Multiple components of plant diversity loss determine herbivore phylogenetic diversity in a subtropical forest experiment

Ming‐Qiang Wang,Douglas Chesters,Chun‐Sheng Wu,Peng‐Fei Guo,Jing‐Ting Chen,Werner Härdtle,Keping Ma,Chao‐Dong Zhu,Goddert Von Oheimb,Andreas Schuldt,Helge Bruelheide,Qing‐Song Zhou,Nai‐Li Zhang,Walter Durka,Stefan G Michalski,Perttu Anttonen,Bernhard Schmid,Yi Li

doi:10.1111/1365-2745.13273

Abstract

Abstract Plant diversity loss can alter higher trophic‐level communities via non‐random species interactions, which in turn may cascade to affect key ecosystem functions. These non‐random linkages might be best captured by patterns of phylogenetic diversity, which take into account co‐evolutionary dependencies. However, lack of adequate phylogenetic data of higher trophic levels hampers our mechanistic understanding of biodiversity relationships in species‐rich ecosystems. We used DNA barcoding to generate data on the phylogenetic diversity of lepidopteran caterpillars in a large‐scale forest biodiversity experiment in subtropical China. We analysed how different metrics of lepidopteran phylogenetic diversity (Faith's PD, MPD, MNTD) and taxonomic diversity were influenced by multiple components of tree diversity (taxonomic, functional, phylogenetic). Our data from six sampling periods represent 7,204 mitochondrial cytochrome c oxidase subunit I (COI) sequences of lepidopteran larvae, clustered into 461 molecular operational taxonomic units. Lepidopteran abundance, the effective number of species (irrespective of the focus on rare or common species) and Faith's PD and MPD (reflecting basal evolutionary splits), but not MNTD (reflecting recent evolutionary splits), significantly increased with experimentally manipulated tree species richness. Lepidopteran MNTD decreased with increasing tree MNTD. Path analyses showed that tree phylogenetic and functional diversity explained part, but not all of the effects of tree species richness on lepidopteran diversity. Importantly, tree diversity effects on lepidopteran diversity were to a large extent indirect, operating via changes in lepidopteran abundance. Synthesis. Our study shows that evolutionary dependencies determine the response of herbivore communities to changes in host plant diversity. Incorporating a wider range of diversity metrics both at the level of producers and consumers can thus help to develop a more comprehensive understanding of the functional consequences of biodiversity change across trophic levels. Moreover, the dependence of trophic linkages on herbivore abundances underlines the need to address the consequences of current declines in insect abundances for ecosystem structure and functioning.

Highlights

Global environmental change leads to increasing biodiversity loss, with consequences for the structure and functioning of ecosystems (Chapin et al, 2000; Kardol, Fanin, & Wardle, 2018)
| Journal of Ecolo gy 2707 forest ecosystem. It indicates that changes in both the taxonomic and phylogenetic diversity of the tree communities can be tracked in the associated herbivore communities when more basal splits in host and herbivore lineages are taken into account
The increase in the species richness of lepidopteran caterpillars with increasing tree species richness at the plot level is consistent with theoretical expectations, because forest plots with more tree species may support a higher abundance of consumers and provide more niche opportunities for herbivore species adapted to different environments or host plants (Peterson et al, 2011)

Summary

| INTRODUCTION

Global environmental change leads to increasing biodiversity loss, with consequences for the structure and functioning of ecosystems (Chapin et al, 2000; Kardol, Fanin, & Wardle, 2018). Previous studies have shown the important role of plant diversity and the consequences of the loss of plant diversity for key ecosystem functions, such as primary productivity and nutrient cycling (Cardinale et al, 2012; Tilman, Isbell, & Cowles, 2014) These studies have demonstrated that changes in plant diversity can cascade up the food web to affect the abundance and species richness of higher trophic levels (Giling et al, 2019; Gossner et al, 2016; Haddad, Crutsinger, Gross, Haarstad, & Tilman, 2011; Scherber et al, 2010). (b) the strength of these relationships will depend on the metric of phylogenetic diversity and their dependence on the timing and overall number of evolutionary splits in the lepidopteran phylogeny

| MATERIALS AND METHODS

Findings

| DISCUSSION