Approximately 30% of the genes in the human genome code for
membrane proteins, and yet we know relatively little about these molecules.
Less than 1% of structures currently in the protein data bank correspond to
membrane proteins, but this is not because a lack of interest but because
working with these molecules is challenging and difficult. I would even dare to
say that scientists that work with membrane proteins are unique, they are the
bravest and more patient of us all.
Since many membrane proteins sit at the surface of cells,
they are readily available to small molecule drugs circulating in the blood,
thus they are important pharmaceutical
targets. It is therefore not surprising that over 60% of small molecule
drugs bind to membrane proteins.
Membrane proteins are unfortunately
notoriously difficult to handle and study since they are designed to sit within
the hydrophobic environment of the lipid bilayer. Common issues include:
- - Expression
- - Extraction
- - Solubilization
- - Purification
- - Biophysical studies
RELIEVING THE COMPLEXITY OF STUDYING A MEMBRANE COMPLEX
Working with membrane proteins is still based on trials and
errors. From cloning and expression (choosing the right microorganism, what
tags to use, setting conditions for overexpression), solubilization (testing
different detergents) and reconstitution in artificial membranes, but it also
depends on choosing the right tools, which can greatly ease your job, save a
lot of time and money and more importantly that can retrieve valuable and
precise information as in the case of biophysical techniques used to study their
structure and function (molecule binding affinity and specificity, interaction
with other molecules, etc).
In a beautiful study published on 2014
on JBC, Sabine Ebbensperger et al.1 from Goethe University showed
how these problems were overcome in the study of the membrane complex TAP.
THE TAP COMPLEX
When I was a kid I had chickenpox and it was a mess. I was
so unlucky that the virus infected my brain and caused me encephalitis leaving
me with some vision problems. Anyway, at the end it was me who won the battle
and nowadays I still think how fascinating it is to overcome a viral infection.
But how does that happen? Well, the immune system can destroy cells that are
infected with viruses or otherwise damaged, when cytotoxic T-lymphocytes
recognize antigenic peptides presented by MHC class I molecules (MHC I) on the
cell surface. But how on earth does an antigenic peptide, coming from viruses
or damaged cells, end up in the cell surface?
TURNING OFF THE TAP… HOW CLEVER CAN A VIRUS BE
TAP is a heterodimer formed by the subunits TAP1 and
TAP2. Its membrane domains form the peptide-binding site, whereas ATP
hydrolysis occurs at the nucleotide-binding domain (NBD), which energizes
peptide translocation the ER lumen by membrane domains.
But of course, virus are
smart and have evolved proteins that interfere with this pathway!!!!...... and……..
TAP is one viral target that is exploited for example by the herpes simple virus (HSV) ICP47 small protein. ICP47 inhibits peptide
binding to TAP, but does not affect ATP binding. Yet ICP47 does not behave like
a normal peptide as it is not translocated across the membrane and it remains
associated with TAP.
THE CHALLENGE: TO STUDY THE TAP
COMPLEX
PURIFICATION
In this work, TAP was expressed in yeast, with each subunit affinity
tagged (His10 and StrepII) to facilitate purification, and fusioned
to fluorescent protein tags which allow direct visualization of the target
during expression, solubilization and purification and can speed up the
optimization of these processes. Way to go.
During the solubilization stage, membrane proteins are
extracted from the lipid membrane to an aqueous environment by the use of
detergents, which disintegrate the lipid bilayer while incorporating lipids and
proteins in detergent micelles. Then, proteins re ready to be purified.
A great approach of this work and that makes a huge
difference is that the TAP complex was then purified by tandem affinity of its
subunits and detected by Multi Color Fluorescence Size
Exclusion
Chromatography (MC-FSEC), that as FSEC is used to enable tracking of
individual subunits through expression, solubilization and purification steps.
But what makes it better than FSEC though is its ability to detect multiple subunits of membrane protein complexes,
such as TAP1 and TAP2, simultaneously and to analyse their behaviour in
numerous conditions. It allows rapid assessment of the correct assembly and
stoichiometry under the conditions tested and as the authors illustrated, it is
suitable for the study of an hetero-oligomeric membrane protein complex.
RECONSTITUTION OF TAP IN NANODISCS
Reincorporation of purified
membrane proteins into an artificial membrane continue to be crucial in
studying the function and structure of these molecules. The necessity for
reconstitution arises because many membrane proteins express their full
activity only when correctly oriented and inserted in a lipid bilayer.
Nanodiscs
(ND) are self-assembled
discoidal fragments of lipid bilayers 8-16 nm in diameter, stabilized in
solution by two amphipathic helical scaffold proteins.
Now, nanodiscs
provide several key advantages:
1.
Small
size compared to liposomes
2.
Stoichiometry
and composition of membrane protein and lipids can be controlled precisely.
3.
Substrate,
ligand and protein interactions can be studied in close-to-native environment
with access to both sides of the membrane protein complex.
TAP was successfully reconstituted in
nanodiscs, with TAP1 and TAP2 subunits in nanodiscs detected by MC-FSEC. Moreover,
the reconstitution procedure maintained TAP function (peptide binding and ATP
hydrolysis) and gave important information like the annular lipid belt
surrounding the TAP complex in nanodiscs is essential for high affinity
IPCP47-TAP interaction.
PEPTIDE
BINDING ANALYSIS BY MICROSCALE THERMOPHORESIS (MST)
Although biophysical methods
have been successfully applied to an array of soluble protein targets they have
failed in one way or another when applied to membrane proteins.
MST
reports on a direct ligand-protein interaction and it is based on the differential movement of free fluorescent peptides versus and
bound fluorescent peptides in a temperature
gradient, induced by an infrared laser.
Accordingly, the change in
fluorescence was used to reflect the concentration of peptide-TAP complexes.
This technique was used to analyze peptide binding of TAP reconstituted in
nanodiscs. More specifically it retrieved information about:
- - Peptide binding affinity of TAP (Equilibrium dissociation constants KD for nanodiscs-reconstituted TAP as well as detergent-solubilized TAP were obtained).
- - Specificity of peptide-binding.
- - Mode of action of the viral inhibitor ICP47 (using competition microscale thermophoresis it was demonstrated that ICP47 competes with peptides for the TAP binding pocket).
All in all, the combination of nanodiscs, MC-FSEC and MST worked very well in the study of a
membrane complex. It certainly eased the job and showed that good information
can be obtained from a difficult study model, if attention to the available
technologies is paid.
MST holds promises to the study of membrane proteins and
complexes and for the analysis of pharmaceutical-relevant molecules directed
towards them.
1.
Eggensperger S, Fisette O, Parcej D, Schäfer LV, Tampé R. J Biol Chem. 2014 Nov
28;289(48):33098-108.
