Instituto de Fisiología y Recursos Genéticos Vegetales (IFRGV), Centro de Investigaciones Agropecuarias (CIAP), Instituto Nacional de Tecnología Agropecuaria (INTA)-Unidad de Estudios Agropecuarios (UDEA), Consejo Nacional de Investigaciones Científicas y Técnicas (CONICET). Córdoba, Argentina.
Centro de Ciências Agroveterinárias (CAV), Universidade do Estado de Santa Catarina (UDESC), Avenida Luiz de Camões, Lages, Santa Catarina, Brazil.
PLoS One. 2024 Jul 30;19(7):e0306692. doi: 10.1371/journal.pone.0306692. eCollection 2024.
Functional traits are powerful tools for distinguishing between plants with different resource acquisition strategies. Fast-growing plants normally dominate resource-rich habitats and present trait values associated with high productivity, such as high specific leaf area (SLA), short leaf lifespan, and rapid leaf elongation rate (LER). In contrast, slow-growing species have a higher leaf weight ratio (LWR), leaf lifespan (LLS), and phyllochron, which are useful traits for survival in stressful and unfertile environments, but are normally thought to be incompatible with high productivity, even under fertile conditions. We tested the hypothesis that slow-growing forage grasses have demographic parameters (tiller population density and canopy density) that offset their slow individual traits, making them as productive as fast-growing species when grown in fertile soil. Species with contrasting growth strategies (Arrhenatherum elatius L. and Festuca arundinacea Schreb cv. Quantum II, fast and slow-growing species, respectively) were cultivated in 45 m2 field plots and subjected to the same cutting regime and nitrogen supply level. Functional traits and canopy attributes were continuously measured during 8 growing cycles after the establishment of the swards. A. elatius had higher SLA, LER, leaf senescence, and leaf appearance rates, whereas F. arundinacea had higher LLS and LWR values. Conversely, there were no differences in relative growth rate or forage accumulation. F. arundinacea was able to offset their plant functional traits, typically associated with slow-growing grasses, with some demographic parameter like higher tiller population density, allowing it to be as productive as the fast-growing A. elatius when both were grown in fertile soil. Therefore, we suggest cautionary use of traditional plant functional traits to explain and predict the annual productivity of slow-growing grasses.
功能性状是区分具有不同资源获取策略的植物的有力工具。通常,快速生长的植物会在资源丰富的生境中占据主导地位,并表现出与高生产力相关的特征值,如高比叶面积(SLA)、短叶寿命和快速叶伸长率(LER)。相比之下,生长缓慢的物种具有较高的叶重比(LWR)、叶寿命(LLS)和叶龄,这些特征值有助于在压力大且贫瘠的环境中生存,但通常被认为与高生产力不相容,即使在肥沃的条件下也是如此。我们检验了这样一个假设,即生长缓慢的牧草具有能够抵消其个体生长缓慢的特征的繁殖参数(分孽株密度和冠层密度),从而使它们在肥沃的土壤中生长时与快速生长的物种一样具有生产力。我们选择了两种具有不同生长策略的物种(节节麦和多年生黑麦草,分别为快速生长和缓慢生长的物种),在 45 平方米的田间小区进行种植,并采用相同的刈割制度和氮供应水平。在建立草地后的 8 个生长周期中,我们连续测量了功能性状和冠层特征。节节麦具有更高的 SLA、LER、叶片衰老和叶片出现率,而多年生黑麦草则具有更高的 LLS 和 LWR 值。相反,相对生长率或饲草积累量没有差异。多年生黑麦草能够通过一些繁殖参数来抵消其与缓慢生长的牧草相关的植物功能特征,例如较高的分孽株密度,从而使其在肥沃的土壤中与快速生长的节节麦一样具有生产力。因此,我们建议谨慎使用传统的植物功能性状来解释和预测生长缓慢的牧草的年生产力。
