Interbilayer-crosslinked multilamellar vesicles as synthetic vaccines for potent humoral and cellular immune responses

available in PMC 2011 September 1Vaccines based on recombinant proteins avoid the toxicity and antivector immunity associated with live vaccine (for example, viral) vectors, but their immunogenicity is poor, particularly for CD8+ T-cell responses. Synthetic particles carrying antigens and adjuvant molecules have been developed to enhance subunit vaccines, but in general these materials have failed to elicit CD8+ T-cell responses comparable to those for live vectors in preclinical animal models. Here, we describe interbilayer-crosslinked multilamellar vesicles formed by crosslinking headgroups of adjacent lipid bilayers within multilamellar vesicles. Interbilayer-crosslinked vesicles stably entrapped protein antigens in the vesicle core and lipid-based immunostimulatory molecules in the vesicle walls under extracellular conditions, but exhibited rapid release in the presence of endolysosomal lipases. We found that these antigen/adjuvant-carrying vesicles form an extremely potent whole-protein vaccine, eliciting endogenous T-cell and antibody responses comparable to those for the strongest vaccine vectors. These materials should enable a range of subunit vaccines and provide new possibilities for therapeutic protein delivery.Ragon Institute of MGH, MIT and HarvardBill & Melinda Gates FoundationUnited States. Dept. of Defense (contract W911NF-07-D-0004)National Institutes of Health (U.S.) (P41RR002250)National Institutes of Health (U.S.) (RC2GM092599

Water-Gel for Gating Graphene Transistors

Water, the primary electrolyte in biology, attracts significant interest as an electrolyte-type dielectric material for transistors compatible with biological systems. Unfortunately, the fluidic nature and low ionic conductivity of water prevents its practical usage in such applications. Here, we describe the development of a solid state, megahertz-operating, water-based gate dielectric system for operating graphene transistors. The new electrolyte systems were prepared by dissolving metal-substituted DNA polyelectrolytes into water. The addition of these biocompatible polyelectrolytes induced hydrogelation to provide solid-state integrity to the system. They also enhanced the ionic conductivities of the electrolytes, which in turn led to the quick formation of an electric double layer at the graphene/electrolyte interface that is beneficial for modulating currents in graphene transistors at high frequencies. At the optimized conditions, the Na-DNA water-gel-gated flexible transistors and inverters were operated at frequencies above 1 MHz and 100 kHz, respectively. © 2014 American Chemical Society.11Nsciescopu

DNA nanogel encapsulated by a lipid vesicle

DNA has been used as a new generic material due to its selectivity and intrinsic biocompatibility, to construct a variety of nano-architectures such as cubic, tetrahedral, and even complicated origami. Recently, a 3-D hydrogel matrix of DNA has been manufactured at macroscopic scale for biomedical applications as an extra-cellular matrix and a cell-free protein amplification platform. To explore DNA hydrogel in a microscopic level, we report a novel method to produce DNA nanogel enclosed by a lipid vesicle. Nano-sized DNA hydrogels have been simply prepared by mixing precursors with DOPC lipid components under repeated sonications, following by nanometer filtering. After peeling off outer lipids using a lipid-chaotropic reagent (Triton X-100), we observe uniform nanogels entirely composed of DNA. With increasing the amount of DOPC lipids, the size of DNA nanogel has decreased. Our theoretical model based on equilibrium thermodynamics predicts such trend consistent with experiments. It indicates that DOPC lipid molecules energetically interfere with crosslink mechanisms among DNA units. DNA nanogel of well-controlled size may be incorporated with functional multi-modules and further applied to novel and advanced technological tools for in vivo diagnostics or therapeutics in preventive medicines.National Science Foundation (U.S.). Materials Research Science and Engineering Centers (Program) ( Award DMR-02-13282)Bill & Melinda Gates Foundatio

Enzyme-Guided DNA Sewing Architecture

International audienceWith the advent of nanotechnology, a variety of nanoarchitectures with varied physicochemical properties have been designed. Owing to the unique characteristics, DNAs have been used as a functional building block for novel nanoarchitecture. In particular, a self-assembly of long DNA molecules via a piece DNA staple has been utilized to attain such constructs. However, it needs many talented prerequisites (e.g., complicated computer program) with fewer yields of products. In addition, it has many limitations to overcome: for instance, (i) thermal instability under moderate environments and (ii) restraint in size caused by the restricted length of scaffold strands. Alternatively, the enzymatic sewing linkage of short DNA blocks is simply designed into long DNA assemblies but it is more error-prone due to the undeveloped sequence data. Here, we present, for the first time, a comprehensive study for directly combining DNA structures into higher DNA sewing constructs through the 5'-end cohesive ligation of T4 enzyme. Inspired by these achievements, the synthesized DNA nanomaterials were also utilized for effective detection and real-time diagnosis of cancer-specific and cytosolic RNA markers. This generalized protocol for generic DNA sewing is expected to be useful in several DNA nanotechnology as well as any nucleic acid-related fields

Novel functional Renilla luciferase mutant provides long-term serum stability and high luminescence activity

Fluorescent and luminescent chemical probes are essential in recent medical diagnostics. However, the use of these probes in vivo has raised concerns due to their low sensitivity, background signal interference, and non-biocompatibility. Therefore, biological chromophores have received much attention as new alternatives. In particular, luciferase, a class of oxidative enzyme with bioluminescence, has emerged as a promising fluorophore due to its improved biocompatibility. However, the enzyme usually possesses weaker luminescence and stability relative to its chemically-based competitors. Here, we report a novel functional mutant luciferase with both enhanced luminescence and long-term serum stability. For the preparation of the modified Renilla luciferase, a new bacterial subcloning design was established. The luciferase coding DNA sequence was redesigned so that mutant luciferase could be easily expressed in an Escherichia coli system. The mutant Renilla luciferase, which we called "m-RIuc," demonstrated characteristic enzymatic functions and showed a 5.6-fold increase in luminescence activity. In addition, the enzyme's physiological stability remained >80% for more than 5 days, in contrast to conventional luciferase, termed "hrluc," which disappeared within a few hours. We suggest that this novel biological luciferase probe may be a great tool for both in vitro and in vivo medical diagnostics. (C) 2013 Elsevier Inc. All rights reserved.11Nsciescopu

A Gene-Networked Gel Matrix-Supported Lipid Bilayer as a Synthetic Nucleus System

A spheroidal transgene-networked gel matrix was designed as a synthetic nucleus system. It was spheroidically manufactured using both advanced lithography and DNA nanotechnology. Stable Aqueorea coerulescens green fluorescent protein (AcGFP)-encoding gene cross-networks have been optimized in various parameters: the number of gene-networked gel (G-net-gel) spheroids, the concentration of a AcGFP plasmid in the scaffold, and the molar ratio between the X-DNA building blocks and the gene. It was then assessed that 800 units of the gene networked gel matrix at a 4000:1 molar ratio of X-DNA blocks and AcGFP gene components accomplished 20-fold enhanced in vitro protein expression efficiency for 36 h. Furthermore, once with lipid capping, it reproduced the natural nucleus system, demonstrating the 2-fold increased levels of messenger RNAs (mRNAs) relative to solution phase vectors.11Nsciescopu

Novel stem-loop RNA and drug-bearing DNA hybrid nanostructures specific to LNCaP prostate carcinoma

Advances in nanotechnology have resulted in the introduction of new materials for therapeutic and diagnostic purposes. In particular, DNA and RNA are viewed as representative and generic nano-blocks because of their physiochemical characteristics of specificity and nanoscopic-level accuracy. In addition, the intrinsic biocompatibility of DNA and RNA and their immune stimulation effects make these molecules ideal candidates for the rational design of novel bio-drug molecules. Recently, we reported novel RNA-DNA hybrid stem-loop structures that target and are endocytosed by LNCaP prostate cancer cells with high specificity. To effectively ligate the DNA and RNA modules in this research, we thoroughly evaluated and optimized several ligation parameters, and observed that we could enhance the ligation efficacy by changing the overhang sequences. A change in sequence information (GCAT) resulted in a 4-fold increase in ligation efficiency in comparison with other ligation factors. To determine the in vitro cellular targeting ability of the nanostructures, RNA-DNA hybrid constructs were complexed with gold nanorods (AuNRs), and the ability of these nanorods to target prostate cancer cells was highest at a 2:10 molar ratio of LNCaP cancer-specific looped A10 RNA to stem-DNA. Furthermore, doxorubicin (Dox) as a representative anti-prostate cancer therapeutic was loaded into the DNA-RNA hybrid nanostructures. Our results indicate that RNA-DNA hybrid constructs are effective anti-prostate cancer drug delivery platforms and can be employed for both discovery and delivery. © 2014 The Royal Society of Chemistry.11Nsciescopu