Detergent-Free Membrane Protein Purification Using SMA Polymer.

One of the big challenges for the study of structure and function of membrane proteins is the need to extract them from the membrane. Traditionally this was achieved using detergents which disrupt the membrane and form a micelle around the protein, but this can cause issues with protein function and/or stability. In 2009 an alternative approach was reported, using styrene maleic acid (SMA) copolymer to extract small discs of lipid bilayer encapsulated by the polymer and termed SMALPs (SMA lipid particles). Since then this approach has been shown to work for a range of different proteins from many different expression systems. It allows the extraction and purification of a target protein while maintaining a lipid bilayer environment. Recently this has led to several new high-resolution structures and novel insights to function. As with any method there are some limitations and issues to be aware of. Here we describe a standard protocol for preparation of the polymer and its use for membrane protein purification, and also include details of typical challenges that may be encountered and possible ways to address those.

Expression of eukaryotic membrane proteins in eukaryotic and prokaryotic hosts.

The production of membrane proteins of high purity and in satisfactory yields is crucial for biomedical research. Due to their involvement in various cellular processes, membrane proteins have increasingly become some of the most important drug targets in modern times. Therefore, their structural and functional characterization is a high priority. However, protein expression has always been more challenging for membrane proteins than for soluble proteins. In this review, we present four of the most commonly-used expression systems for eukaryotic membrane proteins. We describe the benefits and drawbacks of bacterial, yeast, insect and mammalian cells. In addition, we describe the different features (growth rate, yield, post-translational modifications) of each expression system, and how they are influenced by the construct design and modifications of the target gene. Cost-effective and fast-growing E. coli is mostly selected for the production of small, simple membrane proteins that, if possible, do not require post-translational modifications but has the potential for the production of bigger proteins as well. Yeast hosts are advantageous for larger and more complex proteins but for the most complex ones, insect or mammalian cells are used as they are the only hosts able to perform all the post-translational modifications found in human cells. A combination of rational construct design and host cell choice can dramatically improve membrane protein production processes.