Akira Yamawo1, Haruna Ohsaki1, James F Cahill2. 1. Department of Biology, Faculty of Agriculture and Life Science, Hirosaki University, 1 Bunkyo-cho, Hirosaki, 036-8560, Japan. 2. Department of Biological Sciences, University of Alberta, Edmonton, AB, T6G 2E9, Canada.
Abstract
PREMISE: Plants generally increase root growth in areas with high nutrients in heterogeneous soils, a phenomenon called foraging precision. The physiology of this process is not well understood, but it may involve shoot-root signaling via leaf veins. If this is true, then damage to leaf veins, but not to nearby mesophyll, would reduce plant foraging precision. METHODS: To test this hypothesis, we imposed two leaf damage treatments on Plantago asiatica and Prunus jamasakura, removing either the tip of each main vein or mesophyll tissue between the veins with a 3-mm-diameter hole punch. After 30 days or 20 weeks of plant growth, we measured root biomass in the soil in response to soil nutrient concentration. RESULTS: When leaf mesophyll was damaged, root biomass of both species was greater in nutrient-rich patches than in nutrient-poor patches. However, when leaf veins were damaged, root biomass was similar between patches. CONCLUSIONS: These results suggest the importance of shoot-root signaling in plants, emphasizing that physiological processes are not necessarily restricted to single organs. The idea that herbivores that damage leaf veins may affect a plant's ability to selectively forage in high-nutrient patches is novel, with implications for natural and managed systems.
PREMISE: Plants generally increase root growth in areas with high nutrients in heterogeneous soils, a phenomenon called foraging precision. The physiology of this process is not well understood, but it may involve shoot-root signaling via leaf veins. If this is true, then damage to leaf veins, but not to nearby mesophyll, would reduce plant foraging precision. METHODS: To test this hypothesis, we imposed two leaf damage treatments on Plantago asiatica and Prunus jamasakura, removing either the tip of each main vein or mesophyll tissue between the veins with a 3-mm-diameter hole punch. After 30 days or 20 weeks of plant growth, we measured root biomass in the soil in response to soil nutrient concentration. RESULTS: When leaf mesophyll was damaged, root biomass of both species was greater in nutrient-rich patches than in nutrient-poor patches. However, when leaf veins were damaged, root biomass was similar between patches. CONCLUSIONS: These results suggest the importance of shoot-root signaling in plants, emphasizing that physiological processes are not necessarily restricted to single organs. The idea that herbivores that damage leaf veins may affect a plant's ability to selectively forage in high-nutrient patches is novel, with implications for natural and managed systems.