Tourists visiting the town of Klosterneuburg in eastern Austria often head for the 12th century monastery or the nearby memorial to author Franz Kafka. Virologists and evolutionary biologists, however, may one day pay homage to the town's sewage treatment plant, which has yielded a genome that appears to be from the most cell-like viruses yet. These oddities challenge the controversial hypothesis that so-called giant viruses are descendants of a vanished group of cellular organisms—a fourth domain of life. Instead, the study argues, these outsized viruses have more pedestrian origins.
"I found [the work] very convincing," says environmental virologist Matthias Fischer of the Max Planck Institute for Medical Research in Heidelberg, Germany. "Based on the data available now, I would not put my money on the fourth domain hypothesis."
Most viruses are much smaller than cells and need few genes because they replicate by co-opting the machinery of their hosts. Certain bird and pig viruses, for example, get by with just two genes, compared with nearly 4400 genes in a common strain of the intestinal bacterium Escherichia coli. Because viruses cannot reproduce independently and lack other hallmarks of cellular organisms, biologists have typically blackballed them from the club of life.
The first report of giant viruses, in Science in 2003, jolted researchers. Not only are these viruses larger than many microorganisms, but they can carry more than 2500 genes, surpassing many bacteria. These behemoths required revisions to the evolutionary tree of life, some scientists contended. The standard tree has three main groups, or domains—bacteria, archaea, and eukaryotes. But several researchers proposed that giant viruses are leftovers of a fourth domain of life. In this view, their ancestors were now-extinct cells that over time ditched many genes and became parasites.
F. SCHULZ ET AL., SCIENCE 356, 6333 (7 APRIL 2017) ©AAAS
Other scientists, such as evolutionary biologist Eugene Koonin of the National Center for Biotechnology Information in Bethesda, Maryland, saw no need for a fourth domain. "It's crystal clear that these giant viruses belong to a group of viruses that includes much smaller ones," he says. He believes they evolved when some of these smaller viruses incorporated more and more DNA from hosts and became massive.
Frederik Schulz, a postdoc at the Department of Energy Joint Genome Institute in Walnut Creek, California, and colleagues weren't planning to test the fourth domain scenario when they teamed up with Austrian scientists to investigate the microbes residing in sludge from the Klosterneuburg plant. They used a method known as metagenomics, which involves sequencing all the DNA in a sample to identify the genomic fingerprints of new organisms, rather than directly isolating cells or viruses. Viral DNA fragments kept turning up. When the team assembled some of these fragments into a genome, they concluded that it belongs to a new giant virus, which they named Klosneuvirus. By applying the same techniques to samples from other locales, the team pieced together genomes of three kindred viruses.
These Klosneuviruses stood out because their genomes are more cell-like than those of any previous giant viruses. For example, cells stitch together proteins from 20 types of amino acids, and each has a different enzyme that affixes it to a carrier molecule for delivery to sites of protein synthesis. Other giant viruses carry genes for seven varieties of the attachment enzymes, but between them the Klosneuviruses have genes for all 20.
Giant debate Larger than some bacteria, Mimivirus and related giant viruses dwarf other viruses and harbor complex genomes that have raised questions about their place on the tree of life
Other scientists, such as evolutionary biologist Eugene Koonin of the National Center for Biotechnology Information in Bethesda, Maryland, saw no need for a fourth domain. "It's crystal clear that these giant viruses belong to a group of viruses that includes much smaller ones," he says. He believes they evolved when some of these smaller viruses incorporated more and more DNA from hosts and became massive.
Frederik Schulz, a postdoc at the Department of Energy Joint Genome Institute in Walnut Creek, California, and colleagues weren't planning to test the fourth domain scenario when they teamed up with Austrian scientists to investigate the microbes residing in sludge from the Klosterneuburg plant. They used a method known as metagenomics, which involves sequencing all the DNA in a sample to identify the genomic fingerprints of new organisms, rather than directly isolating cells or viruses. Viral DNA fragments kept turning up. When the team assembled some of these fragments into a genome, they concluded that it belongs to a new giant virus, which they named Klosneuvirus. By applying the same techniques to samples from other locales, the team pieced together genomes of three kindred viruses.
These Klosneuviruses stood out because their genomes are more cell-like than those of any previous giant viruses. For example, cells stitch together proteins from 20 types of amino acids, and each has a different enzyme that affixes it to a carrier molecule for delivery to sites of protein synthesis. Other giant viruses carry genes for seven varieties of the attachment enzymes, but between them the Klosneuviruses have genes for all 20.
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