Solvent Effects on Circular Dichroism of Colominic Acid

To produce acrylamide from acrylonitrile by use of a new enzyme, nitrile hydratase, a number of nitrile-utilizing microorganisms were screened for the enzyme activity by an intact cell system. An isobutyronitrile-utilizing bacterium, strain B23, showed the best productivity among 186 strains tested. The strain was identified taxonomically as Pseudomonas chlor or aphis. The culture and reaction conditions for the production were studied for the strain. Under the optimum conditions, 400 grams/liter of acrylamide was produced in 7.5 hr. The yield was nearly 100% with a trace amount of acrylic acid. The cell-free extract of the strain showed strong activity of nitrile hydratase toward acrylonitrile and extremely low activity of amidase toward acrylamide.     

微生物法生产丙烯酰胺的研究（Ⅱ）—腈水合酶催化反应动力学与失活动力学

在以丙烯腈为原料 ,微生物转化生产丙烯酰胺的过程中 ,酶催化反应是过程的关键。为了了解酶催化的动力学 ,本研究以自由细胞的酶为催化剂 ,进行了腈水合酶的反应动力学和失活动力学的研究。首先研究了菌体浓度、温度、pH值、丙烯腈浓度、丙烯酰胺浓度等对腈水合酶催化反应速度的影响。结果表明 ,在这些因素中 ,温度和丙烯酰胺浓度是最主要的影响因素。 2 8℃时酶活为 5 6 5 9u mL(菌液 ) ,在 5℃时的反应速率仅为 2 8℃时的11 72 % ,相应的表观酶活为 6 6 3u mL(菌液 )。而在丙烯酰胺 45 %浓度条件下的酶活大约只有丙烯酰胺 5 %浓度下的酶活的 1 2。经过对不同温度下的反应速度的研究 ,得到腈水合酶水合反应的活化能为 6 5 5 7kJ·mol- 1 。本文进一步研究了自由细胞状态下 ,菌体浓度、pH值、温度、丙烯腈浓度、丙烯酰胺浓度对腈水合酶失活的影响 ,得到了失活动力学。结果表明 ,在这些因素中 ,对酶失活影响的最主要因素还是温度和丙烯酰胺浓度。尤其当丙烯酰胺浓度到达 35 %时 ,酶活下降得很快 ,在 5 5h后 ,酶活几乎为零。而在丙烯酰胺浓度为 10 %的情况下 ,5 5h的酶活仍然还存在约 5 0 %。试验结果还表明 ,丙烯腈对酶的稳定性的影响很小。经过数据处理 ,得到的 2 8℃的酶失活速率常数为 5℃下的 2 1 7     

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 (V _max), whereas the Michaelis constant (K _M) 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.     

Nitrile-metabolizing potential of Amycolatopsis sp. IITR215

Strain Amycolatopsis sp. IITR215 was isolated from a sewage sample using polyacrylonitrile powder as the sole nitrogen source. Identification was performed by 16S rDNA analysis. The isolated strain harbored multiple nitrile-metabolizing enzymes having a wide range of substrate specificities. It metabolized nitrile and amide compounds with constitutive enzymes. Studies using an amidase inhibitor showed that hydrolysis of acrylonitrile and acrylamide occurred due to nitrile hydratase and amidase, respectively, while hydrolysis of hexanenitrile was due to the action of either nitrilase or a second nitrile hydratase/amidase system. The inhibitory effects of N-bromosuccinimide and N-ethylmaleimide on enzymes of this culture were also studied and this further indicated the involvement of either a nitrilase or a second nitrile hydratase/amidase system for hydrolysis of hexanenitrile. Interestingly, hexanenitrile hydrolysis exhibited an optimum temperature of 55 °C, whereas acrylonitrile and acrylamide hydrolysis showed an optimum temperature of 45 °C. The optimum pH was 5.8 for hexanenitrile hydrolysis and 7.0 for acrylonitrile and acrylamide hydrolysis. Hexanenitrile hydrolysis by enzymes of this strain showed better organic solvent tolerance in the presence of alcohols. The maximum enzyme activity of nitrile-metabolizing enzymes was found using media containing isobutyramide as the nitrogen source. This is the first report on constitutive multiple enzymes from the Amycolatopsis genus.     

Construction of a New Shuttle Vector for Zymomonas mobilis

The culture conditions for Rhodococcus sp. N-774 cells showing high nitrile hydratase activity and the reaction conditions for acrylamide production by the resting cells were optimized. Thiamine was essential for the growth of the strain. Yeast extract and Fe^{2 +} or Fe^{3 +} remarkably promoted the formation of nitrile hydratase of the cells. The reaction proceeded optimally at temperatures below 30°C. Incubation for 1 hr at above 40°C resulted in inactivation of the enzyme. Through reaction at a temperature as low as 0°C, the inhibition and inactivation of the enzyme activity by the substrate, acrylonitrile, and the product, acrylamide, were remarkably reduced, and higher accumulation of acrylamide could be attained. Under the optimal conditions, a more than 20% (w/v) acrylamide solution was obtained with a conversion yield of nearly 100%. Thus, the aqueous acrylamide solution obtained showed a high enough quality for use for the commercial preparation of polyacrylamide.     

The respiratory activity of Rhodococcus rhodochrous M8 cells producing nitrile-hydrolyzing enzymes]

The respiratory activity of Rhodococcus rhodochrous M8 cells containing nitrile hydratase and amidase was studied in the presence of nitriles and amides of carbonic acids. Culturing of cells with acrylonitrile and acrylamide yielding their maximum respiratory activity was studied. The optimum conditions for measurements and maintenance of respiratory activity were found. Curves for the linear concentration dependence of cell respiratory activity on 0.01-0.5 mM acrylonitrile, 0.025-1.0 mM acetonitrile, and 0.01-0.1 mM acrylamide were plotted. The selectivity of cell respiratory activity for some substrates was analyzed.     

Production of acrylamide using immobilized cells of<Emphasis Type="Italic">Rhodococcus rhodochrous</Emphasis> M33

The cellsof Rhodococcus rhodochrous M33, which produce a nitrile hydratase enzyme, were immobilized in acrylamide-based polymer gels. The optimum pH and temperature for the activity of nitrile hydratase in both the free and immobilized cells were 7.4 and 45°C, respectively, yet the optinum temperature for acrylamide production by the immobilized cells was 20°C. The nitrile hydratase of the immobilized cells was more stable with acrylamide than that of the free cells. Under optimal conditions, the final acrylamide concentration reached about 400 g/L with a conversion yield of almost 100% after 8 h of reaction when using 150 g/L of immobilized cells corresponding to a 1.91 g-dry cell weight/L. The enzyme activity of the immobilized cells rapidly decreased with repeated use. However, the quality of the acrylamide produced by the immobilized cells was much better than that produced by the free cells in terms of color, salt content, turbidity, and foam formation. The quality of the aqueous acrylamide solution obtained was found to be of commercial use without further purification.     

Metabolism of acrylonitrile by Klebsiella pneumoniae

A gram-negative rod-shaped bacterium capable of utilizing acrylonitrile as the sole source of nitrogen was isolated from industrial sewage and identified as Klebsiella pneumoniae. The isolate was capable of utilizing aliphatic nitriles containing 1 to 5 carbon atoms or benzonitrile as the sole source of nitrogen and either acetamide or propionamide as the sole source of both carbon and nitrogen. Gas chromatographic and mass spectral analyses of culture filtrates indicated that K. pneumoniae was capable of hydrolyzing 6.15 mmol of acrylonitrile to 5.15 mmol of acrylamide within 24 h. The acrylamide was hydrolyzed to 1.0 mmol of acrylic acid within 72 h. Another metabolite of acrylonitrile metabolism was ammonia, which reached a maximum concentration of 3.69 mM within 48 h. Nitrile hydratase and amidase, the two hydrolytic enzymes responsible for the sequential metabolism of nitrile compounds, were induced by acrylonitrile. The optimum temperature for nitrile hydratase activity was 55°C and that for amidase was 40°C; both enzymes had pH optima of 8.0.Abbreviations PBM phosphate buffered medium - GC gas chromatography - GC/MS gas chromatography/mass spectrometry     

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

Rhodococcus ruber strain gtl, 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 and 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.     

The Respiratory Activity of Rhodococcus rhodochrousM8 Cells Producing Nitrile-Hydrolyzing Enzymes

The respiratory activity of Rhodococcus rhodochrousM8 cells containing nitrile hydratase and amidase was studied in the presence of nitriles and amides of carbonic acids. The culturing of cells with acrylonitrile and acrylamide yielding maximum respiratory activity was studied. The optimum conditions for measurements and maintenance of respiratory activity were found. Curves for the linear concentration dependence of cell respiratory activity on 0.01–0.5 mM acrylonitrile, 0.025–1.0 mM acetonitrile, and 0.01–0.1 mM acrylamide were plotted. The selectivity of cell respiratory activity for some substrates was analyzed.     

Immobilization of <Emphasis Type="Italic">Rhodococcus ruber</Emphasis> 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.     

Superiority of cobalt induced acrylonitril hydratase of Arthrobacter sp. IPCB-3 for conversion of acrylonitrile to acrylamide

Summary The activity of cobalt induced acrylonitrile hydratase was found to be 130% higher than the iron induced acrylonitrile hydratase in Arthrobaeter sp. IPCB-3. The activity of cobalt induced hydratase was not affected up to 6% (w/v) acrylonitrile and 25% (w/v) acrylamide. However, iron induced hydratase activity was significantly inhibited even at half the concentration of the above components. Such a higher tolerance for the substrate and the product makes the Arthrobacter sp. IPCB-3 a potential candidate for the commercial production of acrylamide.     

Rhodococcus pyridinovorans MW3, a bacterium producing a nitrile hydratase

Rhodococcus pyridinovorans MW3 was isolated from an arable land of manioc from the Congo for its ability to transform acrylonitrile to acrylamide. This strain contains a cobalt nitrile hydratase (NHase) showing high sequence homology with NHases so far described. The specific NHase activity was 97 U mg(-1) dry wt. NHase production by R. pyridinovorans MW3 was urea and Co-dependent. The NHase was active for acrylamide up to 60% (w/v) indicating its potential for acrylamide production.     

Methods for increasing nitrile biotransformation into amides using Mesorhizobium sp

Nitriles are potential soil pollutants from industrial wastewater. There has been increased demand for efficient process for nitrile degradation process. Nitrile hydratase (NHase) has been extensively used in the production of acrylamide and treatment of organocyanide contaminated industrial effluents. The NHase of Mesorhizobium sp., isolated from polyacrylonitrile activated sludge from fiber manufacturing wastewater treatment systems was studied in the whole bacterial cells. Different chemicals were added to observe the variation in the percentage of acrylonitrile converted into acrylamide. The result indicated that cobalt ions were the NHase cofactor and could increase the NHase activity. The addition of propionaldehyde, or butyraldehyde could enhance the acrylonitrile conversion rate. Therefore, acrylamide could be accumulated effectively and the percentage of acrylonitrile converted into acrylamide increased. Propionaldehyde was the most effective NHase activator. The percentage of acrylonitrile converted into acrylamide was nearly 100% at 3.8 h when propionaldehyde was added at about 207.4 mg/l. The addition of benzaldehyde was unable to increase the percentage of acrylonitrile converted into acrylamide. EDTA and acrylamide showed no effect on NHase activity. However, 0.1 mg/l of Ag2SO4 would slightly inhibit NHase activity, producing an acrylonitrile conversion rate of 492.9 mg/l with 54.9% converted at 29.1 h. The ability of the acrylonitrile biotransformation was completely inhibited if the Ag2SO4 concentration was above 0.5 mg/l.     

Methods for increasing nitrile biotransformation into amides using Mesorhizobium sp.

Nitriles are potential soil pollutants from industrial wastewater. There has been increased demand for an efficient process for the nitrile degradation process. Nitrile hydratase (NHase) has been extensively used in the production of acrylamide and treatment of organocyanide-contaminated industrial effluents. The NHase of Mesorhizobium sp., isolated from polyacrylonitrile (PAN) activated sludge from fiber manufacturing wastewater treatment systems was studied in the whole bacterial cells. Different chemicals were added to observe the variation in the percentage of acrylonitrile converted into acrylamide. The result indicated that cobalt ions were the NHase cofactor and could increase the NHase activity. The addition of propionaldehyde, or butyraldehyde, could enhance the acrylonitrile conversion rate. Therefore, acrylamide could be accumulated effectively and the percentage of acrylonitrile converted into acrylamide increased. Propionaldehyde was the most effective NHase activator. The percentage of acrylonitrile converted into acrylamide was nearly 100% at 3.8 h when propionaldehyde was added at about 207.4 mg/l. The addition of benzaldehyde was unable to increase the percentage of acrylonitrile converted into acrylamide. EDTA and acrylamide showed no effect on NHase activity. However, 0.1 mg/l of Ag₂SO₄ would slightly inhibit NHase activity, producing an acrylonitrile conversion rate of 492.9 mg/l with 54.9% converted at 29.1 h. The ability of the acrylonitrile biotransformation was completely inhibited if the Ag₂SO₄ concentration was above 0.5 mg/l. Published in Russian in Prikladnaya Biokhimiya i Mikrobiologiya, 2008, Vol. 44, No. 3, pp. 304–307. The text was submitted in English.     

The superiority of the third-generation catalyst,Rhodococcus rhodochrous J1 nitrile hydratase,for industrial production of acrylamide

As the third-generation biocatalyst for industrial production of acrylamide, the superiority of Rhodococcus rhodochrous J1 nitrile hydratase was demonstrated in comparison with other acrylamide-producing bacteria. R. rhodochrous J1 enzyme is much more heat stable and more tolerant to a high concentration of acrylonitrile than Pseudomonas chlororaphis B23 and Brevibacterium R312 enzymes. The J1 enzyme is peculiar in its extremely high tolerance to acrylamide. The hydration reaction of acrylonitrile catalysed by J1 cells proceeded even in the presence of 50% (w/v) acrylamide. The tolerance of J1 enzyme to various organic solvents such as n-propanol and isopropanol was prominent. Using R. rhodochrous J1 resting cells, the accumulation reaction was carried out by feeding acrylonitrile to maintain a level of 6%. After 10 h incubation, the accumulation of acrylamide was approximately 65.6% (w/v) at 10°C, 56.7% (w/v) at 15°C, and 56.0 (w/v) at 20°C. The high stability, high catalytic efficiency and other outstanding features of the J1 enzyme are analysed and discussed. Correspondence to: T. Nagasawa     

Bioconversion of acrylonitrile to acrylamide using polyacrylamide entrapped cells of <Emphasis Type="Italic">Rhodococcus rhodochrous</Emphasis> PA-34

The nitrile hydratase (NHase) of Rhodococcus rhodochrous PA-34 catalyzed the conversion of acrylonitrile to acrylamide. The resting cells (having NHase activity) (8 %; 1 mL corresponds to 22 mg dry cell mass, DCM) were immobilized in polyacrylamide gel containing 12.5 % acrylamide, 0.6 % bisacrylamide, 0.2 % diammonium persulfate and 0.4 % TEMED. The polyacrylamide entrapped cells (1.12 mg DCM/mL) completely converted acrylonitrile in 3 h at 10 °C, using 0.1 mol/L potassium phosphate buffer. In a partitioned fed batch reactor, 432 g/L acrylamide was accumulated after 1 d. The polyacrylamide discs were recycled up to 3×; 405, 210 and 170 g/L acrylamide was produced in 1st, 2nd and 3rd recycling reactions. In four cycles, a total of 1217 g acrylamide was produced by recycling the same mass of entrapped cells.     

Operational stability of Brevibacterium imperialis CBS 489-74 nitrile hydratase

Brevibacterium imperialis CBS 489-74 was grown in broths prepared with yeast and malt extract, bacteriological peptone and 2% glucose or differently modified with the addition of Na-phosphate buffer, FeSO₄, MgSO₄ and CoCl₂. The peak production of nitrile hydratase (NHase) did not change significantly. At the stationary growth phase, the units per milliliter of broth (60 units ml⁻¹) were more important than those at the exponential growth phase.

The NHase operational stability of whole resting cells was monitored following the bioconversion of acrylonitrile to acrylamide in continuous and stirred UF-membrane reactors. The rate of inactivation was independent on buffer molarity from 25 to 75 mM and on pH from 5.8 to 7.4. Enzyme stability and activity remained unchanged in distilled water. The initial reaction rate increased from 12.8 to 23.8 g acrylamide/g dry cell/h, but NHase half-life dropped from 33 to roughly 7 h when temperature was varied from 4°C to 10°C. The addition of butyric acid up to 20 mM did not improve enzyme operational stability, and largely reduced (94%) enzyme activity. Acrylonitrile caused an irreversible damage to NHase activity. High acrylonitrile conversion (86%) was attained using 0.23 mg cells/ml in a continuously operating reactor.