Growth differences and characteristics of root and leaf morphological traits for different mycorrhizal tree species in the subtropical China: A case study of Xingangshan, Jiangxi Province

doi:10.17520/biods.2020368

Abstract

Abstract:

Aims: Exploring the intraspecific and interspecific variations in plant functional traits is not only beneficial for understanding plant adaptation to different environmental factors, but also helpful as a reflection on the ecological strategy. However, the adaptation strategies of root and leaf morphological traits in the growth process of different mycorrhizal tree species need to be explored.

Methods: We studied seven arbuscular mycorrhizal (AM) tree species and seven ectomycorrhizal (EM) tree species in the Biodiversity-Ecosystem Functioning Experiment China Platform (BEF-China). We studied the characteristics of root and leaf morphological traits of different mycorrhizal tree species by measuring the following morphological traits and growth indices: specific leaf area, leaf dry matter content, specific root length, average diameter, the growth rate of tree height, the growth rate of basal diameter, and fine root biomass.

Results: We found that when compared with AM tree species, EM tree species had lower specific leaf area, average diameter of absorbing root, and growth rate (including tree height and basal diameter). EM species had a higher leaf dry matter content. There were no significant differences in the specific root length and fine root biomass between the two types of mycorrhizal tree species. There were significant differences in specific leaf area, leaf dry matter content, the growth rate of tree height, the growth rate of basal diameter and fine root biomass between tree species, mycorrhizal types and the interaction between the two. Additionally, tree species, root functional type, mycorrhizal type and the interaction between tree species with root functional types and mycorrhizal types had significant effects on root functional traits. The intraspecific variation of the aboveground growth indices of EM tree species was greater than that of interspecific variation, whereas the intraspecific variation was similar to the interspecific variations of the above-ground indices of AM tree species. Furthermore, the intraspecific variation was greater than the interspecific variation of fine root biomass for all tree species. Although the above-ground growth for two types of mycorrhizal tree species had a faster growth rate, they usually showed low leaf dry matter content. AM tree species had a high specific root length for absorbing roots, while EM tree species had a high average diameter for transporting roots. Low specific root length of the absorbing roots greatly increased the fine root biomass for all the tree species.

Conclusions: Therefore, there was a certain synergistic effect between root and leaf morphological traits on plant growth above ground. Transporting roots mainly played an important role in the above-ground growth of EM tree species. Whereas absorptive roots mainly were related to the above-ground growth of AM tree species. However, below ground growth was mainly related to the absorptive root for all tree species.

Key words: root and leaf functional traits, plant growth, fine root biomass, aboveground-belowground relationship, mycorrhizal types

Yuanli Ouyang, Cancan Zhang, Xiaofan Lin, Lixin Tian, Hanjiao Gu, Fusheng Chen, Wensheng Bu. Growth differences and characteristics of root and leaf morphological traits for different mycorrhizal tree species in the subtropical China: A case study of Xingangshan, Jiangxi Province[J]. Biodiv Sci, 2021, 29(6): 746-758.

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URL: https://www.biodiversity-science.net/EN/10.17520/biods.2020368

https://www.biodiversity-science.net/EN/Y2021/V29/I6/746

Figures/Tables 9

References 40

[1]	Albert CH, Thuiller W, Yoccoz NG, Douzet R, Lavorel S (2010) A multi-trait approach reveals the structure and the relative importance of intra- versus interspecific variability in plant traits. Functional Ecology, 24,1192-1201. DOI URL
[2]	Auger S, Shipley B (2013) Inter-specific and intra-specific trait variation along short environmental gradients in an old-growth temperate forest. Journal of Vegetation Science, 24,419-428. DOI URL
[3]	Averill C, Bhatnagar JM, Dietze MC, Pearse WD, Kivlin SN (2019) Global imprint of mycorrhizal fungi on whole-plant nutrient economics. Proceedings of the National Academy of Sciences, USA, 116,23163-23168.
[4]	Bu WS, Schmid B, Liu XJ, Li Y, Hrdtle W, Von Oheimb G, Liang Y, Sun ZK, Huang YY, Bruelheide H, Ma KP (2017) Interspecific and intraspecific variation in specific root length drives aboveground biodiversity effects in young experimental forest stands. Journal of Plant Ecology, 10,158-169. DOI URL
[5]	Comas LH, Callahan HS, Midford PE (2014) Patterns in root traits of woody species hosting arbuscular and ectomycorrhizas: Implications for the evolution of belowground strategies. Ecology and Evolution, 4,2979-2990. DOI URL
[6]	Cornelissen J, Aerts R, Cerabolini B, Werger M, Heijden M (2001) Carbon cycling traits of plant species are linked with mycorrhizal strategy. Oecologia, 129,611-619. DOI PMID
[7]	De la Riva EG, Maranon T, Pérez-Ramos IM, Navarro-Fernández CM, Olmo M, Villar R (2018) Root traits across environmental gradients in Mediterranean woody communities: Are they aligned along the root economics spectrum?. Plant and Soil, 424,35-48. DOI URL
[8]	Diaz S, Hodgson JG, Thompson K, Cabido M, Cornelissen JHC, Jalili A, Montserrat-Marti G, Grime JP, Zarrinkamar F, Asri Y, Band SR, Basconcelo S, Castro-Diez P, Funes G, Hamzehee B, Khoshnevi M, Perez-Harguindeguy N, Perez-Rontome MC, Shirvany FA, Vendramini F, Yazdani S, Abbas-Azimi R, Bogaard A, Boustani S, Charles M, Dehghan M, Torres-Espuny L, Falczuk V, Guerrero-Campo J, Hynd A, Jones G, Kowsary E, Kazemi-Saeed F, Maestro-Martinez M, Romo-Diez A, Shaw S, Siavash B, Villar-Salvador P, Zak MR (2004) The plant traits that drive ecosystems: Evidence from three continents. Journal of Vegetation Science, 15,295-304. DOI URL
[9]	Druebert C, Lang C, Valtanen K, Polle A (2009) Beech carbon productivity as driver of ectomycorrhizal abundance and diversity. Plant, Cell & Environment, 32,992-1003.
[10]	Ekblad A, Wallander H, Godbold DL, Cruz C, Johnson D, Baldrian P, Björk RG, Epron D, Kieliszewska-Rokicka B, Kjøller R, Kraigher H, Matzner E, Neumann J, Plassard C (2013) The production and turnover of extramatrical mycelium of ectomycorrhizal fungi in forest soils: Role in carbon cycling. Plant and Soil, 366,1-27. DOI URL
[11]	Fitter AH, Gilligan CA, Hollingworth K, Kleczkowski A, Twyman RM, Pitchford JW (2005) Biodiversity and ecosystem function in soil. Functional Ecology, 19,369-377. DOI URL
[12]	Fordyce JA (2006) The evolutionary consequences of ecological interactions mediated through phenotypic plasticity. The Journal of Experimental Biology, 209,2377-2383. DOI URL
[13]	Geng Y, Ma WH, Wang L, Baumann F, Kuhn P, Scholten T, He JS (2017) Linking above- and belowground traits to soil and climate variables: An integrated database on China's grassland species. Ecology, 98, 1471.
[14]	Heijden M, Wiemken A, Sanders IR (2003) Different arbuscular mycorrhizal fungi alter coexistence and resource distribution between co-occurring plant. New Phytologist, 157,569-578. DOI URL
[15]	Holdaway RJ, Richardson SJ, Dickie IA, Peltzer DA, Coomes DA (2011) Species- and community-level patterns in fine root traits along a 120000-year soil chronosequence in temperate rain forest. Journal of Ecology, 99,954-963. DOI URL
[16]	Jung V, Violle C, Mondy C, Hoffmann L, Muller S (2010) Intraspecific variability and trait-based community assembly. Journal of Ecology, 98,1134-1140. DOI URL
[17]	Kiers ET, Duhamel M, Beesetty Y, Mensah JA, Franken O, Verbruggen E, Fellbaum CR, Kowalchuk GA, Hart MM, Bago A, Palmer TM, West SA, Vandenkoornhuyse P, Jansa J, Bucking H (2011) Reciprocal rewards stabilize cooperation in the mycorrhizal symbiosis. Science, 333,880-882. DOI URL
[18]	Kloeke AEE, Douma JC, Ordoñez JC, Reich PB, Bodegom PM (2012) Global quantification of contrasting leaf life span strategies for deciduous and evergreen species in response to environmental conditions. Global Ecology and Biogeography, 21,224-235. DOI URL
[19]	Laforest-Lapointe I, Martínez-Vilalta J, Retana J (2014) Intraspecific variability in functional traits matters: Case study of Scots pine. Oecologia, 175,1337-1348. DOI PMID
[20]	Liu NN, Tian QY, Zhang WH (2014) Comparison of adaptive strategies to phosphorus-deficient soil between dominant species Artemisia frigida and Stipa krylovii in typical steppe of Nei Mongol . Chinese Journal of Plant Ecology (Chinese version), 38,905-915. (in Chinese with English abstract)
	刘娜娜, 田秋英, 张文浩 (2014) 内蒙古典型草原优势种冷蒿和克氏针茅对土壤低磷环境适应策略的比较. 植物生态学报, 38,905-915.] DOI
[21]	Liu XJ, Ma KP (2015) Plant functional traits—Concepts, applications and future directions. Scientia Sinica Vitae, 45,325-339. (in Chinese with English abstract) DOI URL
	刘晓娟, 马克平 (2015) 植物功能性状研究进展. 中国科学: 生命科学, 45,325-339.]
[22]	Ma KP (2013) Studies on biodiversity and ecosystem function via manipulation experiments. Biodiversity Science, 21,390-391. (in Chinese)
	马克平 (2013) 生物多样性与生态系统功能的实验研究. 生物多样性, 21,390-391.]
[23]	Messier J, McGill BJ, Lechowicz MJ (2010) How do traits vary across ecological scales? A case for trait-based ecology. Ecology Letters, 13,838-848. DOI PMID
[24]	Nakagawa S, Schielzeth H (2013) A general and simple method for obtaining R² from generalized linear mixed-effects models . Methods in Ecology and Evolution, 4,133-142. DOI URL
[25]	Pregitzer KS, DeForest JL, Burton AJ, Allen MF, Ruess RW, Hendrick RL (2002) Fine root architecture of nine north American trees. Ecological Monographs, 72,293-309. DOI URL
[26]	Prinzing A, Durka W, Klotz S, Brand R (2001) The niche of higher plants: Evidence for phylogenetic conservatism. Proceedings of the Royal Society B-Biological Sciences, 268,2383-2389.
[27]	Reich PB (2014) The world-wide ‘fast-slow' plant economics spectrum: A traits manifesto. Journal of Ecology, 102,275-301. DOI URL
[28]	Segnitz RM, Russo SE, Davies SJ, Peay KG (2020) Ectomycorrhizal fungi drive positive phylogenetic plant-soil feedbacks in a regionally dominant tropical plant family. Ecology, 101,e03083.
[29]	Shi W, Wang ZQ, Liu JL, Gu JC, Guo DL (2008) Fine root morphology of twenty hardwood species in Maoershan natural secondary forest in northeastern China. Journal of Plant Ecology (Chinese version), 32,1217-1226. (in Chinese with English abstract)
	师伟, 王政权, 刘金梁, 谷加存, 郭大立 (2008) 帽儿山天然次生林20个阔叶树种细根形态. 植物生态学报, 32,1217-1226.] DOI
[30]	Shipley B (2002) Trade-offs between net assimilation rate and specific leaf area in determining relative growth rate: Relationship with daily irradiance. Functional Ecology, 16,682-689. DOI URL
[31]	Tang QQ, Huang YT, Ding Y, Zang RG (2016) Interspecific and intraspecific variation in functional traits of subtropical evergreen and deciduous broad-leaved mixed forests. Biodiversity Science, 24,262-270. (in Chinese with English abstract) DOI URL
	唐青青, 黄永涛, 丁易, 臧润国 (2016) 亚热带常绿落叶阔叶混交林植物功能性状的种间和种内变异. 生物多样性, 24,262-270.] DOI
[32]	Taylor AFS, Alexander I (2005) The ectomycorrhizal symbiosis: Life in the real world. Mycologist, 19,102-112. DOI URL
[33]	Turrini A, Bedini A, Loor MB, Santini G, Sbrana C, Giovannetti M, Avio L (2018) Local diversity of native arbuscular mycorrhizal symbionts differentially affects growth and nutrition of three crop plant species. Biology and Fertility of Soils, 54,203-217. DOI URL
[34]	Twieg BD, Durall DM, Simard SW (2010) Ectomycorrhizal fungal succession in mixed temperate forests. New Phytologist, 176,437-447. DOI URL
[35]	Wells CE, Eissenstat DM (2002) Beyond the roots of young seedlings: The influence of age and order on fine root physiology. Journal of Plant Growth Regulation, 21,324-334. DOI URL
[36]	Westoby M, Falster DS, Moles AT, Vesk PA, Wright IJ (2002) Plant ecological strategies: Some leading dimensions of variation between species. Annual Review of Ecology and Systematics, 33,125-159. DOI URL
[37]	Wright IJ, Ackerly DD, Bongers F, Harms KE, Ibarra-Manriquez G, Martinez-Ramos M, Mazer SJ, Muller-Landau HC, Paz H, Pitman NCA, Poorter L, Silman MR, Vriesendorp CF, Webb CO, Westoby M, Wright SJ (2007) Relationships among ecologically important dimensions of plant trait variation in seven neotropical forests. Annals of Botany, 99,1003-1015. DOI URL
[38]	Wright IJ, Reich PB, Cornelissen JHC, Falster DS, Garnier E, Hikosaka K, Lamont BB, Lee W, Oleksyn J, Osada N, Poorter H, Villar R, Warton DI, Westoby M (2005) Assessing the generality of global leaf trait relationships. New Phytologist, 166,485-496. PMID
[39]	Wright IJ, Reich PB, Westoby M, Ackerly DD, Baruch Z, Bongers F, Cavender-Bares J, Chapin T, Cornelissen JHC, Diemer M, Flexas J, Garnier E, Groom PK, Gulias J, Hikosaka K, Lamont BB, Lee T, Lee W, Lusk C, Midgley JJ, Navas ML, Niinemets U, Oleksyn J, Osada N, Poorter H, Poot P, Prior L, Pyankov VI, Roumet C, Thomas SC, Tjoelker MG, Veneklaas EJ, Villar R (2004) The worldwide leaf economics spectrum. Nature, 428,821-827. PMID
[40]	Zi HB, Chen Y, Hu L, Wang CT (2018) Effects of nitrogen addition on root dynamics in an alpine meadow, Northwestern Sichuan. Chinese Journal of Plant Ecology, 42,38-49. (in Chinese with English abstract) DOI URL
	字洪标, 陈焱, 胡雷, 王长庭 (2018) 氮肥添加对川西北高寒草甸植物群落根系动态的影响. 植物生态学报, 42,38-49.] DOI

树种 Tree species		菌根类型 Mycorrhiza type
白栎	Quercus fabri	外生菌根 EM
青冈	Cyclobalanopsis glauca	外生菌根 EM
短柄枹栎	Quercus serrata	外生菌根 EM
苦槠	Castanopsis sclerophylla	外生菌根 EM
细叶青冈	Cyclobalanopsis myrsinifolia	外生菌根 EM
石栎	Lithocarpus glaber	外生菌根 EM
锥栗	Castanea henryi	外生菌根 EM
无患子	Sapindus saponaria	丛枝菌根 AM
枫香	Liquidambar formosana	丛枝菌根 AM
复羽叶栾	Koelreuteria bipinnata	丛枝菌根 AM
乌桕	Triadica sebifera	丛枝菌根 AM
蓝果树	Nyssa sinensis	丛枝菌根 AM
木荷	Schima superba	丛枝菌根 AM
南酸枣	Choerospondias axillaris	丛枝菌根 AM

树种 Tree species		菌根类型 Mycorrhiza type
白栎	Quercus fabri	外生菌根 EM
青冈	Cyclobalanopsis glauca	外生菌根 EM
短柄枹栎	Quercus serrata	外生菌根 EM
苦槠	Castanopsis sclerophylla	外生菌根 EM
细叶青冈	Cyclobalanopsis myrsinifolia	外生菌根 EM
石栎	Lithocarpus glaber	外生菌根 EM
锥栗	Castanea henryi	外生菌根 EM
无患子	Sapindus saponaria	丛枝菌根 AM
枫香	Liquidambar formosana	丛枝菌根 AM
复羽叶栾	Koelreuteria bipinnata	丛枝菌根 AM
乌桕	Triadica sebifera	丛枝菌根 AM
蓝果树	Nyssa sinensis	丛枝菌根 AM
木荷	Schima superba	丛枝菌根 AM
南酸枣	Choerospondias axillaris	丛枝菌根 AM

叶功能性状及生长指标 Leaf functional traits and growth indices	树种 Tree species	菌根类型 Mycorrhizal type	树种 × 菌根类型 Tree species × mycorrhizal type
比叶面积 Specific leaf area	12.03^***	113.47^***	30.23^***
叶干物质含量 Leaf dry matter content	32.04^***	155.43^***	81.65^***
树高生长速率 The growth rate of height	21.21^***	29.37^***	26.77^***
地径生长速率 The growth rate of basal diameter	6.27^***	32.78^***	9.74^***
细根生物量 Fine root biomass	29.85^***	3.78^*	28.75^***

叶功能性状及生长指标 Leaf functional traits and growth indices	树种 Tree species	菌根类型 Mycorrhizal type	树种 × 菌根类型 Tree species × mycorrhizal type
比叶面积 Specific leaf area	12.03^***	113.47^***	30.23^***
叶干物质含量 Leaf dry matter content	32.04^***	155.43^***	81.65^***
树高生长速率 The growth rate of height	21.21^***	29.37^***	26.77^***
地径生长速率 The growth rate of basal diameter	6.27^***	32.78^***	9.74^***
细根生物量 Fine root biomass	29.85^***	3.78^*	28.75^***

因素类型 Factor type	比根长 Specific root length	平均直径 Average diameter
树种 Tree species	10.80^***	14.05^***
根功能类型 Root functional type	683.40^***	1,462.96^***
菌根类型 Mycorrhizal type	2.06^*	3.37^*
树种 × 根功能类型 Tree species × root functional type	15.12^**	79.10^***
树种 × 菌根类型 Tree species × mycorrhizal type	2.54^**	1.91^*
根功能类型 × 菌根类型 Root functional type × mycorrhizal type	156.42^***	293.21^***
树种 × 根功能类型 × 菌根类型 Tree species × root functional type × mycorrhizal type	64.47^***	79.11^***