Spatial patterning and floral synchrony among trillium populations with contrasting histories of herbivory.

Christopher R Webster,Michael A Jenkins,Aaron J Poznanovic

doi:10.7717/peerj.782

Abstract

We investigated the spatial patterning and floral synchrony within and among populations of a non-clonal, forest understory herb, Trillium catesbaei. Two populations of T. catesbaei within Great Smoky Mountains National Park were monitored for five years: Cades Cove (high deer abundance) and Whiteoak Sink (low deer abundance). All individuals within each population were mapped during year one and five. Only flowering and single-leaf juveniles were mapped during intervening years. Greater distances between flowering plants (plants currently in flower) and substantially lower population densities and smaller patch sizes were observed at Cades Cove versus Whiteoak Sink. However, with the exception of flowering plants, contrasting histories of herbivory did not appear to fundamentally alter the spatial patterning of the T. catesbaei population at Cades Cove, an area with a long and well-documented history of deer overabundance. Regardless of browse history, non-flowering life stages were significantly clustered at all spatial scales examined. Flowering plants were clustered in all years at Whiteoak Sink, but more often randomly distributed at Cades Cove, possibly as a result of their lower abundance. Between years, however, there was a positive spatial association between the locations of flowering plants at both sites. Flowering rate was synchronous between sites, but lagged a year behind favorable spring growing conditions, which likely allowed plants to allocate photosynthate from a favorable year towards flowering the subsequent year. Collectively, our results suggest that chronically high levels of herbivory may be associated with spatial patterning of flowering within populations of a non-clonal plant. They also highlight the persistence of underlying spatial patterns, as evidenced by high levels of spatial clustering among non-flowering individuals, and the pervasive, although muted in a population subjected to chronic herbivory, influence of precipitation and temperature on flowering in long-lived forest herbs.

Highlights

Spatial relationships within ecological communities increasingly are a focus of theoretical modelling efforts and empirical studies (Bacaro & Ricotta, 2007; Cain & Damman, 1997; Perry et al, 2008; Reine, Chocarro & Fillat, 2006; Zhang et al, 2010)
Even at peak flowering in 2013, the mean distance between flowering plants at Cade Cove was an order of magnitude greater than that observed at Whiteoak Sink (1.64 ± 2.35 m versus 0.39 ± 0.34 m; Table 4)
It has long been recognized that high levels of white-tailed deer herbivory alter the abundance of life-stages within Trillium populations

Summary

Introduction

Spatial relationships within ecological communities increasingly are a focus of theoretical modelling efforts and empirical studies (Bacaro & Ricotta, 2007; Cain & Damman, 1997; Perry et al, 2008; Reine, Chocarro & Fillat, 2006; Zhang et al, 2010). The spatial arrangement of individuals influences numerous density- and distance-dependent processes including pollination (Ison et al, 2014; Knight, 2003a; Morgan, Wilson & Knight, 2005; Steven et al, 2003), seed dispersal (Helenurm & Barrett, 1987), seedling recruitment and survival (Feldman & Morris, 2011; Tomimatsu & Ohara, 2002), and interspecific competition (Gustafsson & Ehrlen, 2003) Disturbances, such as herbivory, that have the potential to alter both the abundance and the spatial patterning of individuals (e.g., plants in flower) within populations may have cascading effects on vital rates (e.g., reproduction and seed dispersal) and population persistence (Knight, 2004; Thomson et al, 1996). The direct effects of herbivory vary with palatability, growth form, and resource allocation patterns (Whigham & Chapa, 1999; Wiegmann & Waller, 2006)

Methods

Results

Conclusion