The transmembrane surface of a multi-helix membrane protein will be rough with cavities of various sizes between the transmembrane alpha-helices. Efficient solvation of the surface by the lipid molecules that surround the protein in a membrane requires that the lipid fatty acyl chains be able to enter the cavities. This possibility has been investigated using fluorescence quenching methods. Trp residues have been introduced into lipid-facing sites in the first transmembrane alpha-helix (M1) of the mechanosensitive channel of large-conductance MscL; lipid-facing residues at the N-terminal end of M1 are buried below the transmembrane surface of the protein. Fluorescence emission maxima for lipid-facing Trp residues in M1 vary with position in the bilayer comparably to those for Trp residues in the second transmembrane alpha-helix (M2) despite the fact that lipid-facing residues in M2 are on the surface of the protein. Fluorescence emission spectra for most Trp residues on the periplasmic sides of M1 and M2 fit well to a model proposing a trough-like variation of dielectric constant across the membrane, but the relationship between location and fluorescence emission maximum on the cytoplasmic side of the membrane is more complex. The fluorescence of Trp residues in M1 is quenched efficiently by phospholipids with bromine-containing fatty acyl chains, showing that the lipid chains must be able to enter the Trp-containing cavities on the surface of MscL, resulting in efficient solvation of the surface.
This unit describes how fluorescence quenching methods can be used to determine binding constants for phospholipids binding to intrinsic membrane proteins. Reconstitution of a Trp-containing intrinsic membrane protein with bromine-containing phospholipids leads to quenching of the Trp fluorescence of the protein; the extent of quenching depends on the strength of binding of the phospholipid to the protein. Protocols are included for the synthesis of bromine-containing phospholipids from phospholipids containing carbon-carbon double bonds in their fatty acyl chains and for the reconstitution of membrane proteins into bilayers containing bromine-containing phospholipids. Details are included on data analysis, including equations and software that can be used for fitting the fluorescence quenching data.
Interactions between a membrane protein and the lipid molecules that surround it in the membrane are important in determining the structure and function of the protein. These interactions can be pictured at the molecular level using fluorescence spectroscopy, making use of the ability to introduce tryptophan residues into regions of interest in bacterial membrane proteins. Fluorescence quenching methods have been developed to study lipid binding separately on the two sides of the membrane. Lipid binding to the surface of the mechanosensitive channel MscL is heterogeneous, with a hot-spot for binding anionic lipid on the cytoplasmic side, associated with a cluster of three positively charged residues. The environmental sensitivity of tryptophan fluorescence emission has been used to identify the residues at the ends of the hydrophobic core of the second transmembrane α-helix in MscL. The efficiency of hydrophobic matching between MscL and the surrounding lipid bilayer is high. Fluorescence quenching methods can also be used to study binding of lipids to non-annular sites such as those between monomers in the homotetrameric potassium channel KcsA.
Interactions between a membrane protein and the lipid molecules that surround it in the membrane are important in determining the structure and function of the protein. These interactions can be pictured at the molecular level using fluorescence spectroscopy, making use of the ability to introduce tryptophan residues into regions of interest in bacterial membrane proteins. Fluorescence quenching methods have been developed to study lipid binding separately on the two sides of the membrane. Lipid binding to the surface of the mechanosensitive channel MscL is heterogeneous, with a hot-spot for binding anionic lipid on the cytoplasmic side, associated with a cluster of three positively charged residues. The environmental sensitivity of tryptophan fluorescence emission has been used to identify the residues at the ends of the hydrophobic core of the second transmembrane alpha-helix in MscL. The efficiency of hydrophobic matching between MscL and the surrounding lipid bilayer is high. Fluorescence quenching methods can also be used to study binding of lipids to non-annular sites such as those between monomers in the homotetrameric potassium channel KcsA.
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