‘Lipid Asymmetry’ Plays Key Role in Activating Immune Cells
A cell's membrane is its natural barrier between the inside of a cell and the outside world -- composed of a double layer (bilayer) of lipids (such as fats, waxes, sterols, or fat-soluble vitamins). Intriguingly, it's been known for decades that the layer facing the inside of cells is made of different lipids than the outside-facing layer.
This "lipid asymmetry," or lack of symmetry, is regulated via a variety of proteins and demands a high amount of energy from the cell. Since the cell invests resources toward keeping the lipids asymmetrically distributed equally between the two sides of the bilayer, the process is vital to its function. Dying cells, which permanently lose their lipid asymmetry, are targeted by the immune system for elimination.
Because different lipids create membranes with different physical properties, a group of McGovern Medical School researchers wondered whether different lipid compositions in the bilayer could also lead to different physical properties.
During the 62nd Biophysical Society Annual Meeting, held Feb. 17-21, in San Francisco, California, Joseph H. Lorent, a postdoctoral researcher, and Ilya Levental, an assistant professor, will present their work exploring lipid asymmetry's role in immune cell activation.
A variety of fluorescent probes can provide insights about the general physical properties of membranes. But these probes tend to stain both sides of the plasma membrane -- making it impossible to independently measure the two layers of the bilayer.
"To overcome it, we use a trick where we inject the probe directly inside single cells using a tiny glass syringe like the kind used for extracting nuclei out of cells for cloning," Lorent said. "This allows us to visualize specifically half of the membrane facing the [inside of the cell]."
Now the researchers could see the changes between the inside and outside bilayer. "The differences were obvious and striking," Lorent said. "By preventing the loss of membrane asymmetry, we inhibited the immune response."
The team found that adjusting the lipid asymmetry of the membrane was important to the immune cells functioning. "In the long run, by knowing how lipid asymmetry is involved in cell signaling, we might be able to 'tune' certain immune responses or even cell death through the regulation of lipid asymmetry," Levental said. "This might involve treatments for allergies, inflammation or possibly even cancer."
This article has been republished from materials provided by the Biophysical Society. Note: material may have been edited for length and content. For further information, please contact the cited source.
Structural determinants and functional consequences of protein association with membrane domains. Joseph Lorent, Blanca Barbara Diaz-Rohrer, Xubo Lin, Alex Gorfe, Kandice R. Levental and Ilya Levental. Presentation for Biophysical Society Conference 2018 Abstract:https://plan.core-apps.com/bpsam2018/abstract/598979c882021290aae09439cc3f6e68.
Synthetic Material That Detects Enzymatic ActivityNews
Scientists integrate protein and polymer building blocks to create stimulus-responsive systemsREAD MORE
Regenerative Medicine Meets Clever Engineering to Accommodate Bone GraftsNews
Personalized bone grafts developed to repair bone defects from disease or injuryREAD MORE
Rapid and Cost-Effective Instrument that Measures Molecular DynamicsNews
By combining mass spectrometry and thermal desorption, researchers honed a new method to measure excitation and relaxation rates of uracil, the building block of RNA.READ MORE