Using nanodot technology, Lawrence Berkeley National Laboratory (Berkeley Lab) researchers have demonstrated the first size-based form of chromatography that can be used to study the membranes of living cells. This unique physical approach to probing cellular membrane structures can reveal information critical to whether a cell lives or dies, remains normal or turns cancerous, that can’t be obtained through conventional microscopy.
“We’ve developed membrane-embedded nanodot array platforms that provide a physical means to both probe and manipulate membrane assemblies, including signaling clusters, while they are functioning in the membrane of a living cell,” says Jay Groves, a chemist with Berkeley Lab’s Physical Biosciences Div., who led this research.
Groves, who is also a prof. with the Univ. of California Berkeley’s Chemistry Dept., and a Howard Hughes Medical Institute (HHMI) investigator, is a recognized leader in developing techniques for studying the impact of spatial patterns on living cells. The live-cell supported synthetic membranes he and his group have been developing are constructed out of lipids and assembled onto a substrate of solid silica. These membranes are being used to determine how living cells not only interact with their environment through chemical signals but also through physical force and spatial patterns.
“We call our approach the spatial mutation strategy because molecules in a cell can be spatially re-arranged without altering the cell in any other way,” Groves says. “Our live cell-supported membranes provide a hybrid interface consisting of mobile and immobile components with controlled geometry that allows us to utilize solid-state nanotechnology to manipulate and control molecular systems inside living cells.”
While the work of Groves and others in recent years has demonstrated the importance of protein and lipid spatial organization within cellular membranes, details as to how spatial organization is tied to function are scarce primarily because of the limitations of optical microscopy at length scales below the 250-nm diffraction limit. The size-based chromatography technique developed by Groves and his group allows them to probe supramolecular structures in a cell membrane at the needed nanometer length-scales.
“We now have a way to translate nanosized structures that approach molecular dimensions into geometric constraints on the movement of molecules inside a living cell,” Groves says.
For their size-based chromatography technique, the spacing of proteins and other cellular molecules is controlled by a hexagonal or honeycomb array of gold nanoparticles that is fabricated into the membrane. The spacing between nanoparticles in each array can be controlled, with accessible sizes ranging from 30 to nearly 200 nm.
“Individual membrane components move freely throughout the array, but movement of larger assemblies is impeded if they exceed the physical dimensions of the array,” Groves says.
Groves and his colleagues tested their size-based chromatography technique on T-cell receptor (TCR) microclusters in T-cell membranes, which is the functional module for antigen recognition by T-cells (lymphocytes from the thymus) in the body’s immune system. These TCR signaling clusters occupy a size regime ranging from tens to a few hundred nanometers, which is typically below the diffraction limit of conventional optical microscopy. Size-based chromatography was used to probe the physical properties of TCR signaling clusters as a function of antigen density. The results revealed that TCR signaling cluster is distinctly dependent on the amount of antigen encountered by the cell.
“This is something we did not know before about the TCR microcluster signaling system, which has been well-studied using conventional optical microscopy,” Groves says. “It is a proof-of-principle demonstration that represents another step in the direction of interfacing living cells with synthetic materials to achieve molecular level control of the cell.”
A paper on this research has been published in NANO Letters.
