Pando (tree)

From Encyc

Pando (Latin for "I spread"), also known as The Trembling Giant,[1][2] is a clonal colony of a single male quaking aspen (Populus tremuloides) determined to be a single living organism by identical genetic markers[3] and one massive underground root system. The plant is estimated to weigh collectively 6,000,000 kg (6,600 short tons),[4] making it the heaviest known organism.[5] The root system of Pando, at an estimated 80,000 years old, is among the oldest known living organisms.[6][7]

Pando is located 1 mile southwest of Fish Lake on Utah route 25.[8] in the Fremont River Ranger District of the Fishlake National Forest, at the western edge of the Colorado Plateau in South-central Utah, at N 38.525 W 111.75.

History[edit]

Pando aspen grove at Fishlake National Forest

Pando is thought to have grown for much of its lifetime under ideal circumstances: frequent forest fires have prevented its main competitor, conifers, from colonizing the area, and a climate shift from wet and humid to semi-arid has obstructed seedling establishment and the accompanying rivalry from younger aspens.[citation needed]

During intense fires, the organism survived underground, with its root system sending up new stems in the aftermath of each wildfire. If its postulated age is correct, the climate into which Pando was born was markedly different from that of today, and it may be as many as 10,000 years since Pando's last successful flowering. According to an Organization for Economic Co-operation and Development (OECD) report:

Clonal groups of P. tremuloides in eastern North America are very common, but generally less than 0.1 ha in size, while in areas of Utah, groups as large as 80 ha have been observed (Kemperman and Barnes 1976). In the semi-arid western United States, some argue that widespread seedling establishment has not occurred since the last glaciation, some 10,000 years ago (Einspahr and Winton 1976, McDonough 1985). Indeed, some biologists feel that western clones could be as old as 1 million years (Barnes 1966, 1975).

— Organisation for Economic Co-operation and Development, Consensus Document on the Biology of Populus L. (Poplars)[4]

Pando was researched by Burton V. Barnes of the University of Michigan in 1968 and the 1970s.[9] Barnes was widely considered an expert on North American aspen at the time, having been one of the first to describe the clonal growth of aspen from an extensive root system as part of his dissertation at Michigan in the late 1950s. Barnes had described Pando as a single organism based on its morphological characteristics. Building on Barnes's earlier work, Michael Grant of the University of Colorado at Boulder re-examined Pando and claimed it to be the world's most massive organism in 1992.[citation needed]

In 2006 the United States Postal Service made a stamp in commemoration of the aspen, calling it one of the forty "Wonders of America."[10]

Size and age[edit]

A trunk or stem of Pando

The clonal colony encompasses 43 hectares (106 acres), weighs nearly 5900 tonnes (13,000,000 pounds), and has over 40,000 stems (trunks), which die individually and are replaced by new stems growing from its roots.[11] The average age of Pando's stems is 130 years, as indicated by tree rings. The roots are 80,000 years old.[12] Michael Grant in BioScience said:

...quaking aspen regularly reproduces via a process called suckering. An individual stem can send out lateral roots that, under the right conditions, send up other erect stems; from all above-ground appearances the new stems look just like individual trees. The process is repeated until a whole stand, of what appear to be individual trees, forms. This collection of multiple stems, called ramets, all form one, single, genetic individual, usually termed a clone.

Debate[edit]

Quaking aspen in Utah

Some experts[who?] speculate that Pando may not be the heaviest existing organism. Less well-studied quaking aspens in Utah may be 80 hectares in extent and one million years old.[citation needed] Other large colonies could exist elsewhere. A clonal colony of at least seven Coastal Redwoods could weigh more,[13] though no such stand has been systematically sought and identified yet. Other scientists think that portions of Pando's root system may be dead and might have led the plant to split into separate groups and it therefore would not be one organism.[citation needed]

Tree experts also note that the organism's age cannot be determined with the level of precision found in tree rings; some claim Pando's age is closer to 1 million years.[5] Its current 80,000 year designation is based on a complex set of factors including the history of its local environment such as: The evidence indicating that there are few if any naturally occurring new aspens in most of the western United States since a climate shift took place 10,000 years ago and eliminated favorable soil conditions for seedlings; the rate of growth (including the differences of rates in distinct climates when accounting for its local-climate history, that males grow slower than females, and that aspens grow slower at higher elevations – Pando is at 2,697 m, or 8,848 ft, above sea level); its size; and its genetic code in comparison to the mutations found among aspens born in the modern era. Michael Grant summed it thus:

Despite enormous crops of viable seeds, successful seedling establishment appears to be a rare event in the semi-arid West, but the establishment of new trees from seeds appears to be common in the moist, humid forests of New England... aspen establishment from seeds probably has not occurred in the western United States since the last glaciation, some 10,000 years ago... Part of the rationale behind current age estimates for aspen clones is that sexual reproduction is effectively frustrated by the rarity of a favorable suite of conditions in semi-arid environments... High levels of genetic variation and excesses of heterozygotes are found in [the aspen of] semi-arid environments... Clonal reproduction is more common in arid environments... Heterozygotes often exhibit superior longevity in forest trees [across many species]... growth rate of aspen decline with elevation, steepness of slope, age of the ramet, and exposure to wind... growth rate decreased dramatically with elevation... The researchers reported that the area of the female clones was 41% greater than males, the number of female ramets 52% greater, and the basal area of females 56% greater [when compared at the same age and environment]...

Conversely, other observations in the region show that seedling establishment of new clones is regular, and often abundant on sites exposed by wildfire.[14] J. L. Howard (U.S. Forest Service Fire Effects Information System) states:[15]

Kay documented post-fire quaking aspen seedling establishment following 1986 and 1988 fires in Grand Teton and Yellowstone National Parks, respectively. He found seedlings were concentrated in kettles and other topographic depressions, seeps, springs, lake margins, and burnt-out riparian zones. A few seedlings were widely scattered throughout the burns. In Grand Teton National Park, establishment was greatest (950-2,700 seedlings/ha) in 1989, a wet year, but hundreds to thousands of seedlings established each year despite drought conditions in 1986-1988 and 1990-1991. Seedlings surviving past one season occurred almost exclusively on severely burned surfaces.

Other candidates for oldest or heaviest living organisms include the possibly larger fungal mats in Oregon, the ancient clonal Creosote bushes, and strands of the clonal marine plant Posidonia oceanica in the Mediterranean Sea.

See also[edit]

References[edit]

  1. Grant, Michael C. (1993-10-01). "The Trembling Giant". Discover Magazine. Retrieved 2008-05-08.
  2. Research and Development Information Outreach, USDA Forest Service (1999). "Quaking in Their Roots: The Decline of Quaking Aspen". Natural Inquirer. US Department of Agriculture. 2 (1): 7–11. Retrieved 2012-03-11. Unknown parameter |month= ignored (help)
  3. DeWoody, J.; Rowe, C.A.; Hipkins, V.D.; Mock, K.E. (2008). ""Pando" Lives: Molecular Genetic Evidence of a Giant Aspen Clone in Central Utah". Western North American Naturalist. 68 (4): 493–497. doi:10.3398/1527-0904-68.4.493.CS1 maint: multiple names: authors list (link)
  4. 4.0 4.1 OECD Environment Directorate (2000). "Consensus Document on the Biology of Populus L. (Poplars)" (Microsoft Word document). Organisation for Economic Co-operation and Development. Retrieved 2006-10-08. Cite journal requires |journal= (help)
  5. 5.0 5.1 Genetic Variation and the Natural History of Quaking Aspen, Jeffry B. Mitton; Michael C. Grant, BioScience, Vol. 46, No. 1. (Jan., 1996), pp. 25-31. JSTOR
  6. Quaking Aspen by the Bryce Canyon National Park Service
  7. Sibley, David Allen. The Sibley Guide to Trees. New York: Knopf, 2009. (p. xv).
  8. "Pando". USDA Forest Service. Retrieved 2013-08-24.
  9. Mock, K.E. , Rowe, C.A. , Hooten, M.B. , Dewoody, J. , Hipkins, V.D. (2008). "Blackwell Publishing Ltd Clonal dynamics in western North American aspen (Populus tremuloides)". U.S. Department of Agriculture, Oxford, UK : Blackwell Publishing Ltd. p. 17. Retrieved 2013-12-05.CS1 maint: multiple names: authors list (link)
  10. "Wonders of America: Land of Superlatives". Archived from the original on 2 December 2008.
  11. "Pando". USDA Forest Service. Retrieved 2013-08-24.
  12. "Quaking Aspen". US National Park Service. Retrieved 2013-08-24.
  13. Bob van Pelt
  14. Kay, Charles E. (1993). Aspen seedlings in recently burned areas of Grand Teton and Yellowstone National Parks. Northwest Science. 67(2): 94-104.
  15. U.S. Forest Service Fire Effects Information System: Populus tremuloides botanical and ecological characteristics