Difference between revisions of "Ageratina aromatica"

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===Phenology===<!--Timing off flowering, fruiting, seed dispersal, and environmental triggers.  Cite PanFlora website if appropriate: http://www.gilnelson.com/PanFlora/ -->  
 
===Phenology===<!--Timing off flowering, fruiting, seed dispersal, and environmental triggers.  Cite PanFlora website if appropriate: http://www.gilnelson.com/PanFlora/ -->  
It can spread vegetatively in a limited area, but it is dependent on sexual reproduction to colonize new areas.<ref name="newengland"/> Flowering occurs in the fall<ref name="wunderlin">Wunderlin, Richard P. and Bruce F. Hansen. Guide to the Vascular Plants of Florida. Second edition. 2003. University Press of Florida: Gainesville/Tallahassee/Tampa/Boca Raton/Pensacola/Orlando/Miami/Jacksonville/Ft. Myers. 295. Print.</ref>, and has been observed flowering in the months of October, November, and January with peak inflorescence in October.<ref name= "Panflora"> Nelson, G. PanFlora: Plant data for the eastern United States with emphasis on the Southeastern Coastal Plains, Florida, and the Florida Panhandle. www.gilnelson.com/PanFlora/ Accessed: 4 MAR 2019 </ref> It has been observed fruiting in October and November as well.<ref name="fsu"/>  
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It can spread vegetatively in a limited area, but it is dependent on sexual reproduction to colonize new areas.<ref name="newengland"/> Flowering occurs in the fall<ref name="wunderlin">Wunderlin, Richard P. and Bruce F. Hansen. Guide to the Vascular Plants of Florida. Second edition. 2003. University Press of Florida: Gainesville/Tallahassee/Tampa/Boca Raton/Pensacola/Orlando/Miami/Jacksonville/Ft. Myers. 295. Print.</ref>, and has been observed flowering in the months of October, November, and January with peak inflorescence in October.<ref name= "Panflora"> Nelson, G. PanFlora: Plant data for the eastern United States with emphasis on the Southeastern Coastal Plains, Florida, and the Florida Panhandle. www.gilnelson.com/PanFlora/ Accessed: 4 MAR 2019 </ref> It has been observed to fruit in October and November as well.<ref name="fsu"/>  
  
On the Wade Tract, flowering occurs at the end of the growing season, in the latter part of October and November, following spring fires. At this time, ''A. aromatica'' often is the most abundant and conspicuous flowering composite in the ground layer of mesic savanna. The white inflorescences are at "canopy" height and form flat platforms of flowers visited by numerous bees and other flying insects in the late fall. Flowering may occur sporadically in years between fires, but is most noticeable as highly synchronized flowering displays across mesic landscapes on the Wade Tract following spring fires.<ref name="platt"/>  
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On the Wade Tract, flowering occurs at the end of the growing season, in the latter part of October and November, following spring fires. At this time, ''A. aromatica'' often is the most abundant and conspicuous flowering composite in the ground layer of mesic savanna. The white inflorescences are at "canopy" height of the herbaceous vegetation and form flat platforms of flowers visited by numerous bees and other flying insects in the late fall. Flowering may occur sporadically in years between fires, but is most noticeable as highly synchronized flowering displays across mesic landscapes on the Wade Tract following spring fires.<ref name="platt"/>  
  
In north Florida, it has been observed to reproduce with ''A. juncunda''[http://coastalplainplants.org/wiki/index.php/Ageratina_jucunda] suggesting these species are possibly conspecific.<ref name="clewell">Clewell, A. F. and J. W. Wooten (1971). "A Revision of Ageratina (Compositae: Eupatorieae) from Eastern North America." Brittonia 23(2): 123-143.</ref>
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In north Florida, it has been observed to reproduce with ''A. juncunda''[http://coastalplainplants.org/wiki/index.php/Ageratina_jucunda], suggesting that these species are possibly conspecific.<ref name="clewell">Clewell, A. F. and J. W. Wooten (1971). "A Revision of Ageratina (Compositae: Eupatorieae) from Eastern North America." Brittonia 23(2): 123-143.</ref>
  
 
===Seed dispersal and germination===
 
===Seed dispersal and germination===

Revision as of 10:17, 23 August 2021

Ageratina aromatica
Ageratina aromatica gil.jpg
Photo taken by Gil Nelson
Scientific classification
Kingdom: Plantae
Division: Magnoliophyta - Flowering plants
Class: Magnoliopsida - Dicotyledons
Order: Asterales
Family: Asteraceae ⁄ Compositae
Genus: Ageratina
Species: A. aromatica
Binomial name
Ageratina aromatica
(L.) Spach
AGER AROM dist.jpg
Natural range of Ageratina aromatica from USDA NRCS Plants Database.

Common names: Lesser snakeroot; Wild hoarhound; Small-leaved white snakeroot

Taxonomic notes

Synonyms: Eupatorium aromaticum Linnaeus; Eupatorium latidens Small.[1]

Varieties: A. aromatica var. aromatica (L.) Spach; A. aromatica var. incisa (Gray) C.F. Reed.[1]

The genus name Ageratina comes from the Greek word "agera" which means un-aging, not growing old in reference to the longevity of the flowers. The specific epithet comes from the Greek word "aroma" meaning spice seasoning.[2]

Description

A description of Ageratina aromatica is provided in The Flora of North America.

The lifepans of individual plants within the Wade Tract old-growth pine savanna in southern Georgia, based on multiple years of data from permanent plots, is several years, with genets that become established and flower persisting through 1 - several fires.[3] No genet has been observed to survive more than about 4-5 years.[4]

Ageratina aromatica genets commonly are comprised of a single ramet or a few ramets within a few centimeters of each other, especially after fires have top-killed existing ramets. Underground the roots radiate from the base of the ramet stem and are thickened relative to most fibrous roots of composites. Below ground rhizomes often are not present, but if present are short. The compact growth form of flowering snakeroots in the old-growth pine savanna, consisting of one or a few closely spaced above-ground ramets, may differ from growth forms of genets in more open secondary forests.[3]

It can be distinguished from the closely related A. altissima[1] by having smaller, thicker, and less sharply toothed leaves on shorter petioles, smaller stature, smaller flower heads, and thicker roots, and shorter, firmer pubescence.[4]

Distribution

It is found from eastern Louisiana and Mississippi eastward to the Atlantic coast and northward to Pennsylvania and Massachusetts.[5] It is regionally rare in New England. In Massachusetts and Connecticut it is listed as endangered (S1) and in Rhode Island is historical only (SH).[4]

Ageratina aromatica is among the 20 most frequent ground layer plant species in mesic old-growth pine savanna on the Wade Tract, occurring in almost half the permanent plots in the ongoing long-term study.[3]

Ecology

Habitat

A. aromatica can be found in a variety of longleaf pine communities, mixed pine-hardwood forests, open oak woods, live oak woodlands, upland woodlands, and rolling red hills. It can also be found in disturbed habitat such as roadsides, along fences, and on the edges of fields.[6]

On the Wade Tract, A. aromatica occurs in open pine savanna along mid and lower mesic slopes, but tends to be absent from drier, sandy ridges. It often occurs in slightly disturbed areas of the Wade Tract, and it occurs in natural hardwood thickets as well.[3] Ageratina aromatica is considered a dominant plant species in post-agricultural longleaf pine savannas.[7] This species is observed in a range of light conditions, from open forest situations to semi-shaded and shady areas. In the ground layer of pine savannas at Girl Scout Camp Whispering Pines in Louisiana, A. aromatica was neither positive nor negatively associated with understory light levels, suggesting broad tolerance of light conditions.[8] Additionally, a study exploring longleaf pine patch dynamics found A. aromatica to be most strongly represented within stands of longleaf pine that are between 10-130 years of age.[9] A. aromatica occurs most frequently in moist sandy loam, dry sand, and areas of lime rock.[6] A. aromatica became absent in response to soil disturbance by military training in west Georgia. It has shown resistance to regrowth in reestablished pinelands that were disturbed by this activity.[10]

Ageratina aromatica is an indicator species for the North Florida Longleaf Woodlands and Clayhill Longleaf Woodlands community types as described in Carr et al. (2010).[11]

Associated species include Chamaecrista fasiculata, Eupatorium album, Helianthus angustifolius, Liatris graminifolia, Solidago odora, Sorghastrum nutans, Pinus palustris, Pinus echinata, Aristida beyrichiana, Quercus, Liatris, and Dicerandra species and others.[6]

Phenology

It can spread vegetatively in a limited area, but it is dependent on sexual reproduction to colonize new areas.[4] Flowering occurs in the fall[12], and has been observed flowering in the months of October, November, and January with peak inflorescence in October.[13] It has been observed to fruit in October and November as well.[6]

On the Wade Tract, flowering occurs at the end of the growing season, in the latter part of October and November, following spring fires. At this time, A. aromatica often is the most abundant and conspicuous flowering composite in the ground layer of mesic savanna. The white inflorescences are at "canopy" height of the herbaceous vegetation and form flat platforms of flowers visited by numerous bees and other flying insects in the late fall. Flowering may occur sporadically in years between fires, but is most noticeable as highly synchronized flowering displays across mesic landscapes on the Wade Tract following spring fires.[3]

In north Florida, it has been observed to reproduce with A. juncunda[2], suggesting that these species are possibly conspecific.[14]

Seed dispersal and germination

This species is thought to be dispersed by wind.[15]

On the Wade Tract, achenes are wind-dispersed in the late fall/early winter. The achenes are light, but the small pappus results in seeds that tend to fall within the vicinity of the parent plant. Whether a seed bank is present is not known, but if present, it is likely only to be comprised of short-lived seeds. Germination has been observed in burned areas during the early summer following the onset of summer rains. Seedlings sometime are numerous around established plants. Survival of seedlings is very low, but the seedlings appear to be shade tolerant and can persist under the shade of other ground-layer plants. Seedlings in plots on the Wade Tract have reached a size such that they flower within 2-3 years. Nonetheless, many juvenile plants survive for several years before being killed in fires without ever flowering. Populations of A. aromatica on the Wade Tract thus tend to be multi-sized, but the short lifespan results in fairly rapid turnover within small areas.[3]

Fire ecology

Ageratina aromatica is found in annually burned savannas and wet pinelands[6] as shown in the populations known to withstand repeated annual burns.[16][17] It is the common ground cover species of North Florida Longleaf Woodlands, which are dependent on fire.[18] This species requires full to partial sun, therefore forest maturation and canopy closure resulting from a lack of disturbance such as fire can shade out A. aromatica.[4]

The nature of the population dynamics of A. aromaticaon the Wade Tract suggests that this species should be sensitive to fire suppression and other disturbances that reduce numbers of established plants, but also capable of rapid recovery if some plants survive the disturbances.[3]

Conservation, cultivation, and restoration

In New England, it is threatened by fire suppression and lack of disturbance that allows for canopy closure and forest maturation, resulting in lack of sunlight needed for A. aromatica to prosper.[4] It is listed as endangered in the state of Massachusetts. [19]

This species should avoid soil disturbance by military training to conserve its presence in longleaf pine habitats.

Cultural use

Photo Gallery

References and notes

  1. 1.0 1.1 Weakley, A.S. 2015. Flora of the southern and mid-atlantic states. Working Draft of 21 May 2015. University of North Carolina at Chapel Hill, Chapel Hill, North Carolina.
  2. [[3]]Alabama Plants. Accessed: March 22, 2016
  3. 3.0 3.1 3.2 3.3 3.4 3.5 3.6 William J. Platt, Unpublished data from ongoing long-term study of ground layer vegetation on the Wade Tract
  4. 4.0 4.1 4.2 4.3 4.4 4.5 [[4]]New England Wild. Accessed: March 22, 2016
  5. Hall, David W. Illustrated Plants of Florida and the Coastal Plain: based on the collections of Leland and Lucy Baltzell. 1993. A Maupin House Book. Gainesville. 100. Print.
  6. 6.0 6.1 6.2 6.3 6.4 .Florida State University Robert K. Godfrey Herbarium database. URL: http://herbarium.bio.fsu.edu. Last accessed: June 2014. Collectors: Loran C. Anderson, Robert Blaisdell, Andre F. Clewell, William B. Fox, J. P. Gillespie, Robert K. Godfrey, C. Jackson, Gary R. Knight, R. Komarek, Robert Kral, Robert L. Lazor, Sidney McDaniel, Richard S. Mitchell, P. L. Redfearn Jr., V. I. Sullivan, Jean W. Wooten, and Geo. Wilder MacClendons. States and Counties: Florida: Bay, Calhoun, Escambia, Franklin, Gadsden, Gulf, Holmes, Jackson, Jefferson, Leon, Levy, Liberty, Madison, Okaloosa, Putnam, Santa Rosa, St. Johns, and Wakulla. Georgia: Grady.
  7. Ostertag, T. E. and K. M. Robertson (2007). A comparison of native versus old-field vegetation in upland pinelands managed with frequent fire, south Georgia, USA. Proceedings of the 23rd Tall Timbers Fire Ecology Conference: Fire in Grassland and Shrubland Ecosystems, Tallahassee, Tall Timbers Research Station.
  8. Platt, W.J., S.M. Carr, M. Reilly, and J. Fahr. 2006. Pine savanna overstorey influences on ground-cover biodiversity. Applied Vegetation Science 9:37-50.
  9. Mugnani et al. (2019). “Longleaf Pine Patch Dynamics Influence Ground-Layer Vegetation in Old-Growth Pine Savanna”.
  10. (2002). Understory vegetation indicators of anthropogenic disturbance in longleaf pine forests at Fort Benning, Georgia, USA. Ecological Indicators 1(3):155-170.
  11. Carr, S.C., K.M. Robertson, and R.K. Peet. 2010. A vegetation classification of fire-dependent pinelands of Florida. Castanea 75:153-189.
  12. Wunderlin, Richard P. and Bruce F. Hansen. Guide to the Vascular Plants of Florida. Second edition. 2003. University Press of Florida: Gainesville/Tallahassee/Tampa/Boca Raton/Pensacola/Orlando/Miami/Jacksonville/Ft. Myers. 295. Print.
  13. Nelson, G. PanFlora: Plant data for the eastern United States with emphasis on the Southeastern Coastal Plains, Florida, and the Florida Panhandle. www.gilnelson.com/PanFlora/ Accessed: 4 MAR 2019
  14. Clewell, A. F. and J. W. Wooten (1971). "A Revision of Ageratina (Compositae: Eupatorieae) from Eastern North America." Brittonia 23(2): 123-143.
  15. Kirkman, L. Katherine. Unpublished database of seed dispersal mode of plants found in Coastal Plain longleaf pine-grasslands of the Jones Ecological Research Center, Georgia.
  16. Robertson, K.M. Unpublished data collected from Pebble Hill Fire Plots, Pebble Hill Plantation, Thomasville, Georgia.
  17. Glitzenstein, J. S., D. R. Streng, R. E. Masters, K. M. Robertson and S. M. Hermann 2012. Fire-frequency effects on vegetation in north Florida pinelands: Another look at the long-term Stoddard Fire Research Plots at Tall Timbers Research Station. Forest Ecology and Management 264: 197-209.
  18. Carr, S. C., K. M. Robertson, et al. (2010). "A Vegetation Classification of Fire-Dependent Pinelands of Florida." Castanea 75(2): 153-189.
  19. USDA Plants Database URL: https://plants.usda.gov/core/profile?symbol=ANGE