Data from: Developmental constraints and resource environment shape early emergence and investment in spines in saplings
Armani, Mohammed; Charles-Dominique, Tristan; E. Barton, Kasey; W. Tomlinson, Kyle (2019), Data from: Developmental constraints and resource environment shape early emergence and investment in spines in saplings, Dryad, Dataset, https://doi.org/10.5061/dryad.nk98sf7ph
Herbivory by large mammals imposes a critical recruitment bottleneck on plants in many systems. Spines defend plants against large herbivores and how early they emerge in saplings may be one of the strongest predictors of sapling survival in herbivore-rich environments. Yet little effort has been directed at understanding the variability in spine emergence across saplings.
We present a multi-species study examining whether and how sapling size,spine type and species’ environmental niche (light and precipitation environment) influence early emergence and biomass investment in spines. A phylogenetically diverse pool of 45 species possessing different spine types (spines, prickles and thorns; that are derived from distinct plant organs: leaf, epidermis or cortex, and branch, respectively), were grown under common garden conditions, and patterns of spine emergence and biomass allocation to spines at 5 and 15 weeks after transplanting were characterized.
Spine type and species’ resource niche were the main factors driving early emergence and investment patterns. Spines emerged earliest in leaf spine-bearing species, and latest in thorn-bearing species. The probability of early spine emergence increased with decreasing precipitation, and was greater in species from open than closed habitats. Sapling investment in spines changed with plant mass but was contingent on spine type and habitat type.
Different spine types have strikingly different timing of expression, suggesting that developmental origins of spines play a critical role in sapling defences. Furthermore, species from different precipitation and light environments (open vs. closed habitats) showed contrasting patterns of early spine expression suggesting that resource limitation in their native range may have driven divergent evolution of early defence expression.
45 diverse spiny plants were grown under common-garden conditions and patterns of spine emergence and biomass allocation to spines after 5 and 15 weeks after transplanting were characterized.
National Natural Science Foundation of China, Award: 31470449
National Natural Science Foundation of China, Award: 017PB0093