November 2008 Molecule of the Month by David Goodsell  |  Previous Features
doi: 10.2210/rcsb_pdb/mom_2008_11

Mechanosensitive Channels

We are remarkably resistant to changes in our surrounding environment. Our bulky bodies allow us to weather extremes of heat and cold, and our skin protects us if we go for a swim in fresh water or salty water. If things get too uncomfortable, we can always get up and walk away, finding a warmer or cooler or drier place. Bacteria don't have as many options. They are tiny and they are immersed in water, so changes in the environment can pose life-threatening challenges. For instance, if it rains they may be suddenly surrounded by fresh water. This is dangerous because the water seeps into the cell through osmosis and increases the pressure inside. At other times, the bacterium may be shifted suddenly to salty conditions, which pulls water out and dehydrates the cell. Bacteria have methods for resisting these changes, so they can keep a steady, comfortable osmotic pressure inside.

Under Pressure

Bacteria control their internal pressure by changing the concentration of molecules inside. If they are placed in salty conditions, they resist dehydration by transporting ions into the cell and by synthesizing more small molecules. However, if they are placed in pure water, they must reduce their inner concentration of ions and small molecules. In that case, they use mechanosensitive channels that open and allow small molecules to leak out. For instance, in laboratory tests, cells that are placed in fresh water rapidly lose more than 95% of small molecules like amino acids, sugars, and potassium ions. However, they keep their proteins or ribosomes safely inside, so they recover quickly and can start up protein synthesis minutes after the conditions return to normal.

Pressure Valve

Mechanosensitive channels respond to pressure inside the cell, opening when it gets to dangerous levels. They sense this pressure by sensing changes in the properties of the membrane. When the membrane is stretched by high internal pressures, it triggers the conformational change that opens the channel. The cell has several different channels that open at different levels of pressure. The MscS channel shown here (PDB entry 2oau) opens at low and moderate pressures, and the one on the following page opens at higher pressures.

Small Channel

MscS, the mechanosensitive channel of small conductance, is composed of seven identical chains arranged to form a tube. A portion of it crosses the membrane and forms a pressure-sensitive pore about 13 Angstroms in diameter. This is just big enough to pass small molecules and ions. The cytoplasmic portion (shown at the bottom here) forms a cap over the pore, creating an antechamber that limits the size of molecules that can reach the pore when it opens.