Protective protein in the eye lens affects protein oxidation

Guardian angel of the eye

Attempts to determine the structure of αA-crystallin were unsuccessful for over 40 years. The breakthrough came for a research team led by the TUM professors Sevil Weinkauf, professor of electron microscopy and Johannes Buchner, professor of biotechnology, by combining cryo-electron microscopy, mass spectrometry, NMR spectroscopy and molecular modeling.

"αA-crystalline is extremely multifaceted," says Sevil Weinkauf. “This makes it very difficult to determine its structure. It was only after developing a new strategy for data analysis that we were able to demonstrate that in solution it takes on different structures with 12, 16 or 20 subunits."

The typical function of protective proteins is to help other proteins maintain their form when stressed, by high temperatures, for example. This is why they are also referred to as chaperones.

αA- and αB-crystallin, too, have this function. In addition, human αA-crystallin has two cysteine residues. The sulfur atoms in these residues can form disulfide bridges. In-depth biochemical studies have shown that this bridging has a significant impact on various properties of the protein molecule.

"A common theory is that the disulfide bridges result from damage to the protein, for example through oxygen," says Johannes Buchner. "Our results suggest that αA-crystallin might play an active role in protecting other proteins from oxidation."

The research team's investigations demonstrate that oxidized αA-crystallin can even transfer the existing disulfide bridge to other proteins. "This ability corresponds to that of a protein disulfide oxidase," says Christoph Kaiser. “αA-crystallin can thus influence the redox state of other lens proteins. This function also explains why roughly half of the αA-crystallins in embryos already have such disulfide bridges.”

“Around 35 percent of all cases of blindness can be attributed to cataracts, says Sevil Weinkauf. “The molecular understanding of the functions of eye lens proteins forms an essential basis for developing prevention and therapy strategies. The realization that αA-crystallin also plays an important role in protecting against oxidation will now spawn further research."