Revealing the structure of somatic cell membranes by in situ cryo-electron tomography

Abstract

AbstractThe cell membrane, which separates the cell from the environment, plays a key role in signal transduction, energy conversion and substance transport. Although previous membrane models have successfully interpreted some functions of the cell membrane, no consensus has been reached for the lack of direct and in situ evidence. Here, we characterized the high-resolution 3D structure of 293T cell membranes in situ for the first time by cryo-electron tomography. Due to the excellent thickness of our cryo-samples, we could clearly observe membrane proteins with an average molecular weight of 100 kD. By analysing tomograms, we found that the total thickness of a 293T plasma membrane is approximately 20 nm and that there is a 4-nm lipid bilayer structure within the membrane. We observed that membrane proteins and protein complexes with a similar height (7-11 nm) are densely embedded in the ectoplasmic side of 293T plasma membranes, whereas membrane proteins aggregate to form islands with heights reaching dozens of nanometres on the cytoplasmic side. Additionally, we measured the average sizes of membrane proteins on the cytoplasmic side of 293T plasma membranes and found them to be approximately 7 nm in length and 4 nm in width. Moreover, if more precise structural information is obtained in future studies, we will identify the molecular interactions and detailed structures of membrane protein clusters that can be easily distinguished on a 293T cell membrane. Our work represents the first in situ structural characterization of a native somatic cell membrane with cryo-electron tomography and advances cell membrane structural studies from the model prediction stage to the real structure observation stage.