The experiment establishes a new technique for reconstructing the 3-D structure of many types of biological samples from a series of X-ray laser snapshots.
"Ever since I started in this field of X-ray laser research, this has always been the dream - to acquire 3-D images of real biological samples," says Tomas Ekeberg, PhD, biophysicist, Uppsala University, Sweden, and lead author of the study, published March 2 in Physical Review Letters. "This is fantastic - it's a breakthrough in our research."
Mimivirus is so big - its volume is thousands of times larger than the smallest viruses and even larger than some bacteria - that it was misclassified as a bacterium until 2003. Subsequent discoveries have found other giant viruses, some of which are even larger.
Mimivirus is also genetically complex, with nearly 1,000 major genes compared to only a handful in the HIV virus.
Scientists have been trying to determine the inner structure of these giant viruses to learn more about their origins: For example, did they borrow genes over time from the host organisms they infect, like amoebas? Did they precede cell-based life or devolve from cell-based organisms?
"We can see quite clearly that the inside of these viruses is not uniform," Ekeberg says.
This same general feature had also been seen before using an electron-based imaging technique with frozen samples, and LCLS allows studies of viruses and other biological samples in a more natural, intact state. Researchers said that LCLS shows promise for achieving sharper images that reveal more inner details in the future because of the uniquely intense, penetrating power of its X-rays.
The same technique was recently used to study bacterial cell structures. LCLS managers have launched an initiative with the scientific community to improve techniques for imaging intact, biological particles that are difficult to study.
"The next Holy Grail is to study large, single proteins at LCLS," says Janos Hajdu, PhD, professor, biophysics, Uppsala, and a pioneer in biological particle imaging.
[Source: SLAC National Accelerator Laboratory]