Boosting Hydrolysis of Cellulose at High Temperature by β‐Glucosidase Induced Metal–Organic Framework In‐Situ Co‐Precipitation Encapsulation

Abstract: Due to the poor enzyme thermal stability, the efficient conversion of high crystallinity cellulose into glucose in aqueous phase over 50 °C is challenging. Herein, an enzymeinduced MOFs encapsulation of β-glucosidase (β-G) strategy was proposed for the first time. By using various methods, including SEM, XRD, XPS, NMR, FTIR and BET, the successful preparation of a porous channel-type flower-like enzyme complex (β-G@MOFs) was confirmed. The prepared enzyme complex (β-G@MOFs) materials showed improved thermal st… Show more

“…Metal–organic frameworks (MOFs) are a class of porous framework materials formed by orderly coordination of metal nodes and organic ligand units. , They have high specific surface area, , tailorable pore structure, and rigid organic framework. − However, until now, owing to the microporous structure of MOFs, only a few enzymes can be encapsulated in situ by MOFs. Moreover, micropores smaller than 2 nm not only affect the accessibility and diffusivity of large macromolecules into the pores but also the enzymes “armored” by the microporosity MOFs suffer compromising activity (<10% of the original activity of the enzyme). , In previous work, our team has successfully prepared an ionic liquid-resistant and high-temperature-resistant flower-like enzyme complex β-G@MOF­(Cu-PABA) by the enzyme-induced MOF method and achieved rapidly hydrolysis of cellulose and cellobiose . However, due to the wide distribution of molecular weight of microcrystalline cellulose, some are concentrated in 2900–3600 g/mol (about 68–84 nm in diameter); this large molecular weight cellulose is difficult to enter the pore of the MOF (Cu-PABA), indicating that the enzyme lysis rate could only reach 50% .…”

“…Moreover, micropores smaller than 2 nm not only affect the accessibility and diffusivity of large macromolecules into the pores but also the enzymes “armored” by the microporosity MOFs suffer compromising activity (<10% of the original activity of the enzyme). , In previous work, our team has successfully prepared an ionic liquid-resistant and high-temperature-resistant flower-like enzyme complex β-G@MOF­(Cu-PABA) by the enzyme-induced MOF method and achieved rapidly hydrolysis of cellulose and cellobiose . However, due to the wide distribution of molecular weight of microcrystalline cellulose, some are concentrated in 2900–3600 g/mol (about 68–84 nm in diameter); this large molecular weight cellulose is difficult to enter the pore of the MOF (Cu-PABA), indicating that the enzyme lysis rate could only reach 50% . Therefore, it is very necessary to construct a MOF with macroporous structure to solve the above problems.…”

“…Simultaneously, under this strategy, MOF-Fe enabled in situ encapsulation of β-glucosidase (β-G), resulting in the construction of a macroporous enzyme complex (β-G@MOF-Fe) possessing superior synergistic catalysis ability. MOF­(Cu-PABA), a framework that is enabled to be assembled in a compatible way, was selected as the model MOF matrix . Specifically, during the formation of MOF-Fe, the addition of Fe 2+ created competitive coordination with the original metal Cu 2+ , and the doped Fe 2+ would preferentially coordinate with the amino-formed Fe 2+ –N bond according to the coordination characteristics of Fe 2+ . , Owing to the strong reducibility of Fe 2+ , Fe 2+ –N would convert into Fe 3+ –N under the action of oxygen.…”

“…30 However, due to the wide distribution of molecular weight of microcrystalline cellulose, some are concentrated in 2900−3600 g/mol (about 68−84 nm in diameter); this large molecular weight cellulose is difficult to enter the pore of the MOF (Cu-PABA), indicating that the enzyme lysis rate could only reach 50%. 30 Therefore, it is very necessary to construct a MOF with macroporous structure to solve the above problems.…”

Construction of Macroporous β-Glucosidase@MOFs by a Metal Competitive Coordination and Oxidation Strategy for Efficient Cellulose Conversion at 120 °C

“…Metal–organic frameworks (MOFs) are a class of porous framework materials formed by orderly coordination of metal nodes and organic ligand units. , They have high specific surface area, , tailorable pore structure, and rigid organic framework. − However, until now, owing to the microporous structure of MOFs, only a few enzymes can be encapsulated in situ by MOFs. Moreover, micropores smaller than 2 nm not only affect the accessibility and diffusivity of large macromolecules into the pores but also the enzymes “armored” by the microporosity MOFs suffer compromising activity (<10% of the original activity of the enzyme). , In previous work, our team has successfully prepared an ionic liquid-resistant and high-temperature-resistant flower-like enzyme complex β-G@MOF­(Cu-PABA) by the enzyme-induced MOF method and achieved rapidly hydrolysis of cellulose and cellobiose . However, due to the wide distribution of molecular weight of microcrystalline cellulose, some are concentrated in 2900–3600 g/mol (about 68–84 nm in diameter); this large molecular weight cellulose is difficult to enter the pore of the MOF (Cu-PABA), indicating that the enzyme lysis rate could only reach 50% .…”

“…Moreover, micropores smaller than 2 nm not only affect the accessibility and diffusivity of large macromolecules into the pores but also the enzymes “armored” by the microporosity MOFs suffer compromising activity (<10% of the original activity of the enzyme). , In previous work, our team has successfully prepared an ionic liquid-resistant and high-temperature-resistant flower-like enzyme complex β-G@MOF­(Cu-PABA) by the enzyme-induced MOF method and achieved rapidly hydrolysis of cellulose and cellobiose . However, due to the wide distribution of molecular weight of microcrystalline cellulose, some are concentrated in 2900–3600 g/mol (about 68–84 nm in diameter); this large molecular weight cellulose is difficult to enter the pore of the MOF (Cu-PABA), indicating that the enzyme lysis rate could only reach 50% . Therefore, it is very necessary to construct a MOF with macroporous structure to solve the above problems.…”

“…Simultaneously, under this strategy, MOF-Fe enabled in situ encapsulation of β-glucosidase (β-G), resulting in the construction of a macroporous enzyme complex (β-G@MOF-Fe) possessing superior synergistic catalysis ability. MOF­(Cu-PABA), a framework that is enabled to be assembled in a compatible way, was selected as the model MOF matrix . Specifically, during the formation of MOF-Fe, the addition of Fe 2+ created competitive coordination with the original metal Cu 2+ , and the doped Fe 2+ would preferentially coordinate with the amino-formed Fe 2+ –N bond according to the coordination characteristics of Fe 2+ . , Owing to the strong reducibility of Fe 2+ , Fe 2+ –N would convert into Fe 3+ –N under the action of oxygen.…”

“…30 However, due to the wide distribution of molecular weight of microcrystalline cellulose, some are concentrated in 2900−3600 g/mol (about 68−84 nm in diameter); this large molecular weight cellulose is difficult to enter the pore of the MOF (Cu-PABA), indicating that the enzyme lysis rate could only reach 50%. 30 Therefore, it is very necessary to construct a MOF with macroporous structure to solve the above problems.…”

Construction of Macroporous β-Glucosidase@MOFs by a Metal Competitive Coordination and Oxidation Strategy for Efficient Cellulose Conversion at 120 °C

“…19−21 In the previous study, our research group have successfully structured floral complexes β-G@MOF(Cu-PABA) with resistance to ionic liquids, as well as high-temperature resistance by the enzyme-induced MOF method. 22 However, owing to the longer mass-transfer distance of the prepared 3D enzyme complex (the particle size was 22 μm), the enzyme catalytic performance was not significantly improved. As a result, it is very meaningful to prepare MOFs with a mesoporous structure, thinner crystal thickness, and more exposed active sites to solve the above problems.…”

Encapsulating β-Glucosidase within Nanoporous ZIF-8-Cu Nanoparticles Enables High-Temperature Activity

Enhancing cellulose hydrolysis via cellulase immobilization on zeolitic imidazolate frameworks using physical adsorption