Enhanced plasmid DNA delivery using anionic LPDII by listeriolysin O incorporation

BACKGROUND: A major obstacle to achieving effective DNA-based therapeutics is efficient delivery of the DNA to its site of action in the cell. Upon internalization by endocytosis, the endosomal membrane represents a critical physical barrier preventing access of DNA to the cell cytosol. In order to overcome the membrane barrier and facilitate cytosolic entry, the endosomolytic bacterial protein listeriolysin O (LLO) is a potentially promising agent. METHODS: LLO was incorporated in an anionic liposome-entrapped polycation-condensed DNA delivery system (LPDII). Plasmid DNA was condensed using protamine sulfate and then complexed to anionic liposomes. LLO was incorporated into the delivery vehicle through encapsulation in anionic, pH-sensitive liposomes. Transfection levels were monitored using a model reporter plasmid encoding luciferase in P388D1 cells, a macrophage-like cell line. RESULTS: Transfection using the anionic LPDII delivery platform was enhanced through incorporation of LLO. Additionally, the net charge of the condensate, the lipid composition, and the total amount of LLO-liposomes were all capable of modulating the transfection levels of the vehicle. Importantly, in the presence of serum, transfection levels using the LLO-containing LPDII system were comparable to established cationic lipid delivery systems. CONCLUSIONS: LLO is capable of facilitating transfection using an anionic LPDII system. This anionic delivery vehicle represents the successful combination of the LPDII system for condensation of the DNA with the unique endosomolytic properties of LLO for improved transfection using plasmid DNA.     

Responses of hybrid striped bass to waterborne and dietary copper in freshwater and saltwater

Mechanisms of copper toxicity and consequences of exposure vary due to uptake route and ionoregulatory status. The goal of this research was to develop a model fish system to assess the influence of different Cu exposure routes (waterborne or dietary) on bioavailability, uptake, and effects in hybrid striped bass (Morone chrysops x Morone saxatilis) acclimated to fresh- or saltwater. Initially, hybrid striped bass were exposed to dietary Cu concentrations of 571, 785, and 1013 mug Cu/g, along with a control (approximately 5 microg Cu/g), for 14 days in saltwater. Intestinal and liver Cu accumulated in a dose-dependent manner in fish exposed to increasing levels of dietary Cu. Chronic (42 days) experiments were then conducted to determine sub-lethal effects of aqueous, dietary, and combined aqueous and dietary Cu exposures to both freshwater- and saltwater-acclimated hybrid striped bass. Growth and Cu accumulation in the gill, intestine, and liver were measured. Although no significant effects were observed in fish exposed to waterborne Cu, those exposed through the diet accumulated significant liver and intestinal Cu but showed no significant change in growth. Overall, these results suggest that at the levels tested, exposure to elevated waterborne Cu did not cause significant long-term tissue Cu accumulation, whereas dietary Cu exposure caused significant liver and intestinal Cu accumulation in hybrid striped bass which was comparable in both freshwater and saltwater (15 g/L).     

Modeling a sialic acid binding pocket in the external loops of JC virus VP1

JC virus (JCV) is a common human polyomavirus that infects over 70% of the population worldwide. JCV has a restricted cell tropism that is caused partly by the initial interaction between the virus and sialic acid-containing host cell receptors. To identify the molecular interactions between the virus and its cellular receptor, we used a combined approach of site-directed mutagenesis and homology-based molecular modeling. A model of the major viral capsid protein VP1 based on sequence alignment with other closely related polyomaviruses allowed us to target specific amino acids in the extracellular loops of VP1 for mutagenesis. An analysis of the growth rates of 17 point mutants led to the identification of VP1 amino acids that are critical in virus-host cell receptor interactions. Molecular dynamics simulations were then used to build and confirm a model of the interaction between VP1 and the sialic acid component of the JCV receptor.     

The organization of engaged and quiescent translocons in the endoplasmic reticulum of mammalian cells

Protein translocons of the mammalian endoplasmic reticulum are composed of numerous functional components whose organization during different stages of the transport cycle in vivo remains poorly understood. We have developed generally applicable methods based on fluorescence resonance energy transfer (FRET) to probe the relative proximities of endogenously expressed translocon components in cells. Examination of substrate-engaged translocons revealed oligomeric assemblies of the Sec61 complex that were associated to varying degrees with other essential components including the signal recognition particle receptor TRAM and the TRAP complex. Remarkably, these components not only remained assembled but also had a similar, yet distinguishable, organization both during and after nascent chain translocation. The persistence of preassembled and complete translocons between successive rounds of transport may facilitate highly efficient translocation in vivo despite temporal constraints imposed by ongoing translation and a crowded cellular environment.