in phase II. In contrast, the EDP mutant showed the same growth behavior as the reference strain. These results demonstrate that the PPP is of major importance for cytoplasmic glucose and gluconate catabolism, whereas the EDP is dispensable. Reasons for this difference are discussed.     

Properties of Crystalline ω-Amino Acid : Pyruvate Aminotransferase of Pseudomonas sp. F–126

ω-Amino acid: pyruvate aminotransferase, purified to homogeneity and crystallized from a Pseudomonas sp. F–126, has a molecular weight of 172,000 or 167,000±3000 as determined by the gel-filtration or sedimentation equilibrium method, respectively. The enzyme catalyzes the transamination between various ω-amino acids or amines and pyruvate which is the exclusive amino acceptor. α-Amino acids except l-α-alanine are inert as amino donor. The Michaelis constants are 3.3 mm for β-alanine, 19 mm for 2-aminoethane sulfonate and 3.3 mm for pyruvate. The enzyme has a maximum activity in the pH range of 8.5~10.5. The enzyme is stable at pH 8.0~10.0 and at up to 65°C at pH 8.0. Carbonyl reagents strongly inhibit the enzyme activity. Pyridoxal 5′-phosphate and pyridoxamine 5′-phosphate reactivate the enzyme inactivated by carbonyl reagents. The inhibition constants were determined to be 0.73 mm for d-penicillamine and 0.58 mm for d-cycloserine. Thiol reagents, chelating agents and l-α-amino acids showed no effect on the enzyme activity.     

Molecular characterization and functional analysis of “fruit-weight2.2-like” gene family in rice

Tomato fruit-weight 2.2 (FW2.2) was reported to control up to 30 % fruit weight. Recent studies demonstrated that FW2.2-like (FWL) genes also play important roles in plant growth and development. For instance, a maize homolog of FW2.2, named cell number regulator 1 (CNR1), negatively regulates plant and organ size. However, FWL genes in rice have not been characterized yet. In this study, eight FWL genes were identified in rice genome and designated as OsFWL1-8. The chromosome location, gene structure, protein motif, and phylogenetic relationship of OsFWL genes were analyzed. RT-PCR result and microarray data revealed that OsFWL genes exhibited diverse expression patterns and the detailed expression patterns of OsFWL5, 6, and 7 negatively correlated with leaf growth activity. Rice protoplast transient transformation experiment showed that most OsFWL proteins locate at cell membrane but OsFWL8 is present in the nucleus. In addition, the functions of OsFWL genes were investigated by analyzing two T-DNA insertion lines for OsFWL3 and 5. Compared with wild type, the grain weight of osfwl3 mutant and the plant height of osfwl5 mutant were increased by 5.3 and 12.5 %, respectively. We also found that the increase in grain length of osfwl3 mutant was due chiefly to incremental cell number, not cell size and the expression of OsFWL3 negatively correlated with glume growth activity. These results provide a comprehensive foundation for further study of OsFWL functions in rice.     

Molecular analysis of the genotype-phenotype relationship in factor VII deficiency

Factor VII (FVII) deficiency is a rare haemorrhagic condition, normally inherited as an autosomal recessive trait, in which clinical presentation is highly variable and correlates poorly with laboratory phenotype. The FVII (F7) gene was sequenced in 48 unrelated individuals with FVII deficiency, yielding a total of 23 novel lesions including 15 missense mutations, 2 micro-deletions, 5 splice junction mutations and a single base-pair substitution in the 5' untranslated region. Family studies were performed in order to distinguish the contributions of individual mutant F7 alleles to the clinical and laboratory phenotypes. Specific missense mutations were evaluated by molecular modelling in the context of the FVIIa-tissue factor crystal structure. Single base-pair substitutions in splice sites and the 5' untranslated region were studied by in vitro splicing assay and luciferase reporter gene assay, respectively. All probands were also typed for four previously reported F7 polymorphisms. In the majority of cases of FVII deficiency studied here, consideration of both mutational and polymorphism data permitted the derivation of plausible explanations for the FVII activity and antigen levels measured in the laboratory. Inter-familial variation in FVII activity and the antigen levels of heterozygous relatives of probands was found to be significantly higher than intra-familial variation, consistent with the view that the nature of the F7 gene lesion(s) segregating in a given family is a prime determinant of laboratory phenotype. Although no relationship could be discerned between laboratory phenotype and polymorphism genotype, the frequencies of the A2 and M2 polymorphic alleles were significantly higher in the FVII-deficient individuals tested than in controls. This suggests that the presence of these alleles may have served to increase the likelihood of pathological F7 gene lesions coming to clinical attention.     

Molecular analysis of the genotype-phenotype relationship in factor X deficiency

Factor X deficiency is a rare haemorrhagic condition, normally inherited as an autosomal recessive trait, in which a variable clinical presentation correlates poorly with laboratory phenotype. The factor X (F10) genes of 14 unrelated individuals with factor X deficiency (12 familial and two sporadic cases) were sequenced yielding a total of 13 novel mutations. Family studies were performed in order to distinguish the contributions of individual mutant F10 alleles to the clinical and laboratory phenotypes. Missense mutations were studied by means of molecular modelling, whereas single basepair substitutions in splice sites and the 5' flanking region were examined by in vitro splicing assay and luciferase reporter gene assay respectively. The deletion allele of a novel hexanucleotide insertion/deletion polymorphism in the F10 gene promoter region was shown by reporter gene assay, to reduce promoter activity by approximately 20%. One family manifesting an autosomal dominant pattern of inheritance possessed three clinically affected members who were heterozygous for a splice-site mutation that was predicted to lead to the production of a truncated protein product. A model which accounts for the dominant negative effect of this lesion is presented. Variation in the antigen level of heterozygous relatives of probands was found to be significantly higher between families than within families, consistent with the view that the nature of the F10 lesion(s) segregating in a given family is a prime determinant of the laboratory phenotype. By contrast, no such relationship could be discerned between laboratory phenotype and polymorphism genotype.