Islands in the Sky: Treetop Biodiversity Exploration

And there it was, a gleaming, silvery to glittering gold and bluish iridescent, spherical spore case, spectral colors reminiscent of a rainbow, atop a stalk, hidden in the bark fissures of a living white oak tree at 60 to 80 feet (Figure 1)….

Figure 1. Diachea arboricola. Stalked fruiting body with iridescent colors.

These spore-filled myxomycete fruiting bodies had developed from a jelly-like protoplasmic mass (Figure 2) that had left behind a network of vein-like paired black tracks after crawling over the bark surface feeding on microorganisms (Figure 3). 

Figure 2. Diachea arboricola. Plasmodium developing on white filter paper in moist chamber culture. Note front feeding edge and network of veins trailing behind that leave plasmodial tracks.
Figure 3. Diachea arboricola. Network of plasmodial paired tracks in situ on tree canopy-collected bark.        

This myxomycete was barely visible to the eyes of undergraduate student Melissa Skrabal who had used the double rope climbing method to access the tree canopy (Figure 4; Kilgore et al, 2008). Her discovery upon closer microscopic examination of fruiting body structural features resulted in a set of unique characteristics (external colors, internal attachments of capillitial threads to a central columella, stalk crystals, and spore size and ornamentation, Figures 5, 6. 7) that represented a myxomycete species new to science, Diachea arboricola (Keller et al., 2004). Diachea (10 species) are all iridescent justifying the descriptive phrase “biological jewels of nature” (Keller and Everhart, 2010).

Figure 4. Melissa Skrabal observing and collecting white oak bark samples with plasmodial tracks and stalked sporangia of Diachea arboricola.
Figure 5. Diachea arboricola scanning electron micrographs. Profile of capillitial threads arising from tip of columella (central column) inside sporangium. 
Figure 7. Diachea arboricola scanning electron micrographs. Unique individual calcium carbonate rhombohedron crystal from stalk.
Figure 7. Diachea arboricola scanning electron micrographs. Fractured stalk showing internal crystals.

This first tree canopy research study project was part of the All Taxa Biodiversity Inventory (ATBI) conducted in the Great Smoky Mountains National Park (GSMNP) sponsored by a non-profit organization Discover Life in America (Figures 8, 9; Keller, 2004). A recent publication (Keller and Barfield, 2017) documents the history, geographical features, establishment of the GSMNP, and ATBI as part of the 100th anniversary of the National Park Service.

Figure 8. Map of GSMNP with points of interest.
Figure 9. Scenic panoramic view of the Smoky Mountains. Note the rounded summits shaped after 380 million years of climatic and geological time.

Canopy research in GSMNP included taxonomic groups represented by bryophytes, ferns, fungi, lichens, myxomycetes, myxobacteria, slugs, snails, and tardigrades (Figures 10–13). The myriad of life forms that are adapted to living in the tree canopy represent one of the last frontiers of exploration on the planet earth.

Figure 10. Tree canopy fern, Polypodium appalachianum, showing fertile fronds with mature sori (red dots) and immature sori (pale dots) on underside. Note ”canopy soil” underneath the fern.
Figure 11. Colorful coral mushroom, Clavaria zollingeri, growing among mosses and leaf litter trailside.
Figure 12. Rare crustose lichen, Gomphillus americanus, a new record for the park. Note the unusual stalked peltate hyphophores showing conspicuous starburst tops with sharply pointed margins.
Figure 13. Tardigrade Echiniscus viridissimus light photomicrograph showing armored dorsal plates and bright green pigmentation.

Readers interested in more details related to this study can learn more by clicking this link: http://www.fungimag.com/summer-2017-articles/Smokey%2044-64_LR.pdf

References

Keller, H.W. 2004. Tree canopy biodiversity: student research experiences in Great Smoky Mountains National Park. Systematics and Geography of Plants 74: 47–65.

Keller, H.W., and S.E. Everhart. 2010. Importance of myxomycetes in biological research and teaching. Fungi 3 (1): 29–43.

KellerH.Wand Keri M. Barfield. 2017. Great Smoky Mountains National Park: The People’s Park. Fungi 10 (2): 44–64.

Kilgore, C.M., H.W. Keller, S.E. Everhart, A.R. Scarborough, K.L. Snell, M.S. Skrabal, C. Pottorff, and J.S. Ely. 2008. Research and student experiences using the Doubled Rope Climbing Method. Journal of the Botanical Research Institute of Texas 2 (2): 1309–1336.

Keller, H.W., M. Skrabal, U.H. Eliasson, and T.W. Gaither. 2004. Tree canopy biodiversity in the Great Smoky Mountains National Park: ecological and developmental observations of a new myxomycete species of DiacheaMycologia 96: 537–547.

Related Articles

Collections Lens

Sean Lahmeyer of the Huntington Herbarium

As part of the Library’s Collection Lens series, BRIT Librarian, Brandy Watts, interviews Sean Lahmeyer of the Huntington Herbarium who discusses the history of the collection and its growth through the years.

Read More »
graphic of DNA double helix
BRIT Research

National DNA Day

A Peek Inside Sumner Lab on National DNA Day Lab Volunteer, Jerrod Stone, shares his experience and the latest projects April 26th is National DNA

Read More »
Botany Stories

Pondering Poaceae Across Texas

Dan Caudle discusses his interest in grasses and grasslands, giving particular attention to his work with Meredith Ellis, a young rancher and committed conservationist in Cooke County, Texas.

Read More »