Endozoochory of Chrysobalanus icaco (Cocoplum) by Gopherus polyphemus (Gopher Tortoise) facilitates rapid germination and colonization in a suburban nature preserve

Carolyn J Hanish; Sebastian Velez; Jon A Moore; Corey Devin Anderson

doi:10.1093/aobpla/plaa024

Endozoochory of Chrysobalanus icaco (Cocoplum) by Gopherus polyphemus (Gopher Tortoise) facilitates rapid germination and colonization in a suburban nature preserve

AoB Plants. 2020 Jun 19;12(4):plaa024. doi: 10.1093/aobpla/plaa024. eCollection 2020 Aug.

Authors

Carolyn J Hanish^{1

2}, Sebastian Velez^{1

3}, Jon A Moore⁴, Corey Devin Anderson⁵

Affiliations

¹ Department of Biological Sciences, Florida Atlantic University, Boca Raton, FL, USA.
² School of Veterinary Medicine and Biomedical Sciences, University of Nebraska-Lincoln; Lincoln, NE, USA.
³ NOAA Office of Law Enforcement, Silver Spring, MD, USA.
⁴ Wilkes Honors College, Florida Atlantic University, Jupiter, FL, USA.
⁵ Department of Biology, Valdosta State University, Valdosta, GA, USA.

Abstract

Some large-seeded plants lack effective seed dispersal agents when they are introduced as ornamental plants to new areas, but can rapidly colonize a landscape if seed dispersal functions are restored. We examined whether Gopherus polyphemus (Gopher Tortoise) facilitated the spread of Chrysobalanus icaco (Cocoplum; Chrysobalanaceae) over a 14-year period in a suburban nature preserve (in Jupiter, FL, USA) by: (i) comparing germination patterns among gut-passed, hand-depulped and whole fruit treatments, and (ii) testing hypotheses about environmental predictors of the spatial distribution of C. icaco, including information about G. polyphemus movement pathways and burrow locations. While we did not find a significant difference in the total proportion of C. icaco seeds that germinated in each treatment, time to event analysis revealed that seeds that were found in faeces germinated significantly earlier than seeds that were hand-depulped or that were planted as whole fruits, supporting a lone scarification effect. Point process modeling revealed that the density of C. icaco bushes was higher near G. polyphemus movement pathways and was lower inside Serenoa repens (Saw Palmetto) patches, supporting a positive effect of tortoise movement patterns on plant distributions. The density of C. icaco increased from west to east, consistent with westward dispersal from the four founder bushes on the east side of the study area. After removal of outliers, we also detected a negative association between C. icaco spatial density and G. polyphemus burrow density that was presumably explained by the fact that seeds defecated deep within burrows were unlikely to germinate and establish without secondary movement. The results suggest that G. polyphemus contributed to the rapid dispersal of C. icaco by scatter dispersal of seeds (via faeces) in areas where tortoises were active and that movement pathways provided suitable conditions for colonization. The spread of C. icaco by G. polyphemus over a relatively short period of time provides a valuable window into the earliest stages of the colonization process and further supports the role of Chelonians as effective seed dispersal agents for large-seeded plants.

Keywords: Burrow; Chyrsobalanaceae; point pattern analysis; point process model; reptile seed dispersal; scarification; time to event analysis.