Scientists celebrate 50 years since key RNA discovery

Today, 50 years later, it is abundantly clear that Rich--who made the discovery with David R. Davies while both were working at the National Institute of Mental Health--was onto something big. In fact, it generated a paradigm shift in the science of biology. The discovery changed how research is done at the molecular level and helped spawn what has become the global biotechnology revolution.

To mark the anniversary, Rich was invited to write an article about the work in the December issue of The Scientist. Likewise, Professor Alexander Varshavsky of Caltech wrote an article for Cell that appeared in the Dec. 29 issue.

In 1956 Rich and Davies announced in the Journal of the American Chemical Society that single strands of RNA can "hybridize," joining together to form a double-stranded molecule. As a result of the discovery and the work that followed, scientists now routinely identify, isolate, manipulate and replace the genes in living things. Such work led to the Human Genome Project and is pushing science toward a fundamental understanding of how life works.

"This was a founding technology of the biotechnology business," explained Rich, the William Sedgwick Thompson Professor of Biophysics. "The discovery was absolutely remarkable because no one, myself included, thought such a thing was possible and could work."

The seminal discovery of double-stranded RNA by Rich and Davies came only three years after James Watson and Francis Crick stunned the scientific world by describing DNA's structure as a double helix. Watson and Crick not only described a structure, but also suggested how inherited information--genetic information--is safely stored and can be passed from one generation to the next. It was a major milestone in the biosciences.

In 1953, Rich--working with famed chemist Linus Pauling at Caltech--was using X-ray crystallography to try to discover the structure of RNA, hoping to learn more about its role in life. One nagging question was whether RNA, like DNA, could exist in a double-stranded helical molecule.

The x-ray images weren't helping much; they were fuzzy, inconclusive shadows of the gooey, glassy fibers that were pulled from a glob of RNA.

At Caltech, and later at the NIH, Rich and his colleagues "talked a lot about RNA," he told a reporter from Chemical and Engineering News last month. "But nobody--including myself--suggested, 'Why don't you mix together PolyA and Poly U,' the two differing stands of RNA. It wasn't at all obvious that could work," he said, in part because everyone felt an enzyme would be needed to stitch them together. "People had no idea that hybridization could occur by itself."

Ultimately Rich did try mixing the two strands, resulting in the discovery of double-stranded RNA, but to this day, he said, he can't recall what prompted him to do so. "I've asked my colleagues and searched through my memory, and I don't actually know." But it did work, and that has made all the difference.

Source: MIT

Shotgun sequencing finds nanoorganisms
For 11 years, Jill Banfield at the University of California, Berkeley, has collected and studied the microbes that slime the floors of mines and convert iron to acid, a common source of stream pollution around the world.
Scientists find genetic oddity protects sex cells
Researchers have found that a class of RNA molecules previously thought to have no function may in fact protect sex cells from self-destructing.
Scientists discover role for dueling RNAs
Researchers have found that a class of RNA molecules, previously thought to have no function, may in fact protect sex cells from self-destructing. These findings will be published in the November 17 issue of the journal Cell.
Science's Breakthrough of the Year: Watching evolution in action
Evolution has been the foundation and guiding theory of biology since Darwin gave the theory its proper scientific debut in 1859. But Darwin probably never dreamed that researchers in 2005 would still be uncovering new details about the nuts and bolts of his theory -- how does evolution actually work in the world of influenza genes and chimpanzee genes and stickleback fish armor? Studies that follow evolution in action claim top honors as the Breakthrough of the Year, named by Science and its publisher AAAS, the nonprofit science society.
Meteorites Could Play a Key Role in Earth Life
University of Arizona scientists have discovered that meteorites, particularly iron meteorites, may have been critical to the evolution of life on Earth.

Their research shows that meteorites easily could have provided more phosphorus than naturally occurs on Earth -- enough phosphorus to give rise to biomolecules which eventually assembled into living, replicating organisms.
Scientists exploring new compounds to target muscular dystrophy
Scientists have identified a promising set of new compounds in the fight against muscular dystrophy. Using a drug-discovery technique in which molecules compete against each other for access to the target – the strand of toxic RNA that causes the most common form of muscular dystrophy in adults – a team at the University of Rochester Medical Center has identified several compounds that, in the laboratory, block the unwanted coupling of two molecules that is at the root of the disease.
Team identifies 13 new tumor-suppressor genes in liver cancer
Over the years, hunting for cancer-related genes and understanding how they work has been an important, although time-consuming, exercise. At Cold Spring Harbor Laboratory (CSHL), five different research groups have now combined their expertise to speed up the rate of discovering cancer-related genes and validating their function in living animals.
Shedding light on the 'dark matter' of genetics: New gene-silencing pathway found in plants
(PhysOrg.com) -- Biologists at Washington University in St. Louis have made major headway in explaining a mechanism by which plant cells silence potentially harmful genes.

Scientists celebrate 50 years since key RNA discovery

Related stories:

News discussion: