Yu. G. Maksimova

Immobilization of Rhodococcus ruber strain gt1, possessing nitrile hydratase activity, on carbon supports

Rhodococcus ruber strain gt1, possessing nitrile hydratase activity, was immobilized by adsorption on carbon supports differing in structure and porosity. The adsorption capacity of the supports towards cells, the substrate of the nitrile hydratase reaction (acrylonitrile), and the product (acrylamide) was studied. Also, the effect of immobilization on nitrile hydratase activity of bacteria was investigated, and the operational stability of the immobilized biocatalyst was determined. It was shown that crushed and granulated active coals were more appropriate for immobilization than fibrous carbon adsorbents.

Microbial biofilms in biotechnological processes

This review summarizes the information concerning the following applications of microbial biofilms in biotechnology: the biodegradation of organic substances and other contaminants during wastewater treatment, biosynthesis, and biocatalysis. The main types of reactors for implementing biotechnical processes based on microbial biofilms are discussed. The advantages and drawbacks of biocatalysts in the form of microbial biofilms for the biotransformation of organic substances are examined.

Effects of Nitriles and Amides on the Growth and Nitrile Hydratase Activity of the Rhodococcus sp. Strain gt1

Effects of some nitriles and amides, as well as glucose and ammonium, on the growth and the nitrile hydratase (EC 4.2.1.84) activity of the Rhodococcus sp. strain gt1 isolated from soil were studied. The activity of nitrile hydratase mainly depended on the carbon and nitrogen supply to cells. The activity of nitrile hydratase was high in the presence of glucose and ammonium at medium concentrations and decreased at concentrations of glucose of more than 0.3%. Saturated unsubstituted aliphatic nitriles and amides were found to be a good source of nitrogen and carbon. However, the presence of nitriles and amides in the medium was not absolutely necessary for the expression of the activity of nitrile hydratase of the Rhodococcus sp. strain gt1.

Catalytic properties of a nitrile hydratase immobilized on activated chitosan

The catalytic properties of a nitrile hydratase, isolated from a strain of Rhodococcus ruber gt1 and immobilized by covalent cross-linking with chitosan activated with 0.1% benzoquinone solution, have been investigated. The kinetic parameters of acrylonitrile hydration catalyzed by immobilized nitrile hydratase and the enzyme in a solution have been determined. It is found that the immobilization does not lead to a decrease in the maximum reaction rate (Vmax), whereas the Michaelis constant (KM) is reduced by a factor of 2.4. The possibility of reusing an immobilized enzyme for 50 consecutive cycles of acrylonitrile transformation was shown, and the nitrile hydratase activity in the 50th cycle exceeded that in the first cycle by 3.5 times. It is shown that the effect of temperature on activity depended on the concentration of the enzyme, which confirms the dissociative nature of nitrile hydratase inactivation. It was found that immobilized nitrile hydratases remain active at pH 3.0–4.0, whereas the enzyme is inactivated in a solution under these conditions. The resulting biocatalyst can be effectively used to receive acrylamide from acrylonitrile.

A study of the catalytic properties of the nitrile hydratase immobilized on aluminum oxides and carbon-containing adsorbents

The nitrile hydratase isolated from Rhodococcus ruber strain gt1, displaying a high nitrile hydratase activity, was immobilized on unmodified aluminum oxides and carbon-containing adsorbents, including the carbon support Sibunit. The activity and operational stability of the immobilized nitrile hydratase were studied in the reaction of acrylonitrile transformation into acrylamide. It was demonstrated that an increase in the carbon content in the support led to an increase in the amount of adsorbed enzyme and, concurrently, to a decrease in its activity. The nitrile hydratase immobilized on Sibunit and carbon-containing aluminum α-oxide having a “crust” structure displayed the highest operational stability in acrylonitrile hydration. It was shown that the thermostability of adsorbed nitrile hydratase increased by one order of magnitude.

Transformation of 2- and 4-cyanopyridines by free and immobilized cells of nitrile-hydrolyzing bacteria

The transformation dynamics of 2- and 4-cyanopyridines by cells suspended and adsorbed on inorganic carriers has been studied in the Rhodococcus ruber gt1 possessing nitrile hydratase activity and the Pseudomonas fluorescens C2 containing nitrilase. It was shown that both nitrile hydratase and nitrilase activities of immobilized cells against 2-cyanopyridine were 1.5–4 times lower compared to 4-cyanopyridine and 1.6–2 times lower than the activities of free cells against 2-cyanpopyridine. The possibility of obtaining isonicotinic acid during the combined conversion of 4-cyanopyridine by a mixed suspension of R. ruber gt1 cells with a high level of nitrile hydratase activity and R. erythropolis 11-2 cells with a pronounced activity of amidase has been shown. Immobilization of Rhodococcus cells on raw coal and Pseudomonas cells on kaolin was shown to yield a heterogeneous biocatalyst for the efficient transformation of cyanopyridines into respective amides and carboxylic acids.

Hydrolysis of acrylonitrile by nitrile-converting bacterial cells immobilized on fibrous carbon adsorbents

Cells of the Pseudomonas fluorescens strain C2 containing nitrilase and Rhodococcus ruber strain gt1 with nitrile hydratase activity have been immobilized by the use of adsorption on fibrous carbon materials. It has been shown that the maximum adsorption value of Rhodococcus cells is higher than that in pseudomonades, reaching 21 mg of dry cells/1 g of the carrier vs. 6 mg, respectively. Cell adsorption, compared to cell suspension, gives a significant rise in nitrilase activity (by 7.4 times, using Ural TM-4 as the carrier) and in the stability of nitrile hydratase activity (5 reaction cycles without loss of activity, using Carbopon-B-active). Immobilized biocatalysts were also obtained by cell growth from Ps. fluorescens strain C2 and Rhodococcus ruber strain gt1 on fibrous carbon adsorbents. Biocatalyst productivity was higher for both strains when the carbonized material Ural TM-4 was used as the carrier.

Stereoselective biotransformation of phenylglycine nitrile by heterogeneous biocatalyst based on immobilized bacterial cells and enzyme preparation

We studied the effect of a heterogeneous environment on the stereoselectivity of transformation of racemic phenylglycine nitrile. Immobilized biocatalysts were prepared by adhesion of Pseudomonas fluorescens C2 cells on carbon-containing supports and covalent crosslinking of nitrile hydratase and amidase of Rhodococcus rhodochrous 4–1 to activated chitosan as well as by the method of cross-linked aggregates. At a reaction duration of 20 h, the ratio of phenylglycine stereoisomers changes depending on the presence of support in medium. The highest optical purity of the product (enantiomeric excess of L-phenylglycine solution, 98%) is achieved when enzyme aggregates of nitrile hydratase and amidase cross-linked with 0.1% glutaraldehyde are used as a biocatalyst.

Transformation of amides by adherent Rhodococcus cells possessing amidase activity

We report the development of a heterogeneous biocatalyst for the hydrolysis of amides that is based on cell adhesion of amidase-containing Rhodococci on activated birch charcoal (ABC) and raw coal. We investigated the properties of the obtained biocatalyst in the hydrolysis reaction of acrylamide to acrylic acid and nicotinamide to nicotinic acid, as well as in a model reaction of racemic lactamide hydrolysis to a mixture of D- and L-isomers of lactic acid. We show that a six- and threefold increase in the concentrations of adherent and suspended cells, respectively, results in a reduction of amidase activity by 3 and 30 times, respectively. Cells adherent on ABC maintained more than 50% of enzymatic activity for seven 24-hour cycles of acrylamide hydrolysis, while suspended cells lost more than 60% of activity already in the second cycle. We also noted that cell adhesion on ABC reduced the stereoselectivity of hydrolysis reaction of racemic lactamide.

Biological diversity of nitrile-metabolizing bacteria in soils of the Perm region affected by human activities

The diversity of bacteria metabolizing nitriles of carbonic acids was studied in soils of the Perm region affected by human activities. Effective methods for selective isolation of cultures possessing the nitrile hydratase and nitrilase activities were developed. Most microorganisms capable of utilizing nitriles were Grampositive Nocardia-like bacteria of the genus Rhodococcus. Isolates with a detectable nitrilase activity were also represented by Gram-negative forms (Gram-negative aerobic/microaerophilic bacilli and cocci of the genera Pseudomonas, Azomonas, Azotobacter, and Acidovorax). Two enzyme systems for nitrile hydrolysis were found in 27% of cultures. The nitrile hydratase and nitrilase activities of the studied strains exceeded these enzymatic activities in bacteria isolated from native soils, which indicates that natural selection of saprophytic microflora occurs in chemically altered soils.