Researchers find that Earth may be home to 1 trillion species
Genetic sequencing indicates that Earth could contain nearly 1 trillion species, with only one-thousandth of 1 percent now identified, according to the results of a new study. The estimate, based on universal scaling laws applied to large datasets, appears today in the journal Proceedings of the National Academy of Sciences.
The scientists combined microbial, plant and animal datasets from government, academic and citizen science sources, resulting in the largest compilation of its kind. Altogether, these data represent more than 5.6 million microscopic and non-microscopic species from 35,000 locations across all the world’s oceans and continents, except Antarctica.
“Estimating the number of species on Earth is among the great challenges in biology,” Lennon said. “Our study combines the largest available datasets with ecological models and new ecological rules for how biodiversity relates to abundance. This gave us a new and rigorous estimate for the number of microbial species on Earth.”
He added that “until recently, we’ve lacked the tools to truly estimate the number of microbial species in the natural environment. The advent of new genetic sequencing technology provides a large pool of new information.”
“This research offers a view of the extensive diversity of microbes on Earth,” said Simon Malcomber, director of the Dimensions of Biodiversity program. “It also highlights how much of that diversity still remains to be discovered and described.”
Microbial species are forms of life too small to be seen with the naked eye, including single-celled organisms such as bacteria and archaea, as well as certain fungi.
“Older estimates were based on efforts that dramatically under-sampled the diversity of microorganisms,” he added. “Before high-throughput genetic sequencing, scientists characterized diversity based on 100 individuals, when we know that a gram of soil contains up to a billion organisms, and the total number on Earth is more than 20 orders of magnitude greater.”
The realization that microorganisms were significantly under-sampled caused an explosion in new microbial sampling efforts over the past several years.
The study’s inventory of data sources includes 20,376 sampling efforts on bacteria, archaea and microscopic fungi, as well as 14,862 sampling efforts on communities of trees, birds and mammals.
“A massive amount of data has been collected from these surveys,” said Locey. “Yet few have tried to pull together all the data to test big questions.”
He added that the scientists “suspected that aspects of biodiversity, like the number of species on Earth, would scale with the abundance of individual organisms. After analyzing a massive amount of data, we observed simple but powerful trends in how biodiversity changes across scales of abundance.”
The researchers found that the abundance of the most dominant species scales with the total number of individuals across 30 orders of magnitude, “making it the most expansive scaling law in biology,” says Lennon.
Scaling laws, like that discovered by the scientists, are known to accurately predict species numbers for plant and animal communities. For example, the number of species scales with the area of a landscape.
“Until now, we haven’t known whether aspects of biodiversity scale with something as simple as the abundance of organisms,” Locey said. “As it turns out, the relationships are not only simple but powerful, resulting in our estimate of upward of one trillion species.”
The study’s results also suggest that identifying every microbial species on Earth presents a huge challenge.
“Of those species cataloged, only about 10,000 have ever been grown in a lab, and fewer than 100,000 have classified genetic sequences,” Lennon said. “Our results show that this leaves 100,000 times more microorganisms awaiting discovery, and 100 million to be fully explored.
“Microbial biodiversity, it appears, is greater than we ever imagined.”