Comparison of the type of liposome involving cytokine production induced by non-CpG Lipoplex in macrophages

Building Blocks to Design Liposomal Delivery Systems

The flexibility of liposomal carriers does not just simply rely on their capability to encapsulate various types of therapeutic substances, but also on the large array of components used for designing liposome-based nanoformulations. Each of their components plays a very specific role in the formulation and can be easily replaced whenever a different therapeutic effect is desired. It is tempting to describe this by an analogy to Lego blocks, since a whole set of structures, differing in their features, can be designed using a certain pool of blocks. In this review, we focus on different design strategies, where a broad variety of liposomal components facilitates the attainment of straightforward control over targeting and drug release, which leads to the design of the most promising systems for drug delivery. The key aspects of this block-based architecture became evident after its implementation in our recent works on liposomal carriers of antisense oligonucleotides and statins, which are described in the last chapter of this review.

Engineering the drug carrier biointerface to overcome biological barriers to drug delivery

Micro and nanoscale drug carriers must navigate through a plethora of dynamic biological systems prior to reaching their tissue or disease targets. The biological obstacles to drug delivery come in many forms and include tissue barriers, mucus and bacterial biofilm hydrogels, the immune system, and cellular uptake and intracellular trafficking. The biointerface of drug carriers influences how these carriers navigate and overcome biological barriers for successful drug delivery. In this review, we examine how key material design parameters lead to dynamic biointerfaces and improved drug delivery across biological barriers. We provide a brief overview of approaches used to engineer key physicochemical properties of drug carriers, such as morphology, surface chemistry, and topography, as well as the development of dynamic responsive materials for barrier navigation. We then discuss essential biological barriers and how biointerface engineering can enable drug carriers to better navigate and overcome these barriers to drug delivery.

Cationic lipid/pDNA complex formation as potential generic method to generate specific IRF pathway stimulators

Cationic liposome - CpG DNA complexes (lipoplexes) are known as stimulators of innate immunity via Toll-like receptor 9 (TLR9)-triggered activation of the nuclear factor kappa B (NF-κB) pathway. More recent reports suggest that DNA lipoplexes also engage DNA sensors in the cytosol leading to the stimulation of the interferon response factor (IRF) pathway. In this study a range of lipoplexes were formulated by using an invariable helper lipid, three different cationic lipids (DOTAP, DOTMA and DDA) and three different CpG-containing plasmids of different sizes. These lipoplexes exhibited similar hydrodynamic diameters, zeta-potentials and plasmid loading rates, despite the different lipid blends and CpG-containing plasmids. Binding and uptake of liposomal lipids by J774.A1 macrophages and JAWSII dendritic cells increased significantly (up to 4-fold) upon lipoplex formation. Cellular plasmid DNA uptake via lipoplexes compared to naked DNA was increased up to 18-fold. Analysis of signal transduction pathway activation in J774-DUAL™ reporter cells by liposomes or naked CpG plasmid DNA compared to their derived lipoplexes showed only minor activation of the NF-κB pathway, while the IRF pathway displayed massive activation factors of up to 46-fold. DOTAP- and DOTMA lipoplexes also led to massive interferon-alpha and -beta secretion of J774A.1 macrophages and JAWSII dendritic cells, which is a hallmark of IRF pathway activation. Cellular distribution studies on DOTAP lipoplexes suggest delivery of plasmid DNA via vesicular compartments into the cytosol. Taken together, the CpG plasmid DNA lipoplexes generated in this study appear to selectively stimulate DNA receptors activating the IRF pathway, while bypassing TLR9 and NF-κB activation.

Immunological and Toxicological Considerations for the Design of Liposomes

Liposomes hold great potential as gene and drug delivery vehicles due to their biocompatibility and modular properties, coupled with the major advantage of attenuating the risk of systemic toxicity from the encapsulated therapeutic agent. Decades of research have been dedicated to studying and optimizing liposomal formulations for a variety of medical applications, ranging from cancer therapeutics to analgesics. Some effort has also been made to elucidate the toxicities and immune responses that these drug formulations may elicit. Notably, intravenously injected liposomes can interact with plasma proteins, leading to opsonization, thereby altering the healthy cells they come into contact with during circulation and removal. Additionally, due to the pharmacokinetics of liposomes in circulation, drugs can end up sequestered in organs of the mononuclear phagocyte system, affecting liver and spleen function. Importantly, liposomal agents can also stimulate or suppress the immune system depending on their physiochemical properties, such as size, lipid composition, pegylation, and surface charge. Despite the surge in the clinical use of liposomal agents since 1995, there are still several drawbacks that limit their range of applications. This review presents a focused analysis of these limitations, with an emphasis on toxicity to healthy tissues and unfavorable immune responses, to shed light on key considerations that should be factored into the design and clinical use of liposomal formulations.

Toll-like receptor 2 promiscuity is responsible for the immunostimulatory activity of nucleic acid nanocarriers

Lipopolyamines (LPAs) are cationic lipids; they interact spontaneously with nucleic acids to form lipoplexes used for gene delivery. The main hurdle to using lipoplexes in gene therapy lies in their immunostimulatory properties, so far attributed to the nucleic acid cargo, while cationic lipids were considered as inert to the immune system. Here we demonstrate for the first time that di-C18 LPAs trigger pro-inflammatory responses through Toll-like receptor 2 (TLR2) activation, and this whether they are bound to nucleic acids or not. Molecular docking experiments suggest potential TLR2 binding modes reminiscent of bacterial lipopeptide sensing. The di-C18 LPAs share the ability of burying their lipid chains in the hydrophobic cavity of TLR2 and, in some cases, TLR1, at the vicinity of the dimerization interface; the cationic headgroups form multiple hydrogen bonds, thus crosslinking TLRs into functional complexes. Unravelling the molecular basis of TLR1 and TLR6-driven heterodimerization upon LPA binding underlines the highly collaborative and promiscuous ligand binding mechanism. The prevalence of non-specific main chain-mediated interactions demonstrates that potentially any saturated LPA currently used or proposed as transfection agent is likely to activate TLR2 during transfection. Hence our study emphasizes the urgent need to test the inflammatory properties of transfection agents and proposes the use of docking analysis as a preliminary screening tool for the synthesis of new non-immunostimulatory nanocarriers.

Transfection of mammalian cells using block copolypeptide vesicles

An arginine-leucine block copolypeptide (R60 L20 ) is synthesized, which is capable of forming vesicles with controllable sizes, able to transport hydrophilic cargo across the cell membrane, and exhibit relatively low cytotoxicity. The R60 L20 vesicles also possess the ability to deliver DNA into mammalian cells for transfection. Although the transfection efficiency is lower than that of the commercially available transfection agent Lipofectamine 2000, the R60 L20 vesicles are able to achieve transfection with significantly lower cytotoxicity and immunogenicity. This behavior is potentially due to its stronger interaction with DNA which subsequently provides better protection against anionic heparin.

Cationic liposome-DNA complexes (CLDC) adjuvant enhances the immunogenicity and cross-protective efficacy of a pre-pandemic influenza A H5N1 vaccine in mice

The development of pre-pandemic influenza A H5N1 vaccines that confer both antigen-sparing and cross-clade protection are a high priority given the limited worldwide capacity for influenza vaccine production, and the antigenic and genetic heterogeneity of circulating H5N1 viruses. The inclusion of potent adjuvants in vaccine formulations may achieve both of these aims. Here we show that the addition of JVRS-100, an adjuvant consisting of cationic liposome-DNA complexes (CLDC) to a clade 1-derived H5N1 split vaccine induced significantly higher virus-specific antibody than unadjuvanted formulations, with a >30-fold dose-sparing effect and induction of increased antigen-specific CD4(+) T-cell responses in mice. All mice that received one dose of adjuvanted vaccine and subsequent H5N1 viral challenges exhibited mild illness, lower lung viral titers, undetectable spleen and brain viral titers, and 100% survival after either homologous clade 1 or heterologous clade 2 H5N1 viral challenges, whereas unadjuvanted vaccine recipients showed significantly increased weight loss, viral titers, and mortality. The protective immunity induced by JVRS-100 adjuvanted H5N1 vaccine was shown to last for over one year without significant waning. Thus, JVRS-100 adjuvanted H5N1 vaccine elicited enhanced humoral and T-cell responses, dose-sparing, and cross-clade protection in mice. CLDC holds promise as an adjuvant for human pre-pandemic inactivated H5N1 vaccines.

Inhibition of nuclear delivery of plasmid DNA and transcription by interferon γ: hurdles to be overcome for sustained gene therapy

Sustained expression of murine interferon (IFN)-γ (Muγ) was found to be effective in preventing tumor metastasis and atopic dermatitis in mouse models. However, our preliminary experiments suggested that the time-dependent decrease in the Muγ expression was not compensated for by repeated injections of Muγ-expressing plasmid. To identify the mechanism underlying this observation, a reporter plasmid was hydrodynamically injected into mice and the levels of the plasmid, mRNA and reporter protein were measured in mice receiving a pre- or co-administration of Muγ-expressing plasmid. Co-injection of Muγ-expressing plasmid had no significant effects on transgene expression from the reporter plasmid. In contrast, pre-injection of Muγ-expressing plasmid greatly inhibited the expression of the reporter protein. Moreover, pre-injection of Muγ-expressing plasmid also reduced the amount of the reporter plasmid in the nuclear fraction of mouse liver to < 10%, and that of reporter mRNA to < 1%. The degree of reduction in the expression of reporter protein was comparable with the reduction in mRNA. These results indicate that the difficulty in regaining the expression level of IFN-γ is due to the impaired delivery of plasmid to the nucleus and to the suppression of transcription from the plasmid.

A DNA microarray-based analysis of the host response to a nonviral gene carrier: a strategy for improving the immune response

The purpose of this study was to investigate the host response to systemically administered lipid nanoparticles (NPs) encapsulating plasmid DNA (pDNA) in the spleen using a DNA microarray. As a model for NPs, we used a multifunctional envelope-type nano device (MEND). Microarray analysis revealed that 1,581 of the differentially expressed genes could be identified by polyethylene glycol (PEG)-unmodified NP using a threefold change relative to the control. As the result of PEGylation, the NP treatment resulted in the reduction in the expression of most of the genes. However, the expression of type I interferon (IFN) was specifically increased by PEGylation. Based on the microarray and a pathway analysis, we hypothesize that PEGylation inhibited the endosomal escape of NP, and extended the interaction of toll-like receptor-9 (TLR9) with CpG-DNA accompanied by the production of type I IFN. This hypothesis was tested by introducing a pH-sensitive fusogenic peptide, GALA, which enhances the endosomal escape of PEGylated NP. As expected, type I IFN was reduced and interleukin-6 (IL-6) remained at the baseline. These findings indicate that a carrier design based on microarray analysis and the manipulation of intracellular trafficking constitutes a rational strategy for reducing the host immune response to NPs.