Department of Ecology, Evolution, and Environmental Biology, Columbia University, New York, New York, 10027, USA.
Department of Ecology and Evolutionary Biology, Princeton University, Princeton, New Jersey, 08544, USA.
Ecology. 2017 Dec;98(12):3127-3140. doi: 10.1002/ecy.2034. Epub 2017 Nov 8.
Symbiotic nitrogen (N) fixation provides a dominant source of new N to the terrestrial biosphere, yet in many cases the abundance of N-fixing trees appears paradoxical. N-fixing trees, which should be favored when N is limiting, are rare in higher latitude forests where N limitation is common, but are abundant in many lower latitude forests where N limitation is rare. Here, we develop a graphical and mathematical model to resolve the paradox. We use the model to demonstrate that N fixation is not necessarily cost effective under all degrees of N limitation, as intuition suggests. Rather, N fixation is only cost effective when N limitation is sufficiently severe. This general finding, specific versions of which have also emerged from other models, would explain sustained moderate N limitation because N-fixing trees would either turn N fixation off or be outcompeted under moderate N limitation. From this finding, four general hypothesis classes emerge to resolve the apparent paradox of N limitation and N-fixing tree abundance across latitude. The first hypothesis is that N limitation is less common at higher latitudes. This hypothesis contradicts prevailing evidence, so is unlikely, but the following three hypotheses all seem likely. The second hypothesis, which is new, is that even if N limitation is more common at higher latitudes, more severe N limitation might be more common at lower latitudes because of the capacity for higher N demand. Third, N fixation might be cost effective under milder N limitation at lower latitudes but only under more severe N limitation at higher latitudes. This third hypothesis class generalizes previous hypotheses and suggests new specific hypotheses. For example, greater trade-offs between N fixation and N use efficiency, soil N uptake, or plant turnover at higher compared to lower latitudes would make N fixation cost effective only under more severe N limitation at higher latitudes. Fourth, N-fixing trees might adjust N fixation more at lower than at higher latitudes. This framework provides new hypotheses to explain the latitudinal abundance distribution of N-fixing trees, and also provides a new way to visualize them. Therefore, it can help explain the seemingly paradoxical persistence of N limitation in many higher latitude forests.
共生固氮为陆地生物圈提供了主要的氮源,但在许多情况下,固氮树种的丰度似乎存在矛盾。在氮限制普遍存在的高纬度森林中,固氮树种本应受到青睐,但在氮限制罕见的许多低纬度森林中却很丰富。在这里,我们开发了一个图形和数学模型来解决这个悖论。我们使用该模型来证明,固氮并不一定在所有程度的氮限制下都是经济有效的,这与直觉相反。相反,只有在氮限制足够严重的情况下,固氮才是经济有效的。这一普遍发现,以及其他模型中出现的特定版本,将解释为什么持续存在中度氮限制,因为在中度氮限制下,固氮树要么关闭固氮,要么在竞争中被淘汰。从这一发现中,出现了四个一般假设类别,以解决纬度跨度上氮限制和固氮树种丰度的明显悖论。第一个假设是,在高纬度地区,氮限制不太常见。这个假设与现有证据相矛盾,因此不太可能,但以下三个假设似乎都有可能。第二个假设是,即使氮限制在高纬度地区更为常见,但由于更高的氮需求能力,更低纬度地区可能更常见更为严重的氮限制。第三,在低纬度地区,在较温和的氮限制下,固氮可能是经济有效的,但在高纬度地区,只有在更严重的氮限制下才是经济有效的。这第三个假设类别概括了以前的假设,并提出了新的具体假设。例如,与氮利用效率、土壤氮吸收或植物周转率相比,在高纬度地区,固氮与氮利用之间的权衡更大,这将使得在高纬度地区只有在更严重的氮限制下固氮才是经济有效的。第四,固氮树种可能在低纬度地区比在高纬度地区更能调整固氮。该框架提供了新的假设来解释固氮树种的纬度丰度分布,也为可视化提供了新的方法。因此,它可以帮助解释许多高纬度森林中氮限制的持续存在看似矛盾的现象。
