The Role of Crystallins in Maintaining Lens Transparency

Crystallins are adapted not to crystallise; the eye lens needs to be a highly concentrated solution, but it needs to avoid small crystals or aggregates, since they would scatter light and make the lens opaque. Our lenses achieve this by mixing together several different crystallins, which together form a uniform, glassy solution. The protein molecules are arranged in a way which means that their refractive index is nearly the same as glass- which makes the lens transparent. This is due to the small size of the protein molecules, less than 10 nm in diameter, and their close packing at high concentration

The lens contains three major types of crystallins, making up about 90% of the protein. Alpha crystallins are the most common. They are composed of two similar types of protein chain, which associate to form large spherical complexes containing about 40 chains. These large spheres repel one another and distribute themselves throughout the lens cells. Beta crystallins, shown here from, also form oligomeric complexes (contains a limited number of monomers), typically formed of two or six copies of the chain. There are several similar beta crystallins, which can mix and match to form a bunch of different types of oligomers. Finally, gamma crystallins are monomeric, and serve as a weak glue to gently bind the alpha crystallins together.

Our crystallin proteins need to last our entire life, so the lens contains a powerful method to protect them. Alpha crystallin acts as chaperone, finding damaged proteins and binding to them before they can form translucent or opaque complexes. Unfortunately, in spite of this protection, the damage builds up as we age, as crystallins are broken or unfolded or oxidized. Slowly, the damage leads to progressive build-up of opaque aggregates, leading to cataracts.