<p>Laccase (LAC) was immobilized onto sponge gourd (<i>Luffa cylindrica</i>) through a two step method involving physical adsorption followed by glutaraldehyde-mediated crosslinking. The immobilization parameters were systematically optimized, resulting in maximum catalytic activity (52.98 ± 0.85 U/g) and protein loading efficiency (62.09%) under the following conditions: 2.5&#xa0;mg/L LAC concentration, 15&#xa0;mg carrier, 90&#xa0;min adsorption time, 120&#xa0;min crosslinking time, and 3% glutaraldehyde. Compared to the free LAC, the immobilized LAC showed a 5&#xa0;°C increase in optimum temperature and a broader pH activity range. It also exhibited significantly improved thermal and pH stability, retaining 33% and 39% more activity after 240&#xa0;min at 50&#xa0;°C and 60&#xa0;°C, respectively. Storage stability was enhanced, with 57% activity retained after 30 days at 4&#xa0;°C, compared to only 16% for free LAC. Kinetic analysis revealed a moderate increase in K<sub>m</sub> (from 0.53 to 0.72 mM) and a decrease in V<sub>max</sub> (from 0.85 to 0.69 mmol/L min), suggesting minor diffusional resistance. In Bisphenol A (BPA) degradation tests, the immobilized enzyme achieved complete removal of 15&#xa0;mg/L BPA within 240&#xa0;min and maintained 46% removal efficiency after 10 reuse cycles. These findings demonstrate that sponge gourd is a cost effective, biodegradable support material that can significantly enhance LAC performance for potential applications in environmental remediation.</p>

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Laccase immobilization on a natural lignocellulosic biomass support: optimization, characterization, and bisphenol A degradation

  • Metin Utku Koç,
  • Ceyhun Işık

摘要

Laccase (LAC) was immobilized onto sponge gourd (Luffa cylindrica) through a two step method involving physical adsorption followed by glutaraldehyde-mediated crosslinking. The immobilization parameters were systematically optimized, resulting in maximum catalytic activity (52.98 ± 0.85 U/g) and protein loading efficiency (62.09%) under the following conditions: 2.5 mg/L LAC concentration, 15 mg carrier, 90 min adsorption time, 120 min crosslinking time, and 3% glutaraldehyde. Compared to the free LAC, the immobilized LAC showed a 5 °C increase in optimum temperature and a broader pH activity range. It also exhibited significantly improved thermal and pH stability, retaining 33% and 39% more activity after 240 min at 50 °C and 60 °C, respectively. Storage stability was enhanced, with 57% activity retained after 30 days at 4 °C, compared to only 16% for free LAC. Kinetic analysis revealed a moderate increase in Km (from 0.53 to 0.72 mM) and a decrease in Vmax (from 0.85 to 0.69 mmol/L min), suggesting minor diffusional resistance. In Bisphenol A (BPA) degradation tests, the immobilized enzyme achieved complete removal of 15 mg/L BPA within 240 min and maintained 46% removal efficiency after 10 reuse cycles. These findings demonstrate that sponge gourd is a cost effective, biodegradable support material that can significantly enhance LAC performance for potential applications in environmental remediation.