Delivery of Nucleic Acids via Disulfide‐Based Carrier Systems

Bauhuber, Sonja; Hozsa, Constantin; Breunig, Miriam; Göpferich, Achim

doi:10.1002/adma.200802453

Cited by 248 publications

(233 citation statements)

References 198 publications

(219 reference statements)

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“…The nature of biomaterials and drug delivery systems incorporating disulfides is varied: Bauhuber et al discuss the use of disulfide-based redox linkers for the delivery of nucleic acids. [1] Meng et al report advances in the development of reduction-sensitive biodegradable polymers and conjugates, with particular focus on the up-to-date design and chemistry of various reduction-sensitive delivery systems including liposomes, polymersomes, micelles, nanoparticles, gels, etc. [2] In addition, immunoconjugates bearing disulfide linkers have been surveyed by Kratz et al [3] and Wu and Senter.…”

Section: Introductionmentioning

confidence: 98%

Interplay of Chemical Microenvironment and Redox Environment on Thiol–Disulfide Exchange Kinetics

Belenda

Leroux

et al. 2011

Chemistry A European J

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The interplay between the chemical microenvironment surrounding disulfides and the redox environment of the media on thiol-disulfide exchange kinetics was examined by using a peptide platform. Exchange kinetics of up to 34 cysteine-containing peptides were measured in several redox buffers. The electrostatic attraction/repulsion between charged peptides and reducing agents such as glutathione was found to have a very pronounced effect on thiol-disulfide exchange kinetics (differences of ca. three orders of magnitude). Exchange kinetics could be directly correlated to peptide charge over the entire range examined. This study highlights the possibility of finely and predictably tuning thiol-disulfide exchange, and demonstrates the importance of considering both the local environment surrounding the disulfide and the nature of the major reducing species present in the environment for which their use is intended (e.g., in drug delivery systems, sensors, etc).

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Section: Introductionmentioning

confidence: 98%

Interplay of Chemical Microenvironment and Redox Environment on Thiol–Disulfide Exchange Kinetics

Belenda

Leroux

et al. 2011

Chemistry A European J

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“…[ 8 ] A gradual solubilization was noted, and a slightly turbid solution was obtained after 12 d under stirring (see images in Figure S9, Supporting Information). The reaction progress was assessed using 13 C NMR. Figure 4 (down) gives the 13 C NMR spectra of 1 , P1 , and P1R the polymer after reduction.…”

Section: Resultsmentioning

confidence: 99%

“…The reaction progress was assessed using 13 C NMR. Figure 4 (down) gives the 13 C NMR spectra of 1 , P1 , and P1R the polymer after reduction. The extent of reduction is refl ected by the integral ratios of the carbon signal of the methylene group (C b ) adjacent to the thiol group at 19.7 ppm to that of a reference resonance, such as the CH 2 (C j ) in alpha position of the methyl group at 22.9 ppm.…”

Section: Resultsmentioning

confidence: 99%

Photoinduced Cross‐Linking of Dynamic Poly(disulfide) Films via Thiol Oxidative Coupling

Feillée

Chemtob

Ley

et al. 2015

Macromol. Rapid Commun.

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Initially developed as an elastomer with an excellent record of barrier and chemical resistance properties, poly(disulfide) has experienced a revival linked to the dynamic nature of the S-S covalent bond. A novel photobase-catalyzed oxidative polymerization of multifunctional thiols to poly(disulfide) network is reported. Based solely on air oxidation, the single-step process is triggered by the photodecarboxylation of a xanthone acetic acid liberating a strong bicyclic guanidine base. Starting with a 1 μm thick film based on trithiol poly(ethylene oxide) oligomer, the UV-mediated oxidation of thiols to disulfides occurs in a matter of minutes both selectively, i.e., without overoxidation, and quantitatively as assessed by a range of spectroscopic techniques. Thiolate formation and film thickness determine the reaction rates and yield. Spatial control of the photopolymerization serves to generate robust micropatterns, while the reductive cleavage of S-S bridges allows the recycling of 40% of the initial thiol groups.

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“…The cytosol has a low redox potential due to the abundance of reduced glutathione (GSH) in the millimolar concentration range, whereas the extracellular glutathione concentration falls in the micromolar range 126 . To utilize this redox potential difference, a variety of gene delivery systems based on the dissociation of disulfide bonds have been reported [127][128][129][130][131] . Similarly, we reason here that protein NCs interconnected by a disulfide-containing crosslinker through interfacial polymerization can maintain the integrity of the thin polymer shell under oxidative 43 conditions outside the cell, but it should undergo rapid degradation and cargo release after entry into the cytosol.…”

Section: Discussionmentioning

confidence: 99%

Redox-responsive nanocapsules for intracellular protein delivery

et al. 2011

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Proteins play a crucial role in life, taking part in all vital processes in the body. Intracellular protein delivery holds enormous promise for biological and medical applications, including cancer therapy, vaccination, regenerative medicine, treatment for loss-of-function genetic diseases and imaging. Engineering vehicles for escorting therapeutic proteins into specific cells in a controlled release fashion has thus generated considerable interest. The development of such therapeutics to selectively target tumor has also been a major research focus in cancer nanotechnology. A novel strategy using polymeric redox-responsive nanocapsules for intracellular protein delivery is described, in which through in situ interfacial polymerization, the target therapeutic protein is noncovalently encapsulated into a biocompatible polymeric shell interconnected by disulfide-containing crosslinkers. The dissociation of the polymeric shell under reducing conditions and the subsequent release of protein were confirmed using cell-free assays in the presence of glutathione. Several therapeutic proteins with different properties, both cytosolic and nuclear, were successfully delivered using the platform. The nanocapsules were demonstrated to be efficiently internalized into mammalian cells through interactions between charge or targeting ligand, iii and to release the protein in the reducing cytosol in active forms. Using such redoxresponsive nanocapsule as a vehicle, pro-apoptotic protein caspase 3 was delivered to induce apoptosis in a variety of human cancer cell lines, including HeLa, MCF-7 and U-87 MG.Tumor-selective killer apoptin was delivered into different breast cancer cell lines as well, which led to rapid resurrection of apoptosis in breast cancer cell lines and shrinkage of xenograft mice models. Tumor suppressor p53 protein, the most commonly mutated protein, was also delivered selectively into tumor cells for apoptosis induction, through targeted redox-responsive nanocapsules. The delivery methodology is general, effective and nontoxic towards healthy cells. This work facilitate the development of new tools for tumorgenesis and drug resistance studies, as well as expanding current therapeutic target pool to many other tumor suppressor proteins for cancer treatment.iv The Dissertation of Muxun Zhao is approved.

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Delivery of Nucleic Acids via Disulfide‐Based Carrier Systems

Cited by 248 publications

References 198 publications

Interplay of Chemical Microenvironment and Redox Environment on Thiol–Disulfide Exchange Kinetics

Interplay of Chemical Microenvironment and Redox Environment on Thiol–Disulfide Exchange Kinetics

Photoinduced Cross‐Linking of Dynamic Poly(disulfide) Films via Thiol Oxidative Coupling

Redox-responsive nanocapsules for intracellular protein delivery

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