Velmala Sannakajsa M, Rajala Tiina, Heinonsalo Jussi, Taylor Andy F S, Pennanen Taina
Finnish Forest Research Institute - Metla, PO Box 18, 01301 Vantaa, Finland.
Viikki Biocenter, Department of Food and Environmental Sciences, Faculty of Agriculture and Forestry, PO Box 56, 00014 University of Helsinki, Finland.
New Phytol. 2014 Jan;201(2):610-622. doi: 10.1111/nph.12542. Epub 2013 Oct 14.
We studied the role of taxonomical and functional ectomycorrhizal (ECM) fungal diversity in root formation and nutrient uptake by Norway spruce (Picea abies) seedlings with fast- and slow-growing phenotypes. Seedlings were grown with an increasing ECM fungal diversity gradient from one to four species and sampled before aboveground growth differences between the two phenotypes were apparent. ECM fungal colonization patterns were determined and functional diversity was assayed via measurements of potential enzyme activities of eight exoenzymes probably involved in nutrient mobilization. Phenotypes did not vary in their receptiveness to different ECM fungal species. However, seedlings of slow-growing phenotypes had higher fine-root density and thus more condensed root systems than fast-growing seedlings, but the potential enzyme activities of ectomycorrhizas did not differ qualitatively or quantitatively. ECM species richness increased host nutrient acquisition potential by diversifying the exoenzyme palette. Needle nitrogen content correlated positively with high chitinase activity of ectomycorrhizas. Rather than fast- and slow-growing phenotypes exhibiting differing receptiveness to ECM fungi, our results suggest that distinctions in fine-root structuring and in the belowground growth strategy already apparent at early stages of seedling development may explain later growth differences between fast- and slow-growing families.
我们研究了分类学和功能外生菌根(ECM)真菌多样性在具有快速生长和缓慢生长表型的挪威云杉(Picea abies)幼苗根系形成和养分吸收中的作用。幼苗在从一种到四种物种的增加的ECM真菌多样性梯度下生长,并在两种表型之间地上部生长差异明显之前进行采样。确定了ECM真菌的定殖模式,并通过测量可能参与养分动员的八种胞外酶的潜在酶活性来测定功能多样性。表型对不同ECM真菌物种的接受性没有差异。然而,生长缓慢表型的幼苗比生长快速的幼苗具有更高的细根密度,因此根系更紧凑,但外生菌根的潜在酶活性在质量或数量上没有差异。ECM物种丰富度通过使胞外酶种类多样化而增加了宿主养分获取潜力。针叶氮含量与外生菌根的高几丁质酶活性呈正相关。我们的结果表明,不是快速生长和缓慢生长的表型对外生菌根真菌表现出不同的接受性,而是在幼苗发育早期已经明显的细根结构和地下生长策略的差异可能解释了快速生长和缓慢生长家族后期的生长差异,而不是快速生长和缓慢生长的表型对外生菌根真菌表现出不同的接受性。
