Genome Sequencing May Save California’s Legendary Sugar Pine

The genome of California’s legendary sugar pine, which naturalist John Muir declared to be “king of the conifers” more than a century ago, has been sequenced by a research team led by UC Davis scientists.
This cone-laden sugar pine grows in the Stanislaus-Tuolumne Experimental Forest of California's Stanislaus National Forest.

Genome Sequencing May Save California’s Legendary Sugar Pine

The genome of California’s legendary sugar pine, which naturalist John Muir declared to be “king of the conifers” more than a century ago, has been sequenced by a research team led by UC Davis scientists.

At 10 times the size of the human genome, the sugar pine genome is the largest ever sequenced for any organism. It is expected to provide valuable information that may help preserve the iconic but imperiled tree.

“Having the genome sequence allows us to discover the underlying genetic determinants of disease resistance, which will greatly facilitate reforestation efforts,” said professor and principal investigator David Neale, a UC Davis forest tree geneticist. “We can now give forest managers modern, rapid genetic tools to identify resistant trees.”

Neale collaborated on the Pine Reference Sequences project with geneticist Charles Langley and bioinformatics researcher Kristian Stevens, both of UC Davis, as well as researchers from other universities and the U.S. Forest Service.

The genome for the sugar pine has been publicly released and is available through open access at the Pine Reference Sequences website.

Importance of sugar pines in California forests

The sugar pine (Pinus lambertiana) is one of the tallest tree species in the world. It is endemic primarily to California, stretching south into parts of Baja Mexico and north into Oregon. The stately tree’s pinecones, averaging 10 to 20 inches in length, are among the longest of any conifer species.

“The sugar pine has important environmental value as a key component of California forests, ecological and recreational value throughout the Sierra Nevada, and economic value as a source of timber,” Neale said.

Around 1930, white pine blister rust was introduced into California. The fungal pathogen is a significant threat to sugar pines and other species of “white pines.” In fact, of the commercially important white pines in North America, sugar pine is most susceptible to white pine blister rust.

In addition, sugar pine survival is threatened by damage from bark beetles, and the ongoing drought and lack of snowpack in the Sierra.

Sequencing pine genomes

Pine trees and other ancient conifers are dominant species in forests found in temperate regions of the world. The genus Pinus includes over 100 species of pine trees, which fall into two major subgroups — the yellow pines and the white pines. The loblolly pine, a member of the yellow pine subgroup, was sequenced by Neale, Langley and colleagues last year. The newly sequenced sugar pine has a genome 1.5 times larger than the loblolly pine, which itself was considered large when it was sequenced. These two new reference sequences serve as foundations for future studies and applications in pine trees.

“The sequencing and assembly of these two pine genomes reaches the present-day limits of genomic technologies and methods,” said Professor Langley. “Like the human genome reference sequence, they are not yet complete, but they do provide an almost complete ‘parts list’ and a draft of the ‘instructions.’”

Building on earlier disease resistance discoveries

Bohun Kinloch, an emeritus research geneticist with the U.S. Forest Service, used traditional breeding methods and progeny testing over many years, before sequencing existed, to detect a rare blister rust resistance gene in sugar pine “parent trees” in 1970.

“The U.S. Forest Service plants seedlings from resistant parent trees into forests, so the new diagnostic tools derived from the reference sequences will speed the finding of disease-resistant parent trees directly, bypassing costly progeny testing. Seeds planted from these parents will help protect new generations of sugar pine trees from the devastating blister rust pathogen,” Kinloch said.

This information is of great interest to environmental agencies such as the U.S. Forest Service and timber companies such as Sierra Pacific Industries that manage the natural range of sugar pine.

Accessing the genome sequence

The sugar pine genomic information has been made freely available by the U.S. Department of Agriculture’s National Institute of Food and Agriculture, which funded the project; UC Davis; and the other research partners. A report of the sequencing and analyses of the sugar pine genome is pending publication in a scientific journal. The scientific reports of the loblolly genome sequencing appeared last year in the journals Genetics and Genome Biology.

Key partners in the sequencing project were professors Steven Salzberg, a computational biologist at Johns Hopkins University, and Jill Wegrzyn, a bioinformatician at the University of Connecticut.

 

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