Carrera de Biotecnología

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Subject: search.filters.subject.CINÉTICA ENZIMÁTICA

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    Degradación de polietileno tereftalato (PET) mediante el uso de la enzima IsPETasa N212A/S238Y a escala de biorreactor
    (Universidad Técnica de Ambato. Facultad de Ciencia e Ingeniería en Alimentos y Biotecnología. Carrera de Biotecnología, 2024-08) Caguana Tenelema, Wilma Alexandra; García Solís, Mario Daniel
    Plastic production in 2022 reached 400.3 metric tons, of which only 8.9 percent was recycled, while the remainder ended up in the environment. PET accounts for 6.2 percent of total plastic production, which represents a source of pollution of concern due to its low level of degradation and a half-life of more than 2,500 years. Conventional recycling methods (physical and chemical) cause secondary contamination, so biological recycling (biodegradation) through enzymes has been chosen. In this study, the degradation of polyethylene terephthalate (PET) using the enzyme IsPETase N212A S238Y was evaluated at bioreactor scale. After production of PETase enzyme at bioreactor scale using whey as autoinduction medium, 5 grams micronized commercial PET (PETc) was combined with 0.67 micromol of PETase prepared in 200 milliliters of 100 millimolar KPO4 buffer pH 8 for the degradation process. After 48 hours, biphasic degradation kinetics was observed. In addition, scanning electron microscopy (SEM) analyses revealed cleavages and cracked edges in the polymer. The N212A S238Y PETase enzyme PETase showed a 2.8 percent yield in the degradation of commercial PET (PETc) at bioreactor scale. This study suggests a new technology for sustainable PET recycling.
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    Caracterización cinética de las variantes silvestre y mutantes I208V, N212A y S238Y de la enzima PETasa de Ideonella sakaiensis
    (Universidad Técnica de Ambato. Facultad de Ciencia e Ingeniería en Alimentos y Biotecnología. Carrera de Biotecnología, 2024-08) Sierra Mena, Joselyn Patricia; García Solís, Mario Daniel
    The accumulation of plastic waste has reached critical levels, with 8 million tons polluting the oceans annually. The resulting microplastics enter ecosystems and organisms, posing a serious threat to environmental health. In response, bioremediation has emerged as a sustainable alternative, employing microorganisms or enzymes to degrade polymers. The enzyme IsPETase from Ideonella sakaiensis is particularly more effective than other PET-degrading enzymes. Thus, mutations close to the active site (S238Y, N212A and I208V) have been recently designed to improve its activity and thermostability, evaluated in qualitative analyses. Therefore, in this research the kinetics of these mutants was characterized by evaluating the kinetic parameters of the reactions catalyzed by these enzymes, using p(NP)-acetate as substrate and varying the temperature (25, 35 and 45 degrees Celsius). The data were analyzed with GraphPad Prism. A reduction in KM was observed in the mutants, indicating that the mutations increased the affinity for the substrate, although the decrease in kcat, reflected a lower catalytic capacity, especially for the I208V variant. Overall, all three mutations are less efficient than the WT variant in hydrolyzing phenyl esters under saturated conditions. Regarding the effect of temperature, the N212A variant showed the highest activity at 45 degrees Celsius, standing out as the most thermostable. This study aims to deepen the catalytic efficiency of IsPETase mutants, contributing to the development of biotechnological recycling for plastic wastes.