A method and system for the treatment of Monarch butterflies (Danaus plexippus Kluk (Lepidoptera: Nymphalidae) to protect them from various life-threatening conditions, including the negative effects of various pesticides, provides Monarch butterflies with the ability to assimilate and degrade pesticides such as neonicotinoids and fipronil. Certain embodiments involve the inoculation of flowers by honey bees with desired bacteria that are able to degrade pesticides, such that when Monarch butterflies visit such flowers, they are exposed to such bacteria, transforming the microbiome of the Monarch butterflies so that pesticides can be degraded, thus enhancing the health of the Monarch butterflies.

The disclosure discloses a nitrile hydratase mutant, a genetically engineered bacterium containing the mutant and applications thereof, and belongs to the technical field of enzyme engineering. In the disclosure, glycine at position 47 of a nitrile hydratase mutant αL6T/A19V/F126Y-βM46K/E108R/S212Y (disclosed in the patent of disclosure CN102216455A) is mutated to asparagine. The obtained new mutant enzyme has better temperature tolerance and tolerance to a product, and is conducive to future industrial production. The recombinant strain containing the nitrile hydratase mutant is fermented at high density, and 3-cyanopyridine is used as a substrate to carry out a whole-cell catalytic reaction to prepare nicotinamide. Compared with a chemical production method, the method has a safe and clean production process and no environmental pollution. Compared with an enzymatic method, the substrate price is cheap and the catalytic efficiency is high. The yield of the final product nicotinamide is over 95%, the concentration reaches 680 g/L, and the separation and purification steps of the product are simplified.

Process for producing aqueous polyacrylamide concentrates by polymerizing an aqueous solution comprising at least acrylamide thereby obtaining an aqueous polyacrylamide gel, comminuting said aqueous polyacrylamide gel and mixing it with an aqueous liquid, wherein the manufacturing steps are allocated to two different locations A and B and the process comprises the step of transporting an aqueous polyacrylamide concentrate hold in a suitable transport unit from a location A to a location B. Modular, relocatable plant for manufacturing aqueous polyacrylamide, wherein the units of the plant are located at two different locations A and B.

A strain of Rhodococcus rhodochrous in which a gene coding at least part of a nitrile hydratase enzyme or any gene coding a protein involved in the transcription, translation or formation of at least part of the nitrile hydratase enzyme has been deactivated or rendered ineffective or a strain of Rhodococcus rhodochrous cultured under condition wherein the nitrile hydratase enzyme is been inhibited.

The invention belongs to the technical field of green chemistry, and provides a novel system based on a new nitrile hydratase for highly efficient catalytic conversion of aliphatic dinitriles. The invention discloses a new application of nitrile hydratase using Rhodococcus erythropolis CCM 2595 in catalyzing aliphatic dinitrile. In particular, the enzyme can regioselectivity catalyze the formation of 5-cyanopyramides from adiponitrile with high reaction rate under mild reaction conditions, which provides a new method for the industrial production of 5-cyanopyramides.

A mutant nitrile hydratase that is derived from Pseudonocardia thermophila and has an α subunit and a β subunit, wherein a specific amino acid residue has been substituted for the amino acid residue in at least one position selected from the group consisting of the 40th and 43rd residues from the N terminal of the α subunit, and the 205th, 206th, and 215th residues from the N terminal of the β subunit.

A bacterial strain of Rhodococcus biphenylivorans named Palladio 22 and registered at the BCCM-LMG Bacteria Collection under registration number LMG P-29520. A method is provided for the production of acrylamide following hydration of acrylonitrile using a biomass of the bacterial strain.

The invention belongs to the technical field of green chemistry, and provides a novel system based on a new nitrile hydratase for highly efficient catalytic conversion of aliphatic dinitriles. The invention discloses a new application of nitrile hydratase using Rhodococcus erythropolis CCM 2595 in catalyzing aliphatic dinitrile. In particular, the enzyme can regioselectivity catalyze the formation of 5-cyanopyramides from adiponitrile with high reaction rate under mild reaction conditions, which provides a new method for the industrial production of 5-cyanopyramides.

The disclosure discloses a nitrile hydratase mutant, a genetically engineered bacterium containing the mutant and applications thereof, and belongs to the technical field of enzyme engineering. In the disclosure, glycine at position 47 of a nitrile hydratase mutant L6T/A19V/F126Y-M46K/E108R/S212Y (disclosed in the patent of disclosure CN102216455A) is mutated to asparagine. The obtained new mutant enzyme has better temperature tolerance and tolerance to a product, and is conducive to future industrial production. The recombinant strain containing the nitrile hydratase mutant is fermented at high density, and 3-cyanopyridine is used as a substrate to carry out a whole-cell catalytic reaction to prepare nicotinamide. Compared with a chemical production method, the method has a safe and clean production process and no environmental pollution. Compared with an enzymatic method, the substrate price is cheap and the catalytic efficiency is high. The yield of the final product nicotinamide is over 95%, the concentration reaches 680 g/L, and the separation and purification steps of the product are simplified.

Provided is a method of producing an amide compound, the method including: obtaining a reaction solution containing an amide compound by bringing a microbial cell containing nitrile hydratase, or a processed product of the microbial cell, into contact with a nitrile compound in an aqueous medium in a first reactor; and causing the obtained reaction solution containing an amide compound to react in a second reactor having a plug-flow region, in which the Reynolds number in the second reactor is controlled to from 5 to 1,000.