Wittyngham Serina S, Johnson David S
Virginia Institute of Marine Science, William & Mary Gloucester Point Virginia USA.
Ecol Evol. 2025 Apr 25;15(4):e71360. doi: 10.1002/ece3.71360. eCollection 2025 Apr.
Herbivore fronts can alter plant traits (chemical and/or morphological features) and performance via grazing. Yet, herbivore-driven trait alterations are rarely considered when assessing how these fronts shape ecosystems, despite the critical role that plant performance plays in ecosystem functioning. We evaluated herbivore fronts created by the purple marsh crab, , as it consumes the cordgrass, , in Virginian salt marshes. fronts form at the head of tidal creeks and move inland, creating a denuded mudflat between the tall-form low marsh (trailing edge) and the short-form high marsh (leading edge). We quantified front migration rate, tested if herbivory altered geomorphic processes and traits at the trailing and leading edges, and examined how these trait changes persisted through the final 8 weeks of the growing season. front migration in our region is two times slower than fronts in the Southeast United States, and retreat rate at the leading edge is greater than the revegetation rate at the trailing edge. fronts lowered elevation and decreased sediment shear strength at the trailing edge while having no impact on soil organic matter and bulk density at either edge. At the leading edge, grazing reduced growth traits and defensive ability, and trait changes persisted through the remaining growing season. At the trailing edge, however, grazing promoted belowground biomass production and had limited to no effect on growth or defensive traits. We show that herbivore fronts negatively impact saltmarsh plant traits at their leading edge, potentially contributing to front propagation. In contrast, plants at the trailing edge were more resistant to herbivore grazing and may enhance resilience through elevated belowground biomass production. Future work should consider herbivore-driven plant trait alterations in the context of herbivore fronts to better predict ecosystem response and recovery.
食草动物前沿可通过啃食改变植物性状(化学和/或形态特征)及表现。然而,在评估这些前沿如何塑造生态系统时,尽管植物表现对生态系统功能起着关键作用,但食草动物驱动的性状改变却很少被考虑。我们评估了弗吉尼亚盐沼中紫螯相手蟹啃食互花米草时形成的食草动物前沿。食草动物前沿在潮汐小溪的源头形成并向内陆移动,在高株互花米草的低沼(后缘)和矮株互花米草的高沼(前缘)之间形成一片光秃的泥滩。我们量化了食草动物前沿的迁移速率,测试了紫螯相手蟹的啃食是否改变了地貌过程以及后缘和前缘的互花米草性状,并研究了这些性状变化在生长季的最后8周内如何持续。我们所在地区的食草动物前沿迁移速度比美国东南部的前沿慢两倍,前缘的后退速度大于后缘的植被恢复速度。食草动物前沿降低了后缘的海拔并降低了沉积物抗剪强度,而对两边缘的土壤有机质和容重均无影响。在前缘,紫螯相手蟹的啃食降低了互花米草的生长性状和防御能力,且性状变化在剩余生长季持续存在。然而,在后缘,紫螯相手蟹的啃食促进了地下生物量的生产,对生长或防御性状的影响有限或没有影响。我们表明,食草动物前沿在其前缘对盐沼植物性状产生负面影响,可能有助于前沿的推进。相比之下,后缘的植物对食草动物的啃食更具抗性,可能通过增加地下生物量的生产来增强恢复力。未来的工作应在食草动物前沿的背景下考虑食草动物驱动的植物性状改变,以便更好地预测生态系统的反应和恢复。
