The urine-caked nests of ancient desert pack rats are offering scientists a glimpse of the genetic makeup of insects from more than 34,000 years ago.
For many years, scientists have been extracting DNA from the bones of ancient humans, humanoids, and animals to paint a picture of evolution and species movement. Despite what the movie Jurassic Park portrays—dinosaurs resurrected based on preserved ancient DNA (aDNA)—scientists have had little success extracting genetic material from the preserved remains of insects.
Insects leave scant DNA behind, and little of it is preserved over thousands of years. However, a scientist has developed a novel way to use extraction methods previously reserved for ancient vertebrate DNA to isolate and amplify insect aDNA, thanks to ancient desert pack rat nests.
“Ancient DNA as a field has mostly been used for hominids, humans, and their close relatives, and to a fair degree for vertebrates, but not for insects,” says Aaron Smith, an assistant professor of entomology at Purdue University and lead author of a paper describing the work in the journal Scientific Reports. “In just the last few years, some papers have described identifying insect DNA through metagenomics, examining all the DNA in a sample without being specific. But we’ve been able to go deeper and identify ancient insects to the species level based on their DNA.”
The reason so much ancient DNA work focuses on vertebrates is because their bones seem to protect DNA for longer periods. It’s also possible to find and analyze those bones. Insects are much smaller and often only leave behind fragments of their exoskeletons, and few insect remains from thousands of years ago have survived intact well enough to draw genetic material from or identify.
Smith, who studies mostly desert insects, realized that ancient pack rat nests, called middens, could contain insect remains suitable for DNA sequencing. Pack rats pull materials together for nests and then urinate on them. The urine crystallizes, protecting the nest. Over time, the nest passes on to other rats who do the same, and the nest becomes solid, trapping insects and other materials in a type of time capsule.
“Eventually the center has accreted enough to be as hard as asphalt,” Smith says. “We can radio-carbon date these accurately back to 50,000 years and see what plants and insects were in a specific area at a specific time.”
Smith was able to identify several Asidini (darkling beetles) and draw DNA from samples gathered at Joshua Tree National Park in California. The DNA, preserved enough to recover the mitochondrial genome, was compared with genomes of modern and museum beetle specimens to confirm the species.
The beetles Smith’s team used date back approximately 1,600, 2,000, 8,400, and 34,400 years. Comparing the DNA sequences of the beetles at different times can tell scientists about species distribution for an area at a particular time and the traits the beetles evolved at those times.
“Now we can open up the field of paleobiology to include insects,” Smith says. “I’m interested in what these insects can tell us about changes in climate for these areas. Being able to look at the past distribution of a species and where it occurred over thousands of years is a powerful tool to have at our disposal.”
The National Science Foundation ARTS Program and the US Department of Agriculture’s National Institute of Food and Agriculture funded Smith’s work.
Source: Purdue University