Detergents enable the purification of membrane proteins and are indispensable reagents in structural biology. Even though a large variety of detergents have been developed in the last century, the challenge remains to identify guidelines that allow fine-tuning of detergents for individual applications in membrane protein research. Addressing this challenge, here we introduce the family of oligoglycerol detergents (OGDs). Native mass spectrometry (MS) reveals that the modular OGD architecture offers the ability to control protein purification and to preserve interactions with native membrane lipids during purification. In addition to a broad range of bacterial membrane proteins, OGDs also enable the purification and analysis of a functional G-protein coupled receptor (GPCR). Moreover, given the modular design of these detergents, we anticipate fine-tuning of their properties for specific applications in structural biology. Seen from a broader perspective, this represents a significant advance for the investigation of membrane proteins and their interactions with lipids.
Dendritic molecules are an exciting research topic because of their highly branched architecture, multiple functional groups on the periphery, and very pertinent features for various applications. Self-assembling dendritic amphiphiles have produced different nanostructures with unique morphologies and properties. Since their self-assembly in water is greatly relevant for biomedical applications, researchers have been looking for a way to rationally design dendritic amphiphiles for the last few decades. We review here some recent developments from investigations on the self-assembly of dendritic amphiphiles into various nanostructures in water on the molecular level. The main content of the review is divided into sections according to the different nanostructure morphologies resulting from the dendritic amphiphiles' self-assembly. Finally, we conclude with some remarks that highlight the self-assembling features of these dendritic amphiphiles.
The use of mass spectrometry
to investigate proteins is now well
established and provides invaluable information for both soluble and
membrane protein assemblies. Maintaining transient noncovalent interactions
under physiological conditions, however, remains challenging. Here,
using nanoscale electrospray ionization emitters, we establish conditions
that enable mass spectrometry of two G protein-coupled receptors (GPCR)
from buffers containing high concentrations of sodium ions. For the
Class A GPCR, the adenosine 2A receptor, we observe ligand-induced
changes to sodium binding of the receptor at the level of individual
sodium ions. We find that antagonists promote sodium binding while
agonists attenuate sodium binding. These findings are in line with
high-resolution X-ray crystallography wherein only inactive conformations
retain sodium ions in allosteric binding pockets. For the glucagon
receptor (a Class B GPCR) we observed enhanced ligand binding in electrospray
buffers containing high concentrations of sodium, as opposed to ammonium
acetate buffers. A combination of native and -omics mass spectrometry
revealed the presence of a lipophilic negative allosteric modulator.
These experiments highlight the advantages of implementing native
mass spectrometry, from electrospray buffers containing high concentrations
of physiologically relevant salts, to inform on allosteric ions or
ligands with the potential to define their roles on GPCR function.
The synthesis, supramolecular complexation, and switching of new bifunctional azobenzene-oligoglycerol conjugates in different environments is reported. Through the formation of host-guest complexes with surface immobilized β-cyclodextrin receptors, the bifunctional switches were coupled to gold surfaces. The isomerization of the amphiphilic azobenzene derivatives was examined in solution, on gold nanoparticles, and on planar gold surfaces. The wettability of functionalized gold surfaces can be reversibly switched under light-illumination with two different wavelengths. Besides the photoisomerization processes and concomitant effects on functionality, the thermal cis to trans isomerization of the conjugates and their complexes was monitored. Thermal half-lives of the cis isomers were calculated for different environments. Surprisingly, the half-lives on gold nanoparticles were significantly smaller compared to planar gold surfaces.
Ion mobility-mass spectrometry was used to obtain detailed information about the kinetics of the light-induced cis/trans isomerization process of a new supramolecular azobenzene-based bolaamphiphile. Further experiments revealed that the investigated light-induced structural transition dramatically influences the aggregation behaviour of the molecule.
Here, L. H. Urner and co-workers identify a new detergent design strategy for the non-denaturing structural analysis of membrane proteins by studying the gas-phase properties of azobenzene-based oligoglycerol detergents.
Combinatorial detergent synthesis permits access to an unexplored part of the detergentome and provides new directions for the preparation of custom-made detergents for future applications.
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