Isolation, screening and identification of Lipase producing fungi from cotton seed soapstock

Patel, Gayatriben B.; Shah, Kamlesh

doi:10.17485/ijst/v13i36.1099

Cited by 12 publications

(3 citation statements)

References 27 publications

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“…Moreover, some recently isolated fungi are also documented as they can produce lipase enzymes such as Rhizopus oryzae R1 (Helal et al, 2021), Stemphylium lycopersici, Sordida sp. (Rocha et al, 2020), Aspergillus niger 13 F, Fusarium solani 7 F (Patel and Shah, 2020), Aspergillus flavus (Ezema et al, 2022), Aspergillus terreus AH-F2 (Shabbir and Mukhtar, 2018), and Thermomyces lanuginosus (Tišma et al, 2019). The production of lipases by fungi is varied according to the fungal organism and composition of the growth medium and physical conditions such as the nitrogen source, carbon source, pH, and temperature (Pandey et al, 2016).…”

Section: Fungal Sources Of Lipasesmentioning

confidence: 99%

“…Shabbir and Mukhtar (2018) also isolated a fungus Aspergillus terreus AH-F2 from soil and oily samples that shows a maximum lipase production of 5.0 U/ml/min in a defined medium at pH 6.0. In another study, Patel and Shah (2020) isolated two fungi, namely, Fusarium solani 7 F and Aspergillus niger 13 F, and both the fungi are capable of producing 5.95 U/mL/min of crude lipase after 4 days of incubation at 30 • C. Some fungal strains, their isolation sites, culture conditions, screening substrate, and specific enzyme activities are summarized in Table 1.…”

Section: Fungal Sources Of Lipasesmentioning

confidence: 99%

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Industrial applications of fungal lipases: a review

Kumar¹,

Verma²,

Dubey³

et al. 2023

Front. Microbiol.

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Fungal lipases (triacylglycerol acyl hydrolases EC 3.1.1.3) are significant industrial enzymes and have several applications in a number of industries and fields. Fungal lipases are found in several species of fungi and yeast. These enzymes are carboxylic acid esterases, categorized under the serine hydrolase family, and do not require any cofactor during the catalyzing of the reactions. It was also noticed that processes including the extraction and purification of lipases from fungi are comparatively easier and cheaper than other sources of lipases. In addition, fungal lipases have been classified into three chief classes, namely, GX, GGGX, and Y. Fungal lipases have applications not only in the hydrolysis of fats and oils (triglycerides) but are also involved in synthetic reactions such as esterification, acidolysis, alcoholysis, interesterification, and aminolysis. The production and activity of fungal lipases are highly affected by the carbon source, nitrogen source, temperature, pH, metal ions, surfactants, and moisture content. Therefore, fungal lipases have several industrial and biotechnological applications in many fields such as biodiesel production, ester synthesis, production of biodegradable biopolymers, formulations of cosmetics and personal care products, detergent manufacturing, degreasing of leather, pulp and paper production, textile industry, biosensor development, and drug formulations and as a diagnostic tool in the medical sector, biodegradation of esters, and bioremediation of wastewater. The immobilization of fungal lipases onto different carriers also helps in improving the catalytic activities and efficiencies of lipases by increasing thermal and ionic stability (in organic solvents, high pH, and temperature), being easy to recycle, and inducing the volume-specific loading of the enzyme onto the support, and thus, these features have proved to be appropriate for use as biocatalysts in different sectors.

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Section: Fungal Sources Of Lipasesmentioning

confidence: 99%

Section: Fungal Sources Of Lipasesmentioning

confidence: 99%

Industrial applications of fungal lipases: a review

Kumar¹,

Verma²,

Dubey³

et al. 2023

Front. Microbiol.

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“…In agriculture, PGPR can be a great tool to help mitigate the negative effects of abiotic stress, such as drought and excessive salinity, by taking the place of costly inorganic fertilisers that are harmful for the environment (Vocciante et al, 2022). According to Patel and Minocheherhomji (2020), PGPR help cotton seeds germinate, improve crop productivity, and serve as an alternative to chemical fertilizers.…”

Section: Introductionmentioning

confidence: 99%

Cotton Productivity and Fiber Quality Improvement by Nano Chitosan-NPK Fertilizer Integrated with Plant Growth Promoting Rhizobacteria Application in North Delta of Egypt

A. E. M.,

S. Arafa,

M.B. Yahia

et al. 2023

Alexandria Science Exchange Journal

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It is vital to limit the loss of mineral NPK fertilizers during crops fertilization, especially in adverse soil conditions that reduce its availability to plants uptake and increase environmental pollution impact. This study aimed to reduce the soil application of the traditional NPK (T-NPK) fertilizers through partially adding foliar nano chitosan-NPK (NCS-NPK) with plant growth promoting rhizobacteria (PGPR) to boost cotton (Gossypium Barbadense L.) productivity and fiber quality. During the growing seasons of 2021 and 2022, field experiments were performed at the Sakha Agricultural Research Station, Kafr El-Sheikh, Egypt. A split-plot with four replicates based on a Randomized Complete Block design was used. Egyptian cotton cultivars Giza 97, 96 and promising hybrid G93xG71 were assigned to main plots, and seven foliar NCS-NPK and PGPR treatments were distributed in subplots. Results showed superiority of Giza 97 cultivar in boll weight (3.38 g), seed cotton yield fed -1 (11.13 ken), maturity ratio (0.94) and fiber elongation (7.85%), while Giza 96 cultivar in uniformity index (86.62%) and fiber strength (46.57g/tex) and promising hybrid G93xG71 in plant height (146.7cm), sympodial branches plant -1 (15.26), seed index(10.84 g), lint% (36.08%), upper half mean (UHM) (35.48 mm), fiber fineness (3.17), and fiber brightness (reflectance degree Rd %, (76.40%). Foliar combined NCS-NPK with PGPR under 50% T-NPK gave the highest values of the most studied treats. There is evidence that the combined application of NCS-NPK with PGPR can reduce the application of T-NPK fertilizers, which sequentially reduce environmental pollution and enhance cotton production and fiber quality.

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Biodegradation of Soap Stock: As an Alternative Renewable Energy Resource and Reduce Environmental Pollution

Shah

Patel

2022

Innovations in Environmental Biotechnology

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Isolation, screening and identification of Lipase producing fungi from cotton seed soapstock

Cited by 12 publications

References 27 publications

Industrial applications of fungal lipases: a review

Industrial applications of fungal lipases: a review

Cotton Productivity and Fiber Quality Improvement by Nano Chitosan-NPK Fertilizer Integrated with Plant Growth Promoting Rhizobacteria Application in North Delta of Egypt

Biodegradation of Soap Stock: As an Alternative Renewable Energy Resource and Reduce Environmental Pollution

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