Progress in Biochemistry and Biotechnology
2 total works
Microbial Xylanolytic Enzymes describes the enzyme structure and its interaction with plant cell walls, the properties and production of different enzymes and their applications, and the knowledge gathered on the hydrolysis mechanism of hemicellulose. The knowledge gathered about the hydrolysis mechanism of the hemicelluloses, especially xylans, has greatly promoted the rapid application of these enzymes in new areas. In recent years, there has been a spurt of interest in xylan degrading enzymes due to their applications in several industrial processes, including paper and pulp industries, food and feed industries, biofuel industry, textile industry, chemical and pharmaceutical industry, brewing industry, and more.
Xylan is the principal type of hemicellulose. An enzymatic complex is responsible for the hydrolysis of xylan, but the main enzymes involved are enzymes produced by fungi, bacteria, yeast, algae, protozoans, and more.
Xylan is the principal type of hemicellulose. An enzymatic complex is responsible for the hydrolysis of xylan, but the main enzymes involved are enzymes produced by fungi, bacteria, yeast, algae, protozoans, and more.
Developments and Applications of Enzymes From Thermophilic Microorganisms
by Pratima Bajpai
Published 25 January 2023
Developments and Applications of Enzymes from Thermophilic Microorganisms extensively presents the industrial application of thermophilic/hyperthermophilic enzymes. The book brings thorough and in-depth coverage on the role of these enzymes in a broad range of industries, focusing on present scenarios of these enzymes in biofuel industries, including recent advancements. The use of thermophilic enzymes in 2G biorefineries may enable the whole production process to take place at high temperatures, allowing increased reaction rate and reduced costs. Researchers in biochemistry, microbiology, microbial technology, biotechnology, molecular biology and bioresource technology will benefit from the new insights given on potential applications of hyperthermophiles.
Hyperthermophilic enzymes, many of which survive at temperatures at or above 100C, contain novel macromolecules and metabolic systems which represent a vast resource for fundamental molecular and physiological studies, and for potential exploitation in biotechnology.
Hyperthermophilic enzymes, many of which survive at temperatures at or above 100C, contain novel macromolecules and metabolic systems which represent a vast resource for fundamental molecular and physiological studies, and for potential exploitation in biotechnology.