Glucose oxidase loaded Cu2+ based metal-organic framework for glutathione depletion/reactive oxygen species elevation enhanced chemotherapy.

INTRODUCTION: The development of multidrug resistance (MDR) is a major cause for the failure of chemotherapy, which requires the aid of nanomedicine. METHODS: Here in our study, a Cu2+ based metal-organic framework (COF) was firstly developed and employed as a carrier for the delivery of glucose oxidase (GOx) and doxorubicin (Dox) (COF/GOx/Dox) for the therapy of MDR lung cancers. RESULTS: Our results showed that the GOx can catalyze glucose and produce H2O2. In the mean time, the Cu2+ can react with GSH and then transform into Cu+, which resulted in GSH depletion. Afterwards, the produced Cu+ and H2O2 trigger Fenton reaction to generate ROS to damage the redox equilibrium of cancer cells. Both effects contributed to the reverse of MDR in A549/Dox cells and finally resulted in significantly enhanced in vitro/in vivo anticancer performance. DISCUSSION: The combination of glutathione depletion/reactive oxygen species elevation might be a promising strategy to enhance the efficacy of chemotherapy and reverse MDR in cancers.

A three-enzyme cascade reaction through positional assembly of enzymes in a polymersome nanoreactor.

Porous polymersomes based on block copolymers of isocyanopeptides and styrene have been used to anchor enzymes at three different locations, namely, in their lumen (glucose oxidase, GOx), in their bilayer membrane (Candida antarctica lipase B, CalB) and on their surface (horseradish peroxidase, HRP). The surface coupling was achieved by click chemistry between acetylene-functionalised anchors on the surface of the polymersomes and azido functions of HRP, which were introduced by using a direct diazo transfer reaction to lysine residues of the enzyme. To determine the encapsulation and conjugation efficiency of the enzymes, they were decorated with metal-ion labels and analysed by mass spectrometry. This revealed an almost quantitative immobilisation efficiency of HRP on the surface of the polymersomes and a more than statistical incorporation efficiency for CalB in the membrane and for GOx in the aqueous compartment. The enzyme-decorated polymersomes were studied as nanoreactors in which glucose acetate was converted by CalB to glucose, which was oxidised by GOx to gluconolactone in a second step. The hydrogen peroxide produced was used by HRP to oxidise 2,2'-azinobis(3-ethylbenzothiazoline-6-sulfonic acid) (ABTS) to ABTS(.+). Kinetic analysis revealed that the reaction step catalysed by HRP is the fastest in the cascade reaction.

Preparation of poly(ethylene glycol) hydrogels with different network structures for the application of enzyme immobilization.

In this study, poly(ethylene glycol) (PEG)-based hydrogels having different network structures were synthesized by UV-initiated photopolymerization and used for the enzyme immobilization. PEGs with different molecular weight were acrylated by derivatizing both ends with acryloyl chloride and photopolymerization of PEG-diacrylate (PEG-DA) yielded crosslinked hydrogel network within 5 seconds. Attachment of acrylate groups and gelation were confirmed by ATR/FT-IR and FT-Raman spectroscopy. Network structures of hydrogels could be easily controlled by changing the molecular weight (MW) of PEG-DA and characterized by calculating molecular weight between crosslinks and mesh size from the swelling measurement. Synthesis of hydrogels with higher MW of PEG produced less crosslinked hydrogels having higher water content, larger value of Mc and mesh size, which resulted in enhanced mass transfer but loss of mechanical properties. For the enzyme immobilization, glucose oxidase (GOX) was immobilized inside PEG hydrogels by means of physical entrapment and covalent immobilization. Encapsulated GOX were covalently bound to PEG backbone using acryloyl-PEG-N-hydroxysuccinimide and maintained their activity over a week period without leakage. Kinetic study indicated that immobilized enzyme inside hydrogel prepared from higher MW of PEG possessed lower apparent Km (Michaelis-Menten constant) and higher activity.

Preparation and characterization of reactive and stable glucose oxidase-containing liposomes modulated with detergent.

Glucose oxidase-containing liposomes (GOL) as well as detergent-modulated glucose oxidase-containing liposomes were prepared and characterized, focusing not only on the reactivity of the liposomes upon external addition of glucose but also on the leakage of the entrapped glucose oxidase (GO) from the liposomes with the aim of developing a reactive and stable liposomal GO system. The membranes of the GOL prepared were composed of 1-palmitoyl-2-oleoyl-sn-glycero-3-phosphocholine (POPC) and modulated with either Triton X-100 or cholate. In the absence of added detergent, no GO leakage from the GOL was observed while its enzymatic activity was very low (low glucose permeability). As detergent-modulated liposomes, mixed POPC/Triton X-100 and mixed POPC/cholate liposomes (abbreviated as TL and CL, respectively) were prepared at different effective detergent/POPC molar ratios (R(e)) ranging from R(e) = 0 to R(e) = R(e) (sat) (R(e) (sat) is the critical value of R(e) at which the liposome membrane is saturated with detergent). The reactivity of GO-loaded TL (abbreviated as GOTL) or GO-loaded CL (GOCL) increased drastically with increase in the respective detergent content in the liposomes. In the case of GOTL, at R(e) (sat) = 0.40, a high reactivity was measured with a simultaneous high extent of GO leakage, suggesting that the observed enzymatic reaction was catalyzed mainly by leaked GO, caused by the interaction of Triton X-100 with the POPC membrane. On the other hand, GOCL prepared at R(e) (sat) = 0.43 showed relatively high reactivity with only a small extent of GO leakage, suggesting that most of the enzyme reaction was limited by the glucose permeation across the bilayers of GOCL. The GO leakage from GOCL was found to occur mostly during the rearrangement of the liposomal membrane during the preparation of the GOCL (mixing the GOL and cholate). Fluorescence polarization measurements of membrane-associated DPH (1,6-diphenyl-1,3,5-hexatriene) indicated that CL prepared by modifying POPC with cholate did not lead to a drastic change in membrane fluidity, indicating that the interacting cholate molecules did not penetrate deeply into the POPC bilayers. In summary, it was clearly shown that the membrane permeability of GOL can be quite simply modulated by mixing it with a certain amount of cholate to form highly reactive and stable GOCL with minimal enzyme leakage.

Influence of process parameters on the protein stability encapsulated in poly-DL-lactide-poly(ethylene glycol) microspheres.

Glucose oxidase (GOD) has been encapsulated as a model protein within poly-DL-lactide-poly(ethylene glycol) (PELA) microspheres to evaluate the activity retention during microencapsulation process. This paper was aimed to investigate the effect of process parameters, such as the preparation method, the used matrix polymer with different compositions, the solvent system and the addition of stabilizer on the structural integrity and activity retention of encapsulated protein. The stability of the protein released during in vitro assay was also assessed. The obtained results showed that the solvent extraction/evaporation method based on the formation of double emulsion w(1)/o/w(2) benefited the activity retention compared with the phase separation method based on the formation of w/o(1)/o(2). And in the emulsion-evaporation system most of the protein activity was lost during the first emulsification procedure to form primary emulsion w(1)/o (ca. 28%) and the second emulsification procedure to form the double emulsion w(1)/o/w(2) (ca. 20%), in contrast to other processes occurring during microspheres preparation. The matrix polymer and the solvent system in the oil phase had an impressive impact on the activity retention, while the addition of gelatin in the internal aqueous phase resulted in no major reduction of activity loss. GOD release from PELA microspheres exhibited a triphasic profile, that is, the initial burst release during the first day, the gradual release over about 1 month, and then the second burst release. The encapsulation of GOD in PELA microspheres was effective in reducing its specific activity loss. Sixty-seven per cent of the initial specific activity retention was detected for the released GOD from microspheres formulation during 1 week of incubation, but nearly all the activity was lost for GOD in solution incubated under the same condition. SDS-PAGE results showed that, although the activity loss was detected, no rough changes of molecular weight of GOD was observed during encapsulation procedure and the initial days of incubation into the in vitro release medium.

Design and synthesis of a protein device that releases insulin in response to glucose concentration.

To synthesize a glucose-sensitive insulin-releasing protein device, insulin was esterified with methanol and connected to glucose oxidase with intervention of a disulfide compound, 5,5'-dithiobis(2-nitrobenzoic acid). On adding glucose to an aqueous solution containing the hybrid enzyme, the modified insulin was released. The amount of insulin released increased with increasing concentration of added glucose. The insulin release from the hybrid enzyme was specific to glucose. The activity of released insulin was about 80% of the unmodified insulin.

Semisynthetic fluorohydrolases prepared by chemical modification of ribonuclease.

A process for conformational modification of protein, which we have previously reported, was investigated as a means of generating fluorohydrolase activity in bovine ribonuclease (RNase). The resulting modified RNase had catalytic activity that depended upon the chosen modifier. Bovine pancreatic ribonuclease, modified by addition of hexamethylphosphoramide (HMPA) at pH 3, was derivatized with diimidates of chain lengths from C1 to C8. The derivative with the highest activity was obtained when RNase was crosslinked with dimethyl pimelimidate (C5). This derivative, which was active over a pH range of 6.5 to 8.0 with an optimum pH of 7.4, hydrolyzed phenylmethylsulfonylfluoride (PMSF) and the potent acetylcholinesterase inhibitor, diisopropyl phosphorofluoridate (DFP). The mean fluorohydrolase activity for four preparations using dimethyl pimelimidate was 0.8 +/- 0.2 U mg-1. Gel filtration on G-75 Sephadex and SDS-polyacrylamide gel electrophoresis showed components having a molecular weight of 13,000 and 27,000, with activity restricted to the 27,000 molecular weight fraction. After gel filtration, the specific activity was 9.1 +/- 2.4 U mg-1, resulting in a molecular activity of 125 min-1. The mechanism of this unique transformation of RNase into a fluorohydrolase is not known, nor has the location of the active site been determined.

Preparation and kinetic properties of 5-ethylphenazine-glucose-dehydrogenase-NAD+ conjugate, a semisynthetic glucose oxidase.

5-Ethylphenazine-glucose-dehydrogenase-NAD+ conjugate (EP(+)-GlcDH-NAD+) was prepared by linking both poly(ethylene glycol)-bound 5-ethylphenazine and poly(ethylene glycol)-bound NAD+ to glucose dehydrogenase. The average number of the ethylphenazine moieties bound/enzyme subunit was 0.8, and that of the NAD+ moieties was 1.2. This conjugate is a semisynthetic enzyme having glucose oxidase activity using oxygen or 3-(4,5-dimethyl-2-thiazolyl)-2, 5-diphenyl-2H-tetrazolium bromide (MTT) as an electron acceptor. When the concentration of oxygen or MTT is varied, the oxidase activity fits the Michaelis-Menten equation with the following values of the kinetic constants: for the system with oxygen, the turnover number per subunit is 0.40 s-1 and Km for oxygen is 1.57 mM; and for the system with MTT, the turnover number is 0.11 s-1 and Km for MTT is 0.072 mM. The catalytic cycle of the semisynthetic oxidase has two catalytic steps: reduction of the NAD+ moiety by the active site of the glucose dehydrogenase moiety and oxidation of the NADH moiety by another catalytic site of the ethylphenazine moiety. The apparent intramolecular rate constants of these steps were estimated, and the values are as follows: 0.39 s-1 for the reductions of the NAD+ moiety, 2.2 s-1 and 0.12 s-1 for the oxidation of the NADH moiety in the systems with oxygen and with MTT, respectively, and 3.2 s-1 and 0.18 s-1 for the reduction of the ethylphenazine moiety in the systems with oxygen and with MTT, respectively. On the bases of these results, the following three rate-acceleration mechanisms of the semisynthetic glucose oxidase are discussed: high effective concentration, intramolecular coupling of successive catalytic reactions, and multiple connection between the two kinds of the catalytic sites.