Long-term exclusion of invasive ungulates alters tree recruitment and functional traits but not total forest carbon

Kara Allen; Peter J Bellingham; Sarah J Richardson; Robert B Allen; Larry E Burrows; Fiona E Carswell; Sean W Husheer; Mark G St John; Duane A Peltzer

doi:10.1002/eap.2836

Long-term exclusion of invasive ungulates alters tree recruitment and functional traits but not total forest carbon

Ecol Appl. 2023 Jun;33(4):e2836. doi: 10.1002/eap.2836. Epub 2023 Mar 28.

Authors

Kara Allen¹, Peter J Bellingham^{1

2}, Sarah J Richardson¹, Robert B Allen³, Larry E Burrows¹, Fiona E Carswell¹, Sean W Husheer⁴, Mark G St John⁵, Duane A Peltzer¹

Affiliations

¹ Manaaki Whenua - Landcare Research, Lincoln, Canterbury, New Zealand.
² School of Biological Sciences, University of Auckland, Auckland, New Zealand.
³ Independent Researcher, 8 Roblyn Place, Lincoln, Canterbury, New Zealand.
⁴ New Zealand Forest Surveys Limited, Hastings Aerodrome, Hawkes Bay, New Zealand.
⁵ Agriculture and Agri-Food Canada, Ottawa Research and Development Centre, Ottawa, Ontario, Canada.

PMID: 36890426
DOI: 10.1002/eap.2836

Abstract

Forests are major carbon (C) sinks, but their ability to sequester C and thus mitigate climate change, varies with the environment, disturbance regime, and biotic interactions. Herbivory by invasive, nonnative ungulates can have profound ecosystem effects, yet its consequences for forest C stocks remain poorly understood. We determined the impact of invasive ungulates on C pools, both above- and belowground (to 30 cm), and on forest structure and diversity using 26 paired long-term (>20 years) ungulate exclosures and adjacent unfenced control plots located in native temperate rainforests across New Zealand, spanning 36-41° S. Total ecosystem C was similar between ungulate exclosure (299.93 ± 25.94 Mg C ha^-1 ) and unfenced control (324.60 ± 38.39 Mg C ha^-1 ) plots. Most (60%) variation in total ecosystem C was explained by the biomass of the largest tree (mean diameter at breast height [dbh]: 88 cm) within each plot. Ungulate exclusion increased the abundance and diversity of saplings and small trees (dbh ≥2.5, <10 cm) compared with unfenced controls, but these accounted for ~5% of total ecosystem C, demonstrating that a few, large trees dominate the total forest ecosystem C but are unaffected by invasive ungulates at a timescale of 20-50 years. However, changes in understory C pools, species composition, and functional diversity did occur following long-term ungulate exclusion. Our findings suggest that, although the removal of invasive herbivores may not affect total forest C at the decadal scale, major shifts in the diversity and composition of regenerating species will have longer term consequences for ecosystem processes and forest C.

Keywords: biological invasion; carbon cycle; climate change mitigation; exclosure treatment; forest ecosystem processes; functional dispersion; large herbivore effects in forests; long-term permanent plot network; nonnative species' impacts; plant population responses.

Publication types

Research Support, Non-U.S. Gov't

MeSH terms

Animals
Carbon
Deer*
Ecosystem
Forests
Trees*

Substances

Carbon