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Trillium angustipetalum

(Torr.) J.D. Freeman

Narrow-petal Trillium

G4Apparently Secure Found in 6 roadless areas NatureServe Explorer →
G4Apparently SecureGlobal Rank
Data deficientIUCN
LowThreat Impact
Identity
Unique IDELEMENT_GLOBAL.2.143413
Element CodePMLIL20020
Record TypeSPECIES
ClassificationSpecies
Classification StatusStandard
Name CategoryVascular Plant
IUCNData deficient
Endemicendemic to a single state or province
KingdomPlantae
PhylumAnthophyta
ClassMonocotyledoneae
OrderLiliales
FamilyMelanthiaceae
GenusTrillium
Concept Reference
Kartesz, J.T. 1994. A synonymized checklist of the vascular flora of the United States, Canada, and Greenland. 2nd edition. 2 vols. Timber Press, Portland, OR.
Taxonomic Comments
B. D. Ness (1993) listed Trillium kurabayashii as a synonym of T. angustipetalum. In bract orientation, color, and texture, and in petal shape, the two are quite different and certainly not the same species. Cytologist Masataka Kurabayashi found chromosomal differences between the two species (reported by J. D. Freeman 1975). Trillium kurabayashii and T. angustipetalum were synonymized by Ness (1993), however, experts agree that these two are indeed distinct species based on morphologic and molecular evidence (A. Floden pers. comm. 2019, K. Wayman pers. comm. 2019, Flora of North America Editorial Committee 2002a).
Conservation Status
Rank Method Rank calculation - Biotics v2
Review Date2019-10-22
Change Date1990-01-16
Edition Date2019-10-23
Edition AuthorsOliver, L. and K. Wayman (2019)
Threat ImpactLow
Range Extent20,000-200,000 square km (about 8000-80,000 square miles)
Number of Occurrences21 - 80
Rank Reasons
Trillium angustipetalum occurs in California from Fresno to Yuba Counties, and from disjunct areas in San Luis Obispo and Santa Barbara counties. The status of populations in Santa Barbara on private property and on the Vandenberg Air Force site is unknown. There is a false report of this species in southern Oregon that was determined to be incorrect. Threats to this species are low, and primarily from wildfire.
Range Extent Comments
Trillium angustipetalum occurs in the western United States, in the Sierra Nevada Mountains in California from Fresno to Yuba county. There are a few disjunct locations in San Luis Obispo and Santa Barbara counties (Case and Case 1997). Recent research grade observations from iNaturalist (2019) indicate this species is extant in areas where Case and Case (1997) report it as disjunct. The calculated range extent includes the disjunct locations. The range extent would be much smaller without the disjunct locations. When evaluating this species for conservation priority, the disjunct locations may warrant greater protection because they are isolated from the Sierra Nevada populations.
Occurrences Comments
There are likely no more than 80 occurrences of this species known as of 2019 (K. Wayman, pers. comm. 2019).
Threat Impact Comments
Threats to Trillium angustipetalum are relatively low and include wildfire, based on the very dry habitat where it occurs. Non-native plants are also a threat in some areas.
Ecology & Habitat

Reproduction

Trillium seeds have an elaiosome, an oily, lipid-rich attachment that is highly attractive to ants. The ants carry the seeds to their nest, eat the attachment, and leave the seeds in tunnels in their nests (FNA 2002a, Leege et al. 2010). The seeds later germinate en masse (Case and Case 1997). Yellow jackets (Vespula spp.) and other wasps are similarly attracted to the elaiosome. Yellow jackets are documented seed dispersers for three species (T. catesbaei, T. cuneatum, T. undulatum) (Zettler et al. 2001). Ants carry the seeds an average of about 1m whereas yellow jackets disperse seeds an average of 1.4m (Chafin 2010, Zettler et al. 2001). Long distance dispersers include mammals, such as white-tailed deer (Odocoileus virginianus) and woodchucks (Marmota monax) (Chafin 2010, Vellend et al. 2006). Similarly, it is suspected that elk (Cervus canadensis) and mule deer (Odocoileus hemionus) of the western U.S.A. are capable of dispersing seeds over long distances (Bartuszevige and Endress 2008).

All Trillium have rhizomes but the frequency of asexually reproduction varies (Chauhan et al. 2019, FNA 2002a, Ohara 1989).

Trillium seeds exhibit a somewhat unique kind of dormancy called deep simple double morphophysiological dormancy, meaning they require two winters and one summer to complete dormancy break. After dispersal, roots (radicles) emerge in the first spring and leaves (epicotyls) begin growing in the second spring. The result is that Trillium seeds are generally about 1.5-2 years before they are non-dormant. If root emergence does not occur during the first spring, the next opportunity for root emergence would be the third spring and epicotyl emergence would occur during the fourth spring after dispersal (Walck et al. 2005). Age to maturity, or flowering, is variable and has been recorded from 4 to 20 years depending on growing conditions (Case and Case 1997).
Terrestrial Habitats
Forest - Hardwood
Other Nations (1)
United StatesN4
ProvinceRankNative
CaliforniaSNRYes
Threat Assessments
ThreatScopeSeverityTiming
7 - Natural system modificationsRestricted (11-30%)Moderate - slightHigh (continuing)
7.1 - Fire & fire suppressionRestricted (11-30%)Moderate - slightHigh (continuing)
7.1.2 - Suppression in fire frequency/intensityRestricted (11-30%)Moderate - slightHigh (continuing)
8 - Invasive & other problematic species, genes & diseasesNegligible (<1%)Extreme or 71-100% pop. declineHigh (continuing)
8.1 - Invasive non-native/alien species/diseasesNegligible (<1%)Extreme or 71-100% pop. declineHigh (continuing)

Plant Characteristics
DurationPERENNIAL, Long-lived
Economic Value (Genus)Yes
Roadless Areas (6)
California (6)
AreaForestAcres
Caples CreekEldorado National Forest17,854
Devil GulchSierra National Forest30,490
North Fork Middle Fork American RiverTahoe National Forest11,245
North MountainStanislaus National Forest7,856
PyramidEldorado National Forest24,347
WaterhouseStanislaus National Forest4,394
References (20)
  1. Aaron, Floden. Assistant Scientist, Flora of Missouri, Monographic Studies. Missouri Botanical Garden. www.mobot.org. St. Louis, MO.
  2. Anderson, M. Kat, and Jon E. Keeley. "Native peoples’ relationship to the California chaparral." <i>Valuing Chaparral</i>. Springer, Cham, 2018. 79-121.
  3. Bartuszevige, A.M., and B.A. Endress. 2008. Do ungulates facilitate native and exotic plant spread? Seed dispersal by cattle, elk and deer in northeastern Oregon. Journal of Arid Environments 72: 904-913.
  4. Case, F.W. and R.B. Case. 1997. Trilliums. Timber Press, Portland Oregon.
  5. Chafin, L. G. 2010d. Species account for <i>Trillium persistens </i>for Georgia Department of Natural Resources. Online. Available: georgiawildlife.com/sites/default/files/uploads/wildlife/nongame/pdf/accounts/plants/trillium_persistens.pdf.
  6. Chauhan, H., A. Bisht, I. Bhatt, A. Bhatt, and D. Gallacher. 2019. <i>Trillium </i>- toward sustainable utilization of a biologically distinct genus valued for traditional medicine. The Botanical Review 85(3): 252-272.
  7. Fernald, M.L., and A.C. Kinsey. 1943. Edible Wild Plants of Eastern North America. Idlewild Press, Cornwall-on-Hudson, NY. xiv+452 pp.
  8. Flora of North America Editorial Committee (FNA). 2002a. Flora of North America north of Mexico. Vol. 26. Magnoliophyta: Liliidae: Liliales and Orchidales. Oxford Univ. Press, New York. xxvi + 723 pp.
  9. iNaturalist. Online. Available: http://www.inaturalist.org (accessed 2019).
  10. Kartesz, J.T. 1994. A synonymized checklist of the vascular flora of the United States, Canada, and Greenland. 2nd edition. 2 vols. Timber Press, Portland, OR.
  11. Klest, S.M. 2002. Propagation Protocol for Western Trilliums. Native Plants Journal 3(1):22-23.
  12. Leege, L. M., J. S. Thompson, D.J. Parris. 2010. The Responses of Rare and Common Trilliums (<i>Trillium reliquum</i>, <i>T. cuneatum</i>, and <i>T. maculatum</i>) to Deer Herbivory and Invasive Honeysuckle Removal. Castanea 75(4): 433-443.
  13. Lewis, Walter H., and Memory P.F. Elvin-Lewis. 1977. Medical Botany: Plants Affecting Man's Health. John Wiley and Sons, New York, New York. 515 p.
  14. Ohara, M. 1989. Life history evolution in the genus Trillium. Plant Species Biology 4:1-28.
  15. Rahman, S., M. Ismail, M. Khurram, I. Ullah, F. Rabbi, and M. Iriti. 2017. Bioactive steroids and saponins of the genus <i>Trillium. </i> Molecules 22(12): 2156.
  16. Trillium workshop group. 2019. , L. L. Gaddy, A. Floden, A. Frances, A. Highland, D. Leaman, T. Littlefield, C. Meredith, S. O'Bryan, L. Oliver, E. Schilling, A. Schotz, A. Walker, K. Wayman. Status assessment workshop at Mt. Cuba Center, Oct. 21-23, 2019.
  17. Vellend, M., J. Myers, S. Gardescu, and P. Marks. 2003. Dispersal of <i>Trillium</i> seeds by deer: Implications for long-distance migration of forest herbs. Ecology 84(4):1067-1072.
  18. Walck, J.L., J.M. Baskin, C.C. Baskin, and S.N. Hidayati. Defining transient and persistent seed banks in species with pronounced seasonal dormancy and germination patterns. Seed Science Research 15: 189-196. DOI: 10.1079/SSR2005209
  19. Wayman, K. Professor of Chemistry, Humboldt State University. Arcata, CA.
  20. Zettler, J. A., T. P. Spira, and A. A. Craig. 2001. Yellow Jackets (<i>Vespula</i> spp.) Disperse <i>Trillium</i> (spp.) Seeds in Eastern North America. American Midland Naturalist 146(2):444-446.