An image of a diplonemid taken at sea; the cell was isolated for genomic sequencing. Credit: Patrick Keeling A rare microbe that was once thought to be insignificant has turned out to be one of the most abundant single-celled hunters in the ocean, and a team of researchers led by UBC have captured the first glimpse of these elusive predators. Diplonemids are tiny cells that have more or less been ignored by researchers until recently when surveys of marine diversity showed they are the most abundant protozoa, a diverse group of single-celled organisms that excludes bacteria and viruses, in the ocean. Despite their abundance, they had never been captured or observed directly in the ocean. Scientists from UBC and the Canadian Institute for Advanced Research (CIFAR) went to sea and managed to observe them for the first time.
”When a microbe is so abundant, it probably plays a very important role in the ecosystem,” said Patrick Keeling, a professor of botany at UBC and director of the Integrated Microbial Biodiversity program at CIFAR. ”The microbial world is one of the last frontiers of exploration on our planet, and we’re using microscopes together with genomics to learn as much as possible about this invisible life.”
The team sailed from the Monterey Bay Aquarium Research Institute in California to a well-studied part of the ocean known as Line 67, where the water is deep yet poor in nutrients. Here they photographed organisms from deep-water samples and used technology to sequence the genomes of these single-celled organisms.
The research showed that diplonemids are a diverse group of species of many different shapes and sizes, and that they hunt both bacteria and larger algae.
”It’s like discovering lions after having only seen gazelles, antelopes and zebras for so many years,” said Keeling.
Diplonemids also proved to have interesting genomes that are large and full of ”junk” DNA called introns that interrupt genes. Introns are found in genes of all complex cells, but the diplonemid introns are unique and appear to spread similar to how a virus copies its genetic material into other cells when it attacks.
To learn more about the ecology of these organisms and the role they play in maintaining the marine ecosystmes, the next step will be to figure out how to keep diplonemids alive in the lab, ”which will now be a lot easier since we know what they look like,” said Keeling.
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More information: Ryan M.R. Gawryluk et al, Morphological Identification and Single-Cell Genomics of Marine Diplonemids, Current Biology (2016). DOI: 10.1016/j.cub.2016.09.013
Journal reference:Current Biology
Provided by:University of British Columbia