Immobilization of Proteins in Silica Gel: Biochemical and Biophysical Properties

Ronda, Luca; Bruno, Stefano; Campanini, Barbara; Mozzarelli, Andrea; Abbruzzetti, Stefania; Viappiani, Cristiano; Cupane, Antonio; Levantino, Matteo; Bettati, Stefano

doi:10.2174/1385272819666150601211349

Cited by 23 publications

(17 citation statements)

References 217 publications

(297 reference statements)

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“…A low degree of condensation, which in the case of silica gels corresponds to a high amount of free hydroxyl groups, high ability of water binding, and large pores, yields looser matrices; a high degree of condensation yields more rigid systems with smaller pores. This is the result of a different average numbers of covalent bonds per molecular unit, which generates a discontinuity in the behavior at the molecular scale: the rigidity increases stepwise and is defined at the moment of the gel formation, and any modulation arises from the presence of a mixed population of pores with different diameters or hydration [13].…”

Section: Hard and Soft Entrapment: Host Matrices' Effects On Biomolecmentioning

confidence: 99%

“…For the same structural reasons (prevailing covalent bonds and low flexibility), in silica gel or other more structured matrices (e.g., zeolites), the confining environment is geometrically characterized: the dimensions and shapes of the pores that form in the rigid scaffold determine the confining ability, the type of macromolecules that can be embedded, and the properties of the "solvent" layer trapped within the pores [13]. The larger flexibility in saccharide confinement makes porosity not the primary measure of the confining ability: polysaccharide matrices with defined porosity do exist, but the macromolecular scaffold is in any case less rigid and allows a certain degree of adaptability, allowing also the hosting of macromolecules with dimensions or shapes not properly matching those of the pores.…”

Section: Hard and Soft Entrapment: Host Matrices' Effects On Biomolecmentioning

confidence: 99%

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More than a Confinement: “Soft” and “Hard” Enzyme Entrapment Modulates Biological Catalyst Function

et al. 2019

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Catalysis makes chemical and biochemical reactions kinetically accessible. From a technological point of view, organic, inorganic, and biochemical catalysis is relevant for several applications, from industrial synthesis to biomedical, material, and food sciences. A heterogeneous catalyst, i.e., a catalyst confined in a different phase with respect to the reagents’ phase, requires either its physical confinement in an immobilization matrix or its physical adsorption on a surface. In this review, we will focus on the immobilization of biological catalysts, i.e., enzymes, by comparing hard and soft immobilization matrices and their effect on the modulation of the catalysts’ function. Indeed, unlike smaller molecules, the catalytic activity of protein catalysts depends on their structure, conformation, local environment, and dynamics, properties that can be strongly affected by the immobilization matrices, which, therefore, not only provide physical confinement, but also modulate catalysis.

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Section: Hard and Soft Entrapment: Host Matrices' Effects On Biomolecmentioning

confidence: 99%

Section: Hard and Soft Entrapment: Host Matrices' Effects On Biomolecmentioning

confidence: 99%

More than a Confinement: “Soft” and “Hard” Enzyme Entrapment Modulates Biological Catalyst Function

et al. 2019

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“…puuE was encapsulated in a silica matrix by the sol-gel method [24,25]. Tetramethylorthosilicate (TMOS), water and a 40 mM HCl solution were mixed and sonicated for 20 min (divided in 5-min on and 1-min off cycles), then an equal volume of 10 mM phosphate, pH 6.0, was added and the solution was fluxed with humidified nitrogen for 40 min.…”

Section: Enzyme Encapsulationmentioning

confidence: 99%

“…The relevance of a biosensor resides in the selectivity and sensitivity in target quantification and reusability, determining its applicability as a tool for routine clinical practice. With this purpose, we entrapped puuE in a wet nanoporous silica gel matrix, a strategy largely exploited in enzyme immobilization because of its several advantages, among which the easy and flexible chemistry, with mild chemical and physical entrapment conditions compatible with protein stability, the optical transparency allowing signal detection with conventional spectroscopic techniques, the ease of separation of the active material from the reaction solution [24][25][26][27][28][29][30][31].…”

Section: Introductionmentioning

confidence: 99%

Immobilization of Allantoinase for the Development of an Optical Biosensor of Oxidative Stress States

Marchetti

Ronda

Percudani

et al. 2019

Sensors

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Allantoin, the natural end product of purine catabolism in mammals, is non-enzymatically produced from the scavenging of reactive oxygen species through the degradation of uric acid. Levels of allantoin in biological fluids are sensitively influenced by the presence of free radicals, making this molecule a candidate marker of acute oxidative stress in clinical analyses. With this aim, we exploited allantoinase-the enzyme responsible for allantoin hydrolization in plants and lower organisms-for the development of a biosensor exploiting a fast enzymatic-chemical assay for allantoin quantification. Recombinant allantoinase was entrapped in a wet nanoporous silica gel matrix and its structural properties, function, and stability were characterized through fluorescence spectroscopy and circular dichroism measurements, and compared to the soluble enzyme. Physical immobilization in silica gel minimally influences the structure and the catalytic efficiency of entrapped allantoinase, which can be reused several times and stored for several months with good activity retention. These results, together with the relative ease of the sol-gel preparation and handling, make the encapsulated allantoinase a good candidate for the development of an allantoin biosensor.

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“…It is well-known that encapsulation of biomolecule, such as proteins [1] [2], enzymes [3], antibodies and cells [1], using sol-gels method is widely considered for research in the development of biosensor [4] [5] [6], tissue engineering [7], and drug delivery [8] [9]. This technique involves the inclusion of a biomolecule in an inorganic matrix where mobility is restricted but allows migration of particular analytes through the gel lattice [10] [11].…”

Section: Introductionmentioning

confidence: 99%

Transfer and Reactivity of Hydrogen Sulfide with Immobilized Hemeproteins in Polymeric Matrix

Vargas-Santiago¹,

López‐Garriga²

2019

JEAS

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Hydrogen sulfide (H 2 S) has been related to be toxic and to have a role in human physiological functions. Therefore, there is a necessity to comprehend ways to scavenger hydrogen sulfide from different media. Here, we used recombinant metaquo-Hemoglobin I (metHbI) from Lucina pectinata and metaquo-myoglobin (metMb) encapsulated in the tetramethyl orthosilicate gel (TMOS), to facilitate the understanding of H 2 S transfer toward these metaquo-hemeproteins. In this sol-gel environment, metHbI binds and releases H 2 S with rate constants of 0.0597 M −1 •s −1 and 6.67 × 10 −5 s −1 , respectively. The process generates an H 2 S affinity constant (k on /k off) of 8.9 × 10 2 M −1 , which is 10 7 lowers than the analogous constant in solution (6.3 × 10 9 M −1). Although the H 2 S k off for the rHbI-H 2 S complex is almost similar with both sol-gel and solution. To further understand how the H 2 S k off from rHbI-H 2 S in solution (5 µM) is influenced by the protein concentration gradient, metHbI and metMb (25 µM) encapsulated in TMOS sol-gel. Under these circumstances, the H 2 S transfer from a solution of the rHbI-H 2 S complex to encapsulated hemeprotein resulted in k off values of 1.90 × 10 −4 s −1 , and 2.09 × 10 −4 s −1 leading to the formation of rHbI-H 2 S and Mb-H 2 S species, respectively. The results suggest that the: 1) extreme ionic TMOS construct limits the H 2 S pathways to reach the hemeprotein active center, 2) possible interaction with metHbI hydrophilic forces increases the hydrogen bonding networking and decreases the H 2 S association constant, 3) hemeproteins concentration gradients between solution and sol-gels also influence its hydrogen sulfide transfer. In the presence of oxygen or hydrogen peroxide metMb generated a mixture of Mb-H 2 S and sulfmyoglobin derivative, while encapsulated metHbI reaction did not produce the sulfheme species. Consequently, the results show that metHbI encapsulated in TMOS is an excellent trap for H 2 S from solution or gas media.

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Immobilization of Proteins in Silica Gel: Biochemical and Biophysical Properties

Cited by 23 publications

References 217 publications

More than a Confinement: “Soft” and “Hard” Enzyme Entrapment Modulates Biological Catalyst Function

More than a Confinement: “Soft” and “Hard” Enzyme Entrapment Modulates Biological Catalyst Function

Immobilization of Allantoinase for the Development of an Optical Biosensor of Oxidative Stress States

Transfer and Reactivity of Hydrogen Sulfide with Immobilized Hemeproteins in Polymeric Matrix

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