Growth adaptability of Zostera marina at different habitats of the Swan Lake in Rongcheng, China

doi:10.13287/j.1001-9332.201705.035

Abstract

Abstract: Eelgrass (Zostera marina), a seagrass species widely distributed in the coastal regions of northern hemisphere, has suffered with a great decline due to a variety of anthropogenic and environmental stresses. In order to examine the adaptability of eelgrass to different environmental stresses, studies on the morphology and reproductive capacity of eelgrass had been carried out monthly from November 2014 to October 2015 at four different habitats of the Swan Lake, including patch area inintertidal area and subtidal area, eelgrass meadow edge, and eelgrass meadow area. The results showed significant spatio-temporal variations in the morphological parameters and branch frequency of eelgrass shoots at different habitats of the Swan Lake. The highest values of leaf length, leaf width, aboveground/belowground biomass, and internode length/diameter were observed in the meadow area, i.e., 78.54 cm, 7.93 mm, 7.03 and 3.88, respectively, while the highest branch frequency was observed in the meadow edge (88.4%). The plasticity index for aboveground/belowground biomass was higher (ranging from 0.77 to 0.92) at the four habitats, but those for the leaf width was slightly lower (ranging from 0.41 to 0.64). The number of spathes in each shoot showed no significant difference at different habitats, whereas the number of spathes per unit area was significantly different. Clonal reproduction was more dominant in meadow area than in the patch area where human disturbance was high.

Key words: reproductive strategy, morphological parameter, morphology adaptability, Zostera marina

GUO Mei-yu, LI Wen-tao, YANG Xiao-long, ZHANG Xiu-mei, LIU Jian-ying, LI Chang-jun. Growth adaptability of Zostera marina at different habitats of the Swan Lake in Rongcheng, China[J]. Chinese Journal of Applied Ecology, 2017, 28(5): 1498-1506.

References

[1] Huang X-P (黄小平), Jiang Z-J (江志坚), Fan H-Q (范航清), et al. The nomenclature of the ‘Algae’ name of seagrasses in China. Oceanologia et Limnologia Sinica (海洋与湖沼), 2016, 47(1): 290-294 (in Chinese)
[2] Li S (李森), Fan H-Q (范航清), Qiu G-L (邱广龙), et al. Review on research of seagrass beds restoration. Acta Ecologica Sinica (生态学报), 2010, 30(9): 2443-2453 (in Chinese)
[3] Han Q-Y (韩秋影), Huang X-P (黄小平), Shi P (施平), et al. Seagrass bed ecosystem service value: A case study on the Hepu seagrass bed in Guangxi Pro-vince. Marine Science Bulletin (海洋通报), 2007, 26(3): 33-38 (in Chinese)
[4] Ling J (凌娟), Dong J-D (董俊德), Zhang Y-Y (张燕英), et al. Isolation and characterization of a N₂-fixing bacterium from coral reef-seagrass ecosystem. Microbiology China (微生物学通报), 2010, 37(7): 962-968 (in Chinese)
[5] Dai B-L (戴本林), Hua Z-L (华祖林), Mu F-H (穆飞虎), et al. Offshore ecosystem health status assessment: A review. Chinese Journal of Applied Ecology (应用生态学报), 2013, 24(4): 1169-1176 (in Chinese)
[6] Waycott M, Duarte CM, Carruthers TJB, et al. Acce-lerating loss of seagrasses across the globe threatens coastal ecosystems. Proceedings of the National Academy of Sciences of the United States of America, 2009, 106: 12377-12381
[7] Fan H-Q (范航清), Shi Y-J (石雅君), Qiu G-L (邱广龙). China Seagrass Plants. Beijing: Ocean Press, 2009 (in Chinese)
[8] Furman BT, Jackson LJ, Bricker E, et al. Sexual recruitment in Zostera marina: A patch to landscape-scale investigation. Limnology and Oceanography, 2015, 60: 584-599
[9] Potouroglou M, Kenyon EJ, Gall A, et al. The roles of flowering, overwinter survival and sea surface temperature in the long-term population dynamics of Zostera marina around the Isles of Scilly, UK. Marine Pollution Bulletin, 2014, 83: 500-507
[10] Yu H (于函), Ma Y-H (马有会), Zhang Y (张岩), et al. Ecological characteristics of eelgrass (Zostera marina L.) and its response to environmental changes. Transactions of Oceanology and Limnology (海洋湖沼通报), 2007(suppl.): 112-120 (in Chinese)
[11] Pigliucci M. Evolution of phenotypic plasticity: Where are we going now? Trends in Ecology & Evolution, 2005, 20: 481-486
[12] Bradshaw WE, Holzapfel CM. Evolutionary response to rapid climate change. Science, 2006, 312: 1477-1478
[13] Zhu Z-H (朱志红), Liu J-X (刘建秀), Wang X-A (王孝安). Review of phenotypic plasticity and hierarchical selection in clonal plants. Chinese Journal of Plant Ecology (植物生态学报), 2007, 31(4): 588-598 (in Chinese)
[14] Shen D-W (沈栋伟), Li Y-Y (李媛媛), Chen X-Y (陈小勇). Review of clonal diversity and its effects on ecosystem functioning. Chinese Journal of Plant Ecology (植物生态学报), 2007, 31(4): 552-560 (in Chinese)
[15] Zheng F-Y (郑凤英), Liu X-Q (刘雪芹), Jin Y-M (金艳梅), et al. Clonal growth characteristics of Zostera marina L. Chinese Journal of Ecology (生态学杂志), 2013, 32(11): 2997-3003 (in Chinese)
[16] De Cock A. Flowering, pollination and fruit development in Zostera marina L. Aquatic Botany, 1980, 9: 201-220
[17] Thorhaug A, Roessler MA. Seagrass community dyna-mics in a subtropical estuarine lagoon. Aquaculture, 1977, 12: 253-277
[18] Orth RJ, Moore KA. Seasonal and year-to-year variations in the growth of Zostera marina L. (eelgrass) in the lower Chesapeake Bay. Aquatic Botany, 1986, 24: 335-341
[19] Sand-Jensen KAJ. Effect of epiphytes on eelgrass photosynthesis. Aquatic Botany, 1977, 3: 55-63
[20] Thayer GW, Kenworthy WJ, Fonseca MS. Ecology of Eelgrass Meadows of the Atlantic Coast: A Community Profile. Washington DC: U. S. Fish and WildlifeSer-vice. FWS/OBS-84/02, 1984: 147
[21] Gambi MC, Nowell ARM, Jumars PA. Flume observations on flow dynamics in Zostera marina (eelgrass) beds. Marine Ecology Progress Series, 1990, 61: 159-169
[22] Valle M, van Katwijk MM, de Jong DJ, et al. Comparing the performance of species distribution models of Zostera marina: Implications for conservation. Journal of Sea Research, 2013, 83: 56-64
[23] Schubert PR, Hukriede W, Karez R, et al. Mapping and modeling eelgrass Zostera marina distribution in the western Baltic Sea. Marine Ecology Progress Series, 2015, 522: 79-95
[24] Yuan Y-D (原永党), Song Z-C (宋宗诚), Guo C-L (郭长禄), et al. Morphological characters and microstructure of Zostera marina. Transactions of Oceanology and Limnology (海洋湖沼通报), 2010(3): 73-78 (in Chinese)
[25] Li W-T (李文涛), Zhang X-M (张秀梅). The ecolo-gical functions of seagrass meadows. Periodical of Ocean University of China (中国海洋大学学报), 2009, 39(5): 933-939 (in Chinese)
[26] Zhang PD, Fang C, Liu J, et al. An effective seed protection method for planting Zostera marina (eelgrass) seeds: Implications for their large-scale restoration. Marine Pollution Bulletin, 2015, 95: 89-99
[27] Yang CJ, Liu YS, Liu J, et al. Assessment of the establishment success of Zostera marina (eelgrass) from seeds in natural waters: Implications for large-scale restoration. Ecological Engineering, 2016, 92: 1-9
[28] Han Q, Soissons LM, Bouma TJ, et al. Combined nutrient and macroalgae loads lead to response in seagrass indicator properties. Marine Pollution Bulletin, 2016, 106: 174-182
[29] Xue Y-C (薛允传), Gao S (高抒), Jia J-J (贾建军). Bedload transport within the ebb channel of a tidal inlet system, Swan Lake, Shandong Peninsula, China. Oceanologia et Limnologia Sinica (海洋与湖沼), 2002, 33(4): 354-363 (in Chinese)
[30] Jia J-J (贾建军), Gao S (高抒), Xue Y-C (薛允传). Patterns of time-velocity asymmetry at the Yuehu Inlet, Shandong Peninsula, China. Acta Oceanologica Sinica (海洋学报), 2003, 25(3): 68-76 (in Chinese)
[31] Liu J (柳杰). Effects of Different Environmental Conditions on the Growth and Photosynthetic Pigment Contents of Zostera marina L. in Swan Lake. PhD Thesis. Qingdao: Ocean University of China (中国海洋大学), 2011 (in Chinese)
[32] Qin LZ, Li WT, Zhang X, et al. Recovery of the eelgrass Zostera marina following intense Manila clam Ruditapes philippinarum harvesting disturbance in China: The role and fate of seedlings. Aquatic Botany, 2016, 130: 27-36
[33] Yang X, Yuan X, Zhang A, et al. Spatial distribution and sources of heavy metals and petroleum hydrocarbon in the sand flats of Shuangtaizi Estuary, Bohai Sea of China. Marine Pollution Bulletin, 2015, 95: 503-512
[34] Valladares F, Wright SJ, Lasso E, et al. Plastic phenotypic response to light of 16 congeneric shrubs from a Panamanian rainforest. Ecology, 2000, 81: 1925-1936
[35] Bardgett RD, McAlister E. The measurement of soil fungal: Bacterial biomass ratios as an indicator of ecosystem self-regulation in temperate meadow grasslands. Biology and Fertility of Soils, 1999, 29: 282-290
[36] Sultan SE, Wilczek AM, Bell DL, et al. Physiological response to complex environments in annual Polygonum species of contrasting ecological breadth. Oecologia, 1998, 115: 564-578
[37] Maxwell PS, Pitt KA, Burfeind DD, et al. Phenotypic plasticity promotes persistence following severe events: Physiological and morphological responses of seagrass to flooding. Journal of Ecology, 2014, 102: 54-64
[38] McDonald AM, Prado P, Heck KL, et al. Seagrass growth, reproductive, and morphological plasticity across environmental gradients over a large spatial scale. Aquatic Botany, 2016, 134: 87-96
[39] Sandoval-Gil J, Alexandre A, Santos R, et al. Nitrogen uptake and internal recycling in Zostera marina exposed to oyster farming: Eelgrass potential as a natural biofilter. Estuaries and Coasts, 2016, 39: 1694-1708
[40] Wu G-L (武高林), Chen M (陈敏), Du G-Z (杜国祯). Effects of nutrient and light on seedlings morphological plasticity of four Saussurea species with diffe-rent ecological breadth. Chinese Journal of Applied Ecolo-gy (应用生态学报), 2008, 19(8): 1708-1713 (in Chinese)
[41] Zhang P-D (张沛东), Sun Y (孙燕), Niu S-N (牛淑娜), et al. Research progress in seed dormancy, germination, and seeding growth and related affecting factors. Chinese Journal of Applied Ecology (应用生态学报), 2011, 22(11): 3060-3066 (in Chinese)
[42] Wu G-L (武高林), Chen M (陈敏), Du G-Z (杜国祯). Response of biomass allocation and morphological characteristics to light and nutrient resources for seedlings of three alpine species. Acta Ecologica Sinica (生态学报), 2010, 30(1): 60-66 (in Chinese)
[43] Yan X-F (闫兴富), Liu J-L (刘建利), Bei Z-L (贝盏临), et al. Characteristics of seed germination and seedling growth of Caragana korshinskii under different light intensities. Chinese Journal of Ecology (生态学杂志), 2015, 34(4): 912-918 (in Chinese)
[44] Salo T, Pedersen MF. Synergistic effects of altered sali-nity and temperature on estuarine eelgrass (Zostera marina) seedlings and clonal shoots. Journal of Experimental Marine Biology and Ecology, 2014, 457: 143-150
[45] Olesen B, Krause-Jensen D, Christensen PB. Depth-related changes in reproductive strategy of a cold-tempe-rate Zostera marina meadow. Estuaries and Coasts, 2016, doi: 10.1007/s12237-016-0155-4
[46] Cabaco S, Santos R. Seagrass reproductive effort as an ecological indicator of disturbance. Ecological Indicators, 2012, 23: 116-122
[47] Eckert CG, Dorken ME, Barrett SCH. Ecological and evolutionary consequences of sexual and clonal reproduction in aquatic plants. Aquatic Botany, 2016, 135: 46-61
[48] Zhang X-M (张晓梅), Zhou Y (周毅), Wang F (王峰), et al. Ecological characteristics of Zostera japonica population in Swan Lake of Rongcheng, Shandong Province of China. Chinese Journal of Applied Eco-logy (应用生态学报), 2013, 24(7): 2033-2039 (in Chinese)
[49] Pascarella JB. Hurricane disturbance, plant-animal interactions, and the reproductive success of a tropical shrub. Biotropica, 1998, 30: 416-424
[50] Kim JY, Kim GY, Do Y, et al. Effects of monsoon on topography, soil variables, and coastal plants. Estuaries and Coasts, 2015, 38: 494-505
[51] Jarvis JC. Function of Seed-bank Ecology in Mid-Atlantic Semi-annual and Perennial Zostera marina Beds. PhD Thesis. Seattle, WA: University of Washington, 2009
[52] Keddy CJ, Patriquin DG. An annual form of eelgrass in Nova Scotia. Aquatic Botany, 1978, 5: 163-170