Earth’s Oldest Trees in Climate-Induced Race up the Tree Line Posted on September 18, 2017 Share on Facebook Share on Twitter Share on Google+ Share on Reddit Share on Pinterest Share on Linkedin Share on Tumblr Gnarled, dead bristlecone pine trees, which can live more than 5,000 years, stand where young limber pine grow around them. Limber pine is beginning to colonize areas of the Great Basin once dominated by bristlecones. (Brian Smithers/UC Davis) Davis, Calif., (September 18, 2017) – Bristlecone pine and limber pine trees in the Great Basin region are like two very gnarled, old men in a slow-motion race up the mountaintop, and climate change is the starting gun, according to a study from the University of California, Davis. Gnarled, dead bristlecone pine trees, which can live more than 5,000 years, stand where young limber pine grow around them. Limber pine is beginning to colonize areas of the Great Basin once dominated by bristlecones. (Brian Smithers/UC Davis) The study, published in the journal Global Change Biology, shows that the tree line has been steadily moving upslope over the past 50 years in the Great Basin. The region extends from California’s Sierra Nevada, across Nevada to Utah’s Uinta Mountains. Its north and south are framed by the Columbia and Colorado rivers’ watersheds. The study also found that limber pine is successfully “leapfrogging” over bristlecone pine. They are growing in soils once almost completely dominated by bristlecone pine, and they are moving upslope at a faster rate than the bristlecone pine. Charging upslope – “We are seeing very little regeneration anywhere in bristlecone ranges except in the tree line and, there, limber pine is taking all the good spots,” said the study’s corresponding author Brian Smithers, a Ph.D. candidate in the Department of Plant Sciences at UC Davis. “It’s jarring because limber pine is a species you normally see further downslope, not at tree line. So it’s very odd to see it charging upslope and not see bristlecone charging upslope ahead of limber pine, or at least with it.” The study concludes that if bristlecone pine trees are unable to advance upslope because they are blocked by limber pine, bristlecones could face a reduction of their range and possibly local extinctions. Earth’s oldest living trees – Bristlecone pine trees are Earth’s oldest individual trees and can live for more than 5,000 years. No spring chicken, limber pine trees can live 2,000 years or more. Dead bristlecone pines stand among limber pine trees on the California side of the White Mountains, part of the Great Basin region. (Brian Smithers/UC Davis) Both tree species have seen many climate changes during their time on Earth — from extremely warm periods to ice ages — and have slowly advanced across the landscape. Over millennia, bristlecone pine trees have moved from the lowlands of the Great Basin up to the current tree line. But, the study notes, neither bristlecone nor limber pine have ever experienced climate change and temperature increases as rapidly as what has been occurring in recent decades. Legacy effects – Smithers said he doesn’t expect bristlecone pine adult trees to be impacted much by current climatic shifts, as those trees are well-established. But how, if and where new bristlecone pine trees will regenerate is less certain, particularly as other species like limber pine take up valuable space for them to germinate. “The things we’re doing today have legacy effects for thousands of years in the Great Basin,” Smithers said. “When those trees do start to die, they won’t likely be replaced because it’s just too hot and dry.” The study suggests that land managers identify the specific bottlenecks for a species to live long enough to reproduce, and focus on that stage. For long-lived trees like bristlecone and limber pines, the bottleneck is at the time of their initial establishment, not hundreds and thousands of years into their adulthoods. Bristlecone pine trees grow on soils and in conditions where few other species can live. But limber pines in the Great Basin region, such as California’s White Mountains, are beginning to give them some competition. (Brian Smithers/UC Davis) The study’s additional authors include co-leading authors Malcolm North with UC Davis and the USDA Forest Service, and Andrew Latimer with UC Davis, and co-author Constance Millar with the USDA Forest Service. The study was financially supported by the UC Davis Graduate Group in Ecology, White Mountains Research Center, California Native Plant Society, the Henry A. Jastro Fund, Nevada Native Plant Society, and the Davis Botanical Society.