Utilization of Enzymes for Environmental Applications

Ahuja, Sanjeev; Ferreira, Gisela; Moreira, A.

doi:10.1080/07388550490493726

Cited by 119 publications

(67 citation statements)

References 102 publications

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“…The detergent industry is the largest market for industrial enzymes (Ahuja et al 2004). Lipases improve the washing capability of detergents towards the fatty food stains from fabrics which are difficult to go off during normal washing conditions (Andree et al 1980).…”

Section: Applications In the Detergent Industrymentioning

confidence: 99%

Cold active lipases – an update

Kavitha

2016

Frontiers in Life Science

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Cold active lipases (CLPs) are gaining importance nowadays as they are increasingly used in fine chemical synthesis, bioremediation, food processing and as detergent additive. These enzymes exhibit high catalytic activity at low temperatures and flexibility to act at low water medium. Since they are active at low temperatures consume less energy and also stabilize fragile compounds in the reaction medium. CLPs are commonly obtained from psychrophilic microorganisms which thrive in cold habitats. Compared to mesophilic and thermophilic lipases, only a few CLPs were studied and industrially exploited so far. CLPs (C. antarctica lipase-A and C. antarctica lipase-B) from Candida antarctica isolated from Antarctic region are the well studied and industrially employed, and many are being followed up. This review updates the CLPs reported recently and the industrial applications of CLPs. ARTICLE HISTORY

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Section: Applications In the Detergent Industrymentioning

confidence: 99%

Cold active lipases – an update

Kavitha

2016

Frontiers in Life Science

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“…Genomic tools are now used for elucidation of biodegradation pathways using PCR, DNA hybridization, Microarray analysis, isotope distribution analysis, molecular connectivity analysis, the assessment of mineralization process using metabolic footprinting analysis, and the improvement of the biodegradation process via metabolic engineering [48]. The future will also see the employment of various technologies including gene shuffl ing, high throughput screening, and nanotechnology [49].…”

Section: Looking Beyond the Culturable Microorganismsmentioning

confidence: 99%

Genomic tools in bioremediation

Kapley

Purohit

2009

Indian J Microbiol

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Bioremediation is a process that uses microorganisms or their enzymes to remove pollutants from the environment. Generally, bioremediation technologies can be classifi ed as in situ or ex situ. In situ bioremediation involves treating the contaminated material at the site while ex situ involves the removal of the contaminated material to be treated elsewhere. Like so much else in biology, the ease and availability of genomic data has created a new level of understanding this system. Bioremediation capabilities of the microbial population can be analyzed; not only by physiological parameters, but also by the use of genomic tools, and effi cient remediation strategies can be planned. PCR and DNA-or oligonucleotide-based microarray technology is a powerful functional genomics tool that allows researchers to view the physiology of a living cell from a comprehensive and dynamic molecular perspective. This paper explores the use of such tools in bioremediation process.

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“…The disadvantage of using microorganisms is the difficulty in maintaining optimum conditions for their growth and survival, e.g., oxygen availability, moisture levels, pollutant levels, pH, and temperature (Baker and Herson 1994). On the contrary, the use of enzymes also known as ' 'White Biotechnology'' (Alcalde et al 2006) is more desirable for enhanced bioremediation because of the inherent capacity of the enzymes to remain active under a wide range of environmental conditions (Ahuja et al 2004;Gianfreda and Rao 2004). Moreover, enzymatic precipitation produces less toxic or biodegradable end products (Ruggaber and Talley 2006).…”

Section: Introductionmentioning

confidence: 99%