Polarized microscopy technique shows protein relation in living cells

A polarized light technique developed by Rockefeller University scientists uses properties that can help to figure out the orientation of specific proteins within a cell. Zeroing their microscopes in on the nuclear pore complex, the technique measures how components of large protein complexes are arranged in relation to one another, says Sandy Simon, head of the Laboratory of Cellular Biophysics at Rockefeller. The scientists believe their technique can also be applied to other multi-protein complexes such as those involved in DNA transcription, protein synthesis or viral replication, he says.

The new technique takes advantage polarized light to show how specific proteins are aligned in relation to one another. After genetically attaching fluorescent markers to individual components of the nuclear pore complex, the scientists replaced the cell's own copy of the gene that encodes the protein with the new form that has the fluorescent tag. Then, they used customized microscopes to measure the orientation of the waves of light the fluorescently tagged proteins emitted. By combining these measurements with known data about the structure of the complex, the scientists can confirm or deny the accuracy of previously suggested models.

"Our experimental approach to the structure is synergistic with other studies being conducted at Rockefeller, including analysis with X-ray crystallography in Günter's [Blobel] lab and electron microscopy and computer analysis in Mike Rout's lab," says Simon. "By utilizing multiple techniques, we are able to get a more precise picture of these complexes than has ever been possible before."

The scientists used the technique to study nuclear pore complexes in both budding yeast and human cells. In the case of the human cells, their new data shows that multiple copies of a key building block of the nuclear pore complex, the Y-shaped subcomplex, are arranged head-to-tail, rather than like fence posts, confirming a model proposed by Blobel in 2007.

"As a graduate student with Günter Blobel, I determined the three-dimensional structure of the Y-shaped subcomplex using electron microscopy," says Martin Kampmann, a former a member of Günter Blobel's Laboratory of Cell Biology who is currently at the University of California, San Francisco. "However, it was still a mystery how these 'Y's are arranged. The new technique we have developed reveals the orientation of building blocks in the cell, and we hope that it will eventually enable us to assemble individual crystal structures into a high-resolution map of the entire nuclear pore complex."

Eventually, the scientists say their technique could go even further. Because the proteins' fluorescence can be measured while the cells are still alive, it could give scientists new insights into how protein complexes react to varying environmental conditions, and how their configurations change over time.

"What happens when other proteins pass through the nuclear pore? Does the orientation of the nucleoporins change? With this technique, can find out not only what the pore looks like when it's sitting still, but what happens to it when it's active," Simon says. Their first characterization of the dynamics of the nuclear pore proteins was published recently in The Biophysical Journal.

The polarized microscopy technique was developed by Simon along with Kampmann, postdoc Alexa Mattheyses, and graduate student Claire Atkinson.
 
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Posted by Lee Mather

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