Screening of Membrane Protein Production by Comparison of Transient Expression in Insect and Mammalian Cells.

Membrane proteins are difficult biomolecules to express and purify. In this paper, we compare the small-scale production of six selected eukaryotic integral membrane proteins in insect and mammalian cell expression systems using different techniques for gene delivery. The target proteins were C terminally fused to the green fluorescent marker protein GFP to enable sensitive monitoring. We show that the choice of expression systems makes a considerable difference to the yield and quality of the six selected membrane proteins. Virus-free transient gene expression (TGE) in insect High Five cells combined with solubilization in dodecylmaltoside plus cholesteryl hemisuccinate generated the most homogeneous samples for all six targets. Further, the affinity purification of the solubilized proteins using the Twin-Strep® tag improved protein quality in terms of yield and homogeneity compared to His-tag purification. TGE in High Five insect cells offers a fast and economically attractive alternative to the established methods that require either baculovirus construction and the infection of the insect cells or relatively expensive transient gene expression in mammalian cells for the production of integral membrane proteins.

Transient Transfection and Expression of Eukaryotic Membrane Proteins in Expi293F Cells and Their Screening on a Small Scale: Application for Structural Studies.

Cancers, neurodegenerative and infectious diseases remain some of the leading causes of deaths worldwide. The structure-guided drug design is essential to advance drug development for these important diseases. One of the key challenges in the structure determination workflow is the production of eukaryotic membrane proteins (drug targets) of high quality. A number of expression systems have been developed for the production of eukaryotic membrane proteins. In this chapter, an optimized detailed protocol for transient transfection and expression of eukaryotic membrane proteins in Expi293F cells is presented. Testing expression and purification on a small scale allow optimizing conditions for sample preparation for downstream structural (cryo-EM) elucidation.

LptC from Anabaena sp. PCC 7120: Expression, purification and crystallization.

Lipopolysaccharides are central elements of the outer leaflet of the outer membrane of Gram-negative bacteria and as such, of cyanobacteria. In the past, the structural analysis of the system in proteobacteria like Escherichia coli has contributed to a deep understanding of the transport of lipopolysaccharides from plasma membrane to the outer membrane. While many components of the transport system are conserved between proteobacteria and cyanobacteria, the periplasmic LptC appears to be distinct. The cyanobacterial proteins are twice as long as the proteobacterial proteins or proteins from firmicutes. This prompted the question whether the structure of the cyanobacterial proteins is comparable the one of the proteobacterial proteins. To address this question, we expressed LptC from Anabaena sp. PCC 7120 in E. coli as truncated protein without the transmembrane segment. We purified the protein utilizing HIS-tag based affinity chromatography and polished the protein after removal of the tag by size exclusion chromatography. The purified recombinant protein was crystallized by the sitting-drop vapor diffusion technique and best crystals, despite being twinned, diffracted to a resolution of 2.6 Å.

Purification and Reconstitution of Ilyobacter tartaricus ATP Synthase.

F-type adenosine triphosphate (ATP) synthase is a membrane-bound macromolecular complex, which is responsible for the synthesis of ATP, the universal energy source in living cells. This enzyme uses the proton- or sodium-motive force to power ATP synthesis by a unique rotary mechanism and can also operate in reverse, ATP hydrolysis, to generate ion gradients across membranes. The F1Fo-ATP synthases from bacteria consist of eight different structural subunits, forming a complex of ∼550 kDa in size. In the bacterium Ilyobacter tartaricus the ATP synthase has the stoichiometry α3ß3γδεab2c11. This chapter describes a wet-lab working protocol for the purification of several tens of milligrams of pure, heterologously (E. coli-)produced I. tartaricus Na+-driven F1Fo-ATP synthase and its subsequent efficient reconstitution into proteoliposomes. The methods are useful for a broad range of subsequent biochemical and biotechnological applications.

Engineering rotor ring stoichiometries in the ATP synthase.

ATP synthase membrane rotors consist of a ring of c-subunits whose stoichiometry is constant for a given species but variable across different ones. We investigated the importance of c/c-subunit contacts by site-directed mutagenesis of a conserved stretch of glycines (GxGxGxGxG) in a bacterial c(11) ring. Structural and biochemical studies show a direct, specific influence on the c-subunit stoichiometry, revealing c(<11), c(12), c(13), c(14), and c(>14) rings. Molecular dynamics simulations rationalize this effect in terms of the energetics and geometry of the c-subunit interfaces. Quantitative data from a spectroscopic interaction study demonstrate that the complex assembly is independent of the c-ring size. Real-time ATP synthesis experiments in proteoliposomes show the mutant enzyme, harboring the larger c(12) instead of c(11), is functional at lower ion motive force. The high degree of compliance in the architecture of the ATP synthase rotor offers a rationale for the natural diversity of c-ring stoichiometries, which likely reflect adaptations to specific bioenergetic demands. These results provide the basis for bioengineering ATP synthases with customized ion-to-ATP ratios, by sequence modifications.