Difference between revisions of "Asclepias humistrata"

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The root system of ''Asclepias humistrata'' includes stem tubers which store non-structural carbohydrates (NSC) important for both resprouting following fire and persisting during long periods of fire exclusion.<ref name="Diaz"> Diaz-Toribio, M.H. and F. E. Putz 2021. Underground carbohydrate stores and storage organs in fire-maintained longleaf pine savannas in Florida, USA. American Journal of Botany 108: 432-442.</ref> Diaz-Toribio and Putz (2021) recorded this species to have an NSC concentration of 171 mg/g (ranking 28 out of 100 species studied) and water content of 62.4% (ranking 55 out of 100 species studied).<ref name = "Diaz"/>
 
The root system of ''Asclepias humistrata'' includes stem tubers which store non-structural carbohydrates (NSC) important for both resprouting following fire and persisting during long periods of fire exclusion.<ref name="Diaz"> Diaz-Toribio, M.H. and F. E. Putz 2021. Underground carbohydrate stores and storage organs in fire-maintained longleaf pine savannas in Florida, USA. American Journal of Botany 108: 432-442.</ref> Diaz-Toribio and Putz (2021) recorded this species to have an NSC concentration of 171 mg/g (ranking 28 out of 100 species studied) and water content of 62.4% (ranking 55 out of 100 species studied).<ref name = "Diaz"/>
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According to Diaz-Torbio and Putz (2021), ''Asclepais humistrata'' has stem tubers with a below-ground to above-ground biomass ratio of 1.205 and nonstructural carbohydrate concentration of 171 mg g<sup>-1</sup>.<ref>Diaz-Torbio, M. H. and F. E. Putz. 2021. Underground carbohydrate stores and storage organs in fire-maintained longleaf pine savannas in Florida, USA. American Journal of Botany 108(3):432-442.</ref>
  
 
==Distribution==
 
==Distribution==
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In the Coastal Plain in Florida and Georgia, ''A. humistrata'' can occur in scrub oak sand ridges, longleaf pine-scrub oak ridges, pine-palmetto thickets, turkey oak scrubs, low sand dunes, and mixed pine hardwood associations. It can occur in disturbed areas such as sandy fallow fields and roadsides. Soil types include loamy sand and coarse sand.<ref name="fsu"/>
 
In the Coastal Plain in Florida and Georgia, ''A. humistrata'' can occur in scrub oak sand ridges, longleaf pine-scrub oak ridges, pine-palmetto thickets, turkey oak scrubs, low sand dunes, and mixed pine hardwood associations. It can occur in disturbed areas such as sandy fallow fields and roadsides. Soil types include loamy sand and coarse sand.<ref name="fsu"/>
  
Associated species include ''[[Coreopsis basalis]], [[Hymenopappus scabiosaeus]], Liatris, Panicum, [[Leptoloma cognatum]], [[Quercus laevis]], [[Quercus incana]], [[Quercus geminata]], [[Aristida stricta]], [[Vaccinium stamineum]], [[Vaccinium myrsinites]]'' and ''[[Licania michauxii]]''. <ref name="fsu">Florida State University Robert K. Godfrey Herbarium database. URL: http://herbarium.bio.fsu.edu. Last accessed: November 2015. Collectors: Loran C. Anderson, M. Boothe, Edwin L. Bridges, Richard Carter, Jack P. Davis, Elmer, J.P. Gillespie, Robert K. Godfrey, R.D. Houk, Lisa Keppner, Gary R. Knight, Robert Kral , H. Larry, Robert L. Lazor, Karen MacClendon, Sidney McDaniel, R.A. Norris, Steve L. Orzell, C. Prichard, Grady W. Reinert, Annie Schmidt, E. Stipling, D.B. Ward, S.J. Ward, Rodie White, Mary Margaret Williams, Jean W. Wooten. States and Counties: Florida: Baker, Bay, Calhoun, Clay, Dixie, Escambia, Franklin, Gadsden, Gilchrist, Hamilton, Jackson, Leon, Levy, Liberty, Marion, Nassau, Okaloosa, Pasco, Polk, Santa Rosa, Taylor, Volusia, Wakulla, Washington. Georgia: Grady. Compiled by Tall Timbers Research Station and Land Conservancy.</ref>
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Associated species include ''Coreopsis basalis, Hymenopappus scabiosaeus, Liatris, Panicum, Leptoloma cognatum, [[Quercus laevis]], [[Quercus incana]], [[Quercus geminata]], [[Aristida stricta]], [[Vaccinium stamineum]], [[Vaccinium myrsinites]]'' and ''[[Licania michauxii]]''. <ref name="fsu">Florida State University Robert K. Godfrey Herbarium database. URL: http://herbarium.bio.fsu.edu. Last accessed: November 2015. Collectors: Loran C. Anderson, M. Boothe, Edwin L. Bridges, Richard Carter, Jack P. Davis, Elmer, J.P. Gillespie, Robert K. Godfrey, R.D. Houk, Lisa Keppner, Gary R. Knight, Robert Kral , H. Larry, Robert L. Lazor, Karen MacClendon, Sidney McDaniel, R.A. Norris, Steve L. Orzell, C. Prichard, Grady W. Reinert, Annie Schmidt, E. Stipling, D.B. Ward, S.J. Ward, Rodie White, Mary Margaret Williams, Jean W. Wooten. States and Counties: Florida: Baker, Bay, Calhoun, Clay, Dixie, Escambia, Franklin, Gadsden, Gilchrist, Hamilton, Jackson, Leon, Levy, Liberty, Marion, Nassau, Okaloosa, Pasco, Polk, Santa Rosa, Taylor, Volusia, Wakulla, Washington. Georgia: Grady. Compiled by Tall Timbers Research Station and Land Conservancy.</ref>
  
===Phenology===<!--Timing off flowering, fruiting, seed dispersal, and environmental triggers.  Cite PanFlora website if appropriate: http://www.gilnelson.com/PanFlora/ -->  
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===Phenology===<!--Timing off flowering, fruiting, and environmental triggers.  Cite PanFlora website if appropriate: http://www.gilnelson.com/PanFlora/ -->  
 
''Asclepias humistrata'' flowers March through October, with peak inflorescence in April.<ref>Nelson, G.  [http://www.gilnelson.com/ 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: 19 MAY 2021</ref> Fruits April through October.<ref name="fsu"/>
 
''Asclepias humistrata'' flowers March through October, with peak inflorescence in April.<ref>Nelson, G.  [http://www.gilnelson.com/ 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: 19 MAY 2021</ref> Fruits April through October.<ref name="fsu"/>
  
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Pollination of ''Asclepias'' is unusual. Pollen is contained in sacs (pollinia) located in the slits of the flower (stigmatic slits), when a pollinator walks across the flower head, these sacs attach to the pollinator and disperses on to another plant when the pollinator lands and walks.<ref name="fnps"/> There is no specialist insect pollinator.<ref name="xerces">[[http://www.xerces.org/wp-content/uploads/2014/06/Milkweeds_XerSoc_june2014.pdf]]Xerces Society. Accessed: March 30, 2016</ref>
 
Pollination of ''Asclepias'' is unusual. Pollen is contained in sacs (pollinia) located in the slits of the flower (stigmatic slits), when a pollinator walks across the flower head, these sacs attach to the pollinator and disperses on to another plant when the pollinator lands and walks.<ref name="fnps"/> There is no specialist insect pollinator.<ref name="xerces">[[http://www.xerces.org/wp-content/uploads/2014/06/Milkweeds_XerSoc_june2014.pdf]]Xerces Society. Accessed: March 30, 2016</ref>
  
===Use by animals===<!--Herbivory, granivory, insect hosting, etc.-->
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===Herbivory and toxicology===
 
This species is an important host plant to the monarch butterfly (''Danaus plexippus'') and the Queen butterfly (''Danaus gilippus''). Monarch larva feed upon the milkweed plants, ingesting the plant defense chemicals (cardenolids). Monarch caterpillars have evolved the ability to circumvent latex defence of milkweeds and appropriate the cardenolids. However, they can only tolerate a certain level of the cardiac glycoside chemicals, larval survival is negatively correlated with the concentration of cardiac glycosides in the leaves. Many larvae will die because they can become adhered by the latex to the leaf surface.<ref name="zalucki">Zalucki, M. P., L. P. Brower, et al. (2001). "Detrimental effects of latex and cardiac glycosides on survival and growth of first-instar monarch butterfly larvae Danaus plexippus feeding on the sandhill milkweed Asclepias humistrata." ECOLOGICAL ENTOMOLOGY 26(2): 212-224.</ref> Cohen and Brower (1982) observed that more eggs are laid on larger plants, however, larval success was greatest on smaller plants. There is a positive correlation between the number of eggs on a plant and total leaf area.<ref name="cohen">Cohen, J. A. and L. P. Brower (1982). "Oviposition and Larval Success of Wild Monarch Butterflies (Lepidoptera: Danaidae) in Relation to Host Plant Size and Cardenolide Concentration." Journal of the Kansas Entomological Society 55(2): 343-348.</ref>
 
This species is an important host plant to the monarch butterfly (''Danaus plexippus'') and the Queen butterfly (''Danaus gilippus''). Monarch larva feed upon the milkweed plants, ingesting the plant defense chemicals (cardenolids). Monarch caterpillars have evolved the ability to circumvent latex defence of milkweeds and appropriate the cardenolids. However, they can only tolerate a certain level of the cardiac glycoside chemicals, larval survival is negatively correlated with the concentration of cardiac glycosides in the leaves. Many larvae will die because they can become adhered by the latex to the leaf surface.<ref name="zalucki">Zalucki, M. P., L. P. Brower, et al. (2001). "Detrimental effects of latex and cardiac glycosides on survival and growth of first-instar monarch butterfly larvae Danaus plexippus feeding on the sandhill milkweed Asclepias humistrata." ECOLOGICAL ENTOMOLOGY 26(2): 212-224.</ref> Cohen and Brower (1982) observed that more eggs are laid on larger plants, however, larval success was greatest on smaller plants. There is a positive correlation between the number of eggs on a plant and total leaf area.<ref name="cohen">Cohen, J. A. and L. P. Brower (1982). "Oviposition and Larval Success of Wild Monarch Butterflies (Lepidoptera: Danaidae) in Relation to Host Plant Size and Cardenolide Concentration." Journal of the Kansas Entomological Society 55(2): 343-348.</ref>
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<!--===Diseases and parasites===-->
 
<!--===Diseases and parasites===-->
  

Latest revision as of 11:20, 2 July 2024

Asclepias humistrata
Milk 10 - modified.jpg
Asclepias humistrata
Scientific classification
Kingdom: Plantae
Division: Magnoliophyta - Flowering plants
Class: Dicots
Order: Gentianales
Family: Apocynaceae
Genus: Asclepias
Species: A. humistrata
Binomial name
Asclepias humistrata
Walter
A. humistrata Map.PNG
Natural range of Asclepias humistrata from USDA NRCS [1].

Common names: Pinewoods milkweed; Sandhill milkweed

Taxonomic notes

Asclepias is named for Asklepio, the Greek god of medicine and healing. Humistrata is derived from the Latin word 'humis' meaning ground and 'sternere' to spread.[1]

Synonyms: none.[2]

Varieties: none.[2]

Description

In general, with the Asclepias genus, these plants are perennial herbs containing milky sap. The stems are erect, spreading or decumbent and usually are simple and often solitary. The leaves are opposite to subopposite, are sometimes whorled, and rarely alternate. The corolla lobes are reflexed and are rarely erect or spreading. The filaments are elaborate five hoods forming a corona around the gynosteguim. The corona horns are present in most species.[3]

More specifically, for A. humistrata, the stems are glabrous, simple, stout, and rarely solitary; they spread ascendingly, and grow 20 - 70 cm tall. The leaves are opposite, about 5 - 8 pairs, ovate in shape, 6 - 10 cm long and 4.5 - 8.5 cm wide. The leaves are widely acute to obtuse, the margins are flat, auriculate, more or less amplexicaul, subsucculent, glaucous, the veins are pink to lavender in color, and are sessile. There are 2 - 5 or more umbels beginning from the upper 2 - 5 nodes, and are 3 - 5 cm wide. The flower is pale rose or lavender in color, the lobes are reflexed, and are 5 - 6.5 mm long. The corona is 3 - 5 mm in diameter. The horns are shorter than the hood. The follicles are erect and are 9 - 14 cm long, 1.3 - 1.8 cm broad.[3]

The root system of Asclepias humistrata includes stem tubers which store non-structural carbohydrates (NSC) important for both resprouting following fire and persisting during long periods of fire exclusion.[4] Diaz-Toribio and Putz (2021) recorded this species to have an NSC concentration of 171 mg/g (ranking 28 out of 100 species studied) and water content of 62.4% (ranking 55 out of 100 species studied).[4]

According to Diaz-Torbio and Putz (2021), Asclepais humistrata has stem tubers with a below-ground to above-ground biomass ratio of 1.205 and nonstructural carbohydrate concentration of 171 mg g-1.[5]

Distribution

Endemic to the southeastern U.S.: North Carolina south to Florida and west to Louisiana.[1]

Ecology

Habitat

In the Coastal Plain in Florida and Georgia, A. humistrata can occur in scrub oak sand ridges, longleaf pine-scrub oak ridges, pine-palmetto thickets, turkey oak scrubs, low sand dunes, and mixed pine hardwood associations. It can occur in disturbed areas such as sandy fallow fields and roadsides. Soil types include loamy sand and coarse sand.[6]

Associated species include Coreopsis basalis, Hymenopappus scabiosaeus, Liatris, Panicum, Leptoloma cognatum, Quercus laevis, Quercus incana, Quercus geminata, Aristida stricta, Vaccinium stamineum, Vaccinium myrsinites and Licania michauxii. [6]

Phenology

Asclepias humistrata flowers March through October, with peak inflorescence in April.[7] Fruits April through October.[6]

Seed dispersal

The fruit dries and splits open, releasing seeds with a white, silky pappus that allows for wind dispersal.[1] The species is thought to be dispersed by wind.[8]

Seed bank and germination

Germination is delayed until late winter or spring when seeds have after-ripened and environmental temperatures increase to match seeds germination requirements.[9]

Fire ecology

It has been observed growing in burned over, longleaf pine forests.[6] A long, deep, thick taproot aids in rapid recovery after fire.[1]

Pollination

Pollination of Asclepias is unusual. Pollen is contained in sacs (pollinia) located in the slits of the flower (stigmatic slits), when a pollinator walks across the flower head, these sacs attach to the pollinator and disperses on to another plant when the pollinator lands and walks.[1] There is no specialist insect pollinator.[9]

Herbivory and toxicology

This species is an important host plant to the monarch butterfly (Danaus plexippus) and the Queen butterfly (Danaus gilippus). Monarch larva feed upon the milkweed plants, ingesting the plant defense chemicals (cardenolids). Monarch caterpillars have evolved the ability to circumvent latex defence of milkweeds and appropriate the cardenolids. However, they can only tolerate a certain level of the cardiac glycoside chemicals, larval survival is negatively correlated with the concentration of cardiac glycosides in the leaves. Many larvae will die because they can become adhered by the latex to the leaf surface.[10] Cohen and Brower (1982) observed that more eggs are laid on larger plants, however, larval success was greatest on smaller plants. There is a positive correlation between the number of eggs on a plant and total leaf area.[11]


Conservation, cultivation, and restoration

Cultural use

Photo Gallery

References and notes

  1. 1.0 1.1 1.2 1.3 1.4 [[2]]Florida Native Plant Society. Accessed: March 30, 2016
  2. 2.0 2.1 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.
  3. 3.0 3.1 Radford, Albert E., Harry E. Ahles, and C. Ritchie Bell. Manual of the Vascular Flora of the Carolinas. 1964, 1968. The University of North Carolina Press. 848-852. Print.
  4. 4.0 4.1 Diaz-Toribio, M.H. and F. E. Putz 2021. Underground carbohydrate stores and storage organs in fire-maintained longleaf pine savannas in Florida, USA. American Journal of Botany 108: 432-442.
  5. Diaz-Torbio, M. H. and F. E. Putz. 2021. Underground carbohydrate stores and storage organs in fire-maintained longleaf pine savannas in Florida, USA. American Journal of Botany 108(3):432-442.
  6. 6.0 6.1 6.2 6.3 Florida State University Robert K. Godfrey Herbarium database. URL: http://herbarium.bio.fsu.edu. Last accessed: November 2015. Collectors: Loran C. Anderson, M. Boothe, Edwin L. Bridges, Richard Carter, Jack P. Davis, Elmer, J.P. Gillespie, Robert K. Godfrey, R.D. Houk, Lisa Keppner, Gary R. Knight, Robert Kral , H. Larry, Robert L. Lazor, Karen MacClendon, Sidney McDaniel, R.A. Norris, Steve L. Orzell, C. Prichard, Grady W. Reinert, Annie Schmidt, E. Stipling, D.B. Ward, S.J. Ward, Rodie White, Mary Margaret Williams, Jean W. Wooten. States and Counties: Florida: Baker, Bay, Calhoun, Clay, Dixie, Escambia, Franklin, Gadsden, Gilchrist, Hamilton, Jackson, Leon, Levy, Liberty, Marion, Nassau, Okaloosa, Pasco, Polk, Santa Rosa, Taylor, Volusia, Wakulla, Washington. Georgia: Grady. Compiled by Tall Timbers Research Station and Land Conservancy.
  7. 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: 19 MAY 2021
  8. 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.
  9. 9.0 9.1 [[3]]Xerces Society. Accessed: March 30, 2016
  10. Zalucki, M. P., L. P. Brower, et al. (2001). "Detrimental effects of latex and cardiac glycosides on survival and growth of first-instar monarch butterfly larvae Danaus plexippus feeding on the sandhill milkweed Asclepias humistrata." ECOLOGICAL ENTOMOLOGY 26(2): 212-224.
  11. Cohen, J. A. and L. P. Brower (1982). "Oviposition and Larval Success of Wild Monarch Butterflies (Lepidoptera: Danaidae) in Relation to Host Plant Size and Cardenolide Concentration." Journal of the Kansas Entomological Society 55(2): 343-348.