Cold-adapted enzymes exhibit high catalytic activity at low temperatures and specificity, making them ideal biocatalysts for various industrial applications. Their thermolability facilitates easy inactivation under mild conditions, preventing excessive enzymatic activity. In the detergent industry, cold-adapted proteases, lipases, and amylases enable effective stain removal and washing at low temperatures, reducing energy consumption. The textile industry benefits from cold-adapted cellulases and amylases for fabric processing and surface modification. In the food industry, these enzymes enhance processes like meat tenderization, fruit juice clarification, and lactose removal in dairy products, ensuring better preservation and quality at lower temperatures. Cold-adapted enzymes are also vital in the pharmaceutical industry, aiding in peptide synthesis, wound healing, and antiviral treatments. Their role extends to agriculture, where they enhance soil fertility, plant growth, and biocontrol of pathogens, and to bioremediation, where they degrade pollutants in cold environments. Additionally, cold-adapted enzymes are used in the production of fine chemicals, such as biodiesel and chiral intermediates, and as tools in research for processes like DNA manipulation. Their unique properties offer significant advantages across diverse fields, driving innovation and sustainability in industrial processes. This review discusses promising new applications of cold-adapted enzymes in diverse industrial sectors and the strategies to overcome the present upstream and downstream processing challenges including in the application of cold-adapted enzymes.
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