TY - JOUR
T1 - Mesoporous Silica Materials Labeled for Optical Oxygen Sensing and Their Application to Development of a Silica-Supported Oxidoreductase Biocatalyst
AU - Bolivar, Juan M.
AU - Schelch, Sabine
AU - Mayr, Torsten
AU - Nidetzky, Bernd
PY - 2015/10/2
Y1 - 2015/10/2
N2 - Porous silica materials make great supports for heterogeneous catalysis with immobilized enzymes; however, direct functionalization of their surface through stable attachment of enzymes, reporter molecules, or both is a difficult problem. Overcoming that is necessary for practical implementation. Here, we integrate the development of luminophor-doped oxygen-sensing silica materials with a modular strategy of enzyme immobilization to demonstrate generally applicable design of an oxygen-dependent biocatalyst on a porous silica support. Zbasic2, a highly positively charged silica-binding module of about 7 kDa size, was fused to d-amino acid oxidase, and the resulting chimeric protein was tethered noncovalently via Zbasic2 in defined orientation and in a highly selective manner on silica. The enzyme supports used differed in overall shape and size as well as in internal pore structure. A confocal laser scanning microscopy (CLSM) analysis that employed the oxidases flavin cofactor as the fluorescent reporter group showed a homogeneous internal protein distribution in all supports used. Ru-based organometallic luminophor was adsorbed tightly onto the silica supports, thus enabling internal optical sensing of the O2 available to the enzymatic reaction. Optimization of the surface labeling regarding homogeneous luminophor distribution was guided, and its efficacy was verified by CLSM. Mesostructured silica surpassed controlled pore glass by ≥10-fold in terms of immobilized enzyme effectiveness at high loading of oxidase activity. The effect was shown from detailed comparison of the time-resolved O2 concentration profiles in solution and inside porous support to result exclusively from variable degrees of diffusion-caused limitation in the internal O2 availability. Enzyme immobilized on mesostructured silica approached perfection of a heterogeneous biocatalyst in being almost as effective as the free enzyme (assayed in oxidative deamination of d-methionine), thus emphasizing the large benefit of targeted mass transfer intensification, through proper choice of support parameters, in the development of immobilizates of O2-dependent oxidoreductases on porous silica material.
AB - Porous silica materials make great supports for heterogeneous catalysis with immobilized enzymes; however, direct functionalization of their surface through stable attachment of enzymes, reporter molecules, or both is a difficult problem. Overcoming that is necessary for practical implementation. Here, we integrate the development of luminophor-doped oxygen-sensing silica materials with a modular strategy of enzyme immobilization to demonstrate generally applicable design of an oxygen-dependent biocatalyst on a porous silica support. Zbasic2, a highly positively charged silica-binding module of about 7 kDa size, was fused to d-amino acid oxidase, and the resulting chimeric protein was tethered noncovalently via Zbasic2 in defined orientation and in a highly selective manner on silica. The enzyme supports used differed in overall shape and size as well as in internal pore structure. A confocal laser scanning microscopy (CLSM) analysis that employed the oxidases flavin cofactor as the fluorescent reporter group showed a homogeneous internal protein distribution in all supports used. Ru-based organometallic luminophor was adsorbed tightly onto the silica supports, thus enabling internal optical sensing of the O2 available to the enzymatic reaction. Optimization of the surface labeling regarding homogeneous luminophor distribution was guided, and its efficacy was verified by CLSM. Mesostructured silica surpassed controlled pore glass by ≥10-fold in terms of immobilized enzyme effectiveness at high loading of oxidase activity. The effect was shown from detailed comparison of the time-resolved O2 concentration profiles in solution and inside porous support to result exclusively from variable degrees of diffusion-caused limitation in the internal O2 availability. Enzyme immobilized on mesostructured silica approached perfection of a heterogeneous biocatalyst in being almost as effective as the free enzyme (assayed in oxidative deamination of d-methionine), thus emphasizing the large benefit of targeted mass transfer intensification, through proper choice of support parameters, in the development of immobilizates of O2-dependent oxidoreductases on porous silica material.
KW - biocatalysis
KW - enzyme immobilization
KW - fusion protein
KW - intraparticle oxygen gradient
KW - optical sensing
KW - oxygen-dependent oxidations
KW - silica binding module
KW - silica materials
UR - http://www.scopus.com/inward/record.url?scp=84943146376&partnerID=8YFLogxK
U2 - 10.1021/acscatal.5b01601
DO - 10.1021/acscatal.5b01601
M3 - Article
AN - SCOPUS:84943146376
SN - 2155-5435
VL - 5
SP - 5984
EP - 5993
JO - ACS Catalysis
JF - ACS Catalysis
IS - 10
ER -