Production and Application of Nanobodies for Membrane Protein Structural Biology.

Nanobodies, small recombinant binders derived from camelid single chain antibodies, have become widely used tools in a diversity of disciplines related to membrane proteins. They are applied as chaperones in crystallization and blockers or modifiers of protein activity among numerous other applications. Their simple architecture as a single polypeptide chain, in contrast to classical antibodies, enables straightforward cloning, library generation, and recombinant expression. The small diameter and the pointed wedge-like shape of the antigen-binding site underlies binding to hollows and crevices of membrane proteins and renders nanobodies often conformation specific making them a preferred type of chaperone. Here we describe a simple protocol for the recombinant production of nanobodies in E. coli and their purification. We expand the current repertoire of usage further by describing a procedure for enlarging nanobodies on their C-terminal end to generate "macrobodies," without interfering with their original characteristics. These enlarged nanobodies extend the application as a chaperone in crystallography and can serve to increase the mass for small targets in single particle electron cryo-microscopy, a field where nanobodies had so far only limited effect because of their small size.

Preparation of Proteoliposomes with Purified TMEM16 Protein for Accurate Measures of Lipid Scramblase Activity.

The distribution of different lipid species between the two leaflets is tightly regulated and underlies the concerted action of distinct catalytic entities. While flippases and floppases establish membrane asymmetry, scramblases randomize the lipid distribution and play pivotal roles during blood clotting, apoptosis, and in processes such as N-linked glycosylation of proteins. The recent discovery of TMEM16 family members acting as scramblases has led to an increasing demand for developing protocols tailored for TMEM16 proteins to enable functional investigations of their scrambling activity. Here we describe a protocol for the expression, purification, and functional reconstitution of TMEM16 proteins into preformed liposomes and measurement of their scrambling activity using fluorescence-labeled lipid derivatives. The reconstitution involves extrusion of liposomes through a membrane, destabilization of liposomes using Triton X-100, and stepwise detergent removal by adsorption on styryl-beads. The scrambling assay is based on the selective bleaching of nitrobenzoxadiazol fluorescent lipids on the outer leaflet of liposomes by the membrane-impermeant reducing agent sodium dithionite. The assay allows conclusions on the substrate specificity and on the kinetics of the transported lipids as shown with the example of a Ca2+-activated TMEM16 scramblase from the fungus Nectria haematococca (nhTMEM16).

Structural basis for anion conduction in the calcium-activated chloride channel TMEM16A.

The calcium-activated chloride channel TMEM16A is a member of a conserved protein family that comprises ion channels and lipid scramblases. Although the structure of the scramblase nhTMEM16 has defined the architecture of the family, it was unknown how a channel has adapted to cope with its distinct functional properties. Here we have addressed this question by the structure determination of mouse TMEM16A by cryo-electron microscopy and a complementary functional characterization. The protein shows a similar organization to nhTMEM16, except for changes at the site of catalysis. There, the conformation of transmembrane helices constituting a membrane-spanning furrow that provides a path for lipids in scramblases has changed to form an enclosed aqueous pore that is largely shielded from the membrane. Our study thus reveals the structural basis of anion conduction in a TMEM16 channel and it defines the foundation for the diverse functional behavior in the TMEM16 family.