Cary Institute of Ecosystem Studies, Millbrook, NY 12545, USA.
Oecologia. 2011 Sep;167(1):253-64. doi: 10.1007/s00442-011-1970-8. Epub 2011 Mar 29.
Mosses play an integral role in the hydrologic regimes of ecosystems where they cover the soil surface, and thus affect biogeochemical cycling of elements influenced by soil oxidation-reduction (redox) reactions, including the plant growth-limiting nutrients, nitrogen and phosphorus (P). In rich fens where P often limits plant growth, we hypothesized that feedbacks between mosses and redox conditions would determine P availability to shallow-rooted forb species that constitute much of these wetlands' unusually high plant species diversity. In a moss removal experiment in three fens, forb tissue P and microbial P were greater while anion exchange membrane (AEM) resin P was lower where mosses occurred than where they were removed, suggesting both higher availability and greater demand for P in moss-covered soils. Coupled physicochemical and biological mechanisms drove moss effects on P cycling, ultimately through effects on soil oxygenation or reduction: higher redox potential underlying mosses corresponded to greater microbial activity, phosphatase enzyme activity, and colonization by arbuscular mycorrhizal fungi (AMF), all of which can promote greater P availability to plants. These more oxidized soils stimulated: (1) greater microbial activity and root vigor; (2) correspondingly greater P demand via microbial uptake, forb uptake, and iron (Fe)-P reactions; and (3) greater P supply through soil and root phosphatase activity and AMF colonization. This work demonstrates that mosses improve vascular plant P acquisition by alleviating stresses caused by reducing conditions that would otherwise prevail in shallow underlying soils, thus providing a mechanism by which mosses facilitate plant species diversity in rich fens.
藓类植物在覆盖土壤表面的生态系统水文状态中起着不可或缺的作用,因此会影响受土壤氧化还原(redox)反应影响的元素的生物地球化学循环,包括植物生长受限的养分氮和磷(P)。在富营养沼泽中,P 通常限制植物生长,我们假设藓类植物和 redox 条件之间的反馈将决定浅层根系草本物种的 P 可利用性,这些物种构成了这些湿地异常高的植物物种多样性的大部分。在三个沼泽地的藓类去除实验中,与去除藓类的地方相比,有藓类的地方草本植物组织 P 和微生物 P 更高,而阴离子交换膜(AEM)树脂 P 更低,这表明藓类覆盖土壤中 P 的可用性更高,对 P 的需求也更大。物理化学和生物机制共同作用,最终通过对土壤氧化还原的影响,驱动了藓类对 P 循环的影响:藓类下的氧化还原电位较高对应着更高的微生物活性、磷酸酶活性和丛枝菌根真菌(AMF)的定殖,所有这些都可以促进植物对 P 的更大可用性。这些更氧化的土壤刺激了:(1)更大的微生物活性和根系活力;(2)通过微生物吸收、草本植物吸收和铁(Fe)-P 反应相应地增加 P 需求;(3)通过土壤和根磷酸酶活性以及 AMF 定殖增加 P 供应。这项工作表明,藓类植物通过缓解原本会在浅层下土壤中占主导地位的还原条件造成的压力,从而改善了维管束植物对 P 的获取,为藓类植物促进富营养沼泽中的植物物种多样性提供了一种机制。
