Spontaneous interaction of purified apolipoproteins and phospholipids results in formation of lipoprotein particles with nanometer-sized dimensions; we refer to these assemblies as nanolipoprotein particles or NLPs. These bilayer constructs can serve as suitable mimetics of biological membranes and are fully soluble in aqueous environments. We made NLPs from dimyristoylphospatidylcholine (DMPC) in combination with each of four different apolipoproteins: apoA-I, Delta-apoA-I fragment, apoE4 fragment, and apolipophorin III (apoLp-III) from the silk moth B. mori. Predominately discoidal in shape, these particles have diameters between 10 and 20 nm, share uniform heights between 4.5 and 5 nm, and can be produced in yields ranging between 40 and 60%. The particular lipoprotein, the lipid to lipoprotein ratio, and the assembly parameters determine the size and homogeneity of nanolipoprotein particles and indicate that apoA-I NLP preparations are smaller than the larger apoE422K and apoLp-III NLP preparations.
Here we demonstrate rapid production of solubilized and functional membrane protein by simultaneous cell-free expression of an apolipoprotein and a membrane protein in the presence of lipids, leading to the self-assembly of membrane protein-containing nanolipoprotein particles (NLPs). NLPs have shown great promise as a biotechnology platform for solubilizing and characterizing membrane proteins. However, current approaches are limited because they require extensive efforts to express, purify, and solubilize the membrane protein prior to insertion into NLPs. By the simple addition of a few constituents to cell-free extracts, we can produce membrane proteins in NLPs with considerably less effort. For this approach an integral membrane protein and an apolipoprotein scaffold are encoded by two DNA plasmids introduced into cellfree extracts along with lipids. For this study reported here we used plasmids encoding the bacteriorhodopsin (bR) membrane apoprotein and scaffold protein ⌬1-49 apolipoprotein A-I fragment (⌬49A1). Cell free co-expression of the proteins encoded by these plasmids, in the presence of the cofactor all-trans-retinal and dimyristoylphosphatidylcholine, resulted in production of functional bR as demonstrated by a 5-nm shift in the absorption spectra upon light adaptation and characteristic time-resolved FT infrared difference spectra for the bR 3 M transition. Importantly the functional bR was solubilized in discoidal bR⅐NLPs as determined by atomic force microscopy. A survey study of other membrane proteins co-expressed with ⌬49A1 scaffold protein also showed significantly increased solubility of all of the membrane proteins, indicating that this approach may provide a general method for expressing membrane proteins enabling further studies.
We report a cell-free approach for expressing and inserting integral membrane proteins into water-soluble particles composed of discoidal apolipoprotein-lipid bilayers. Proteins are inserted into the particles, circumventing the need of extracting and reconstituting the product into membrane vesicles. Moreover, the planar nature of the membrane support makes the protein freely accessible from both sides of the lipid bilayer. Complexes are successfully purified by means of the apoplipoprotein component or by the carrier protein. The method significantly enhances the solubility of a variety of membrane proteins with different functional roles and topologies. Analytical assays for a subset of model membrane proteins indicate that proteins are correctly folded and active. The approach provides a platform amenable to high-throughput structural and functional characterization of a variety of traditionally intractable drug targets.
Self-assembly of purified apolipoproteins and phospholipids results in the formation of nanometer-sized lipoprotein complexes, referred to as nanolipoprotein particles (NLPs). These bilayer constructs are fully soluble in aqueous environments and hold great promise as a model system to aid in solubilizing membrane proteins. Size variability in the self-assembly process has been recognized for some time, yet limited studies have been conducted to examine this phenomenon. Understanding the source of this heterogeneity may lead to methods to mitigate heterogeneity or to control NLP size, which may be important for tailoring NLPs for specific membrane proteins. Here, we have used atomic force microscopy, ion mobility spectrometry, and transmission electron microscopy to quantify NLP size distributions on the single-particle scale, specifically focusing on assemblies with 1,2-dimyristoyl-sn-glycero-3-phosphocholine (DMPC) and a recombinant apolipoprotein E variant containing the N-terminal 22 kDa fragment (E422k). Four discrete sizes of E422k/DMPC NLPs were identified by all three techniques, with diameters centered at ?14.5, 19, 23.5, and 28 nm. Computer simulations suggest that these sizes are related to the structure and number of E422k lipoproteins surrounding the NLPs and particles with an odd number of lipoproteins are consistent with the double-belt model, in which at least one lipoprotein adopts a hairpin
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