Xu Shaochun, Wang Pengmei, Zhou Yi, Zhang Xiaomei, Gu Ruiting, Liu Xujia, Liu Bingjian, Song Xiaoyue, Xu Shuai, Yue Shidong
CAS Key Laboratory of Marine Ecology and Environmental Sciences, Institute of Oceanology, Chinese Academy of Sciences, Qingdao, China.
Laboratory for Marine Ecology and Environmental Science, Qingdao National Laboratory for Marine Science and Technology, Qingdao, China.
Front Plant Sci. 2018 Feb 12;9:15. doi: 10.3389/fpls.2018.00015. eCollection 2018.
Seagrasses are important components of global coastal ecosystems, and the eelgrass L. is widely distributed along the Atlantic and Pacific coasts in the temperate northern hemisphere, but limited datum related to the contribution of sexual reproduction to population recruitment have been reported. This study aimed to understand eelgrass sexual reproduction and population recruitment in Swan Lake (SLL), and Huiquan Bay (HQB) was included for comparison. Random sampling, permanent quadrats or cores and laboratory seed germination-based experimental methods were employed. The flowering, seed production, seed banks, seed germination, seedling survival, and seedling growth of eelgrass were investigated from July 2014 to December 2015 to evaluate the contribution of sexual reproduction to population recruitment. Results indicated a dominant role of asexual reproduction in HQB, while sexual reproduction played a relatively important role in SLL. The highest flowering shoot density in SLL was 517.27 ± 504.29 shoots m (June) and represented 53.34% of the total shoots at the center site. The potential seed output per reproductive shoot and per unit area in SLL were 103.67 ± 37.95 seeds shoot and 53,623.66 ± 19,628.11 seeds m, respectively. The maximum seed bank density in SLL was 552.21 ± 204.94 seeds m (October). Seed germination mainly occurred from the middle of March to the end of May, and the highest seedling density was 296.88 ± 274.27 seedlings m in April. The recruitment from seedlings accounted for 41.36% of the population recruitment at the center site, while the sexual recruitment contribution at the patch site (50.52%) was greater than that at the center site. Seeds in SLL were acclimated to spring germination, while in HQB, they were acclimated to autumn germination (early October-late November). Seed bank density in HQB was very low, with a value of 254.35 ± 613.34 seeds m (early October). However, seeds in HQB were significantly larger and heavier than those in SLL (size: = 0.004; weight: < 0.001). The recruitment from seedlings accounted for as low as 2.53% of the population recruitment in HQB. Our laboratory seed germination experiment, which was conducted in autumn, showed that the seed germination percent in HQB was significantly greater than in SLL at optimal germination temperatures (10 and 15°C; < 0.001). A laboratory seed germination test at suitable temperature may be a potential novel approach to identify the ecological differences among different geographic populations. It is suggested that the population recruitment may have different strategies and adapt to specific local conditions, such as in SLL and HQB, and the temperature regime may control morphological and phonological variations.
海草是全球沿海生态系统的重要组成部分,鳗草广泛分布于北半球温带地区的大西洋和太平洋沿岸,但关于有性繁殖对种群补充贡献的相关数据报道有限。本研究旨在了解天鹅湖(SLL)中鳗草的有性繁殖和种群补充情况,并将汇泉湾(HQB)纳入进行比较。采用了随机抽样、永久样方或土芯以及基于实验室种子萌发的实验方法。对2014年7月至2015年12月期间鳗草的开花、种子生产、种子库、种子萌发、幼苗存活和幼苗生长进行了调查,以评估有性繁殖对种群补充的贡献。结果表明,无性繁殖在汇泉湾占主导地位,而有性繁殖在天鹅湖发挥了相对重要的作用。天鹅湖最高的开花茎密度为517.27±504.29茎/平方米(6月),占中心位点总茎数的53.34%。天鹅湖每个生殖茎和单位面积的潜在种子产量分别为103.67±37.95粒/茎和53,623.66±19,628.11粒/平方米。天鹅湖最大的种子库密度为552.21±204.94粒/平方米(10月)。种子萌发主要发生在3月中旬至5月底,4月最高的幼苗密度为296.88±274.27株/平方米。幼苗补充占中心位点种群补充的41.36%,而斑块位点的有性补充贡献(50.52%)大于中心位点。天鹅湖的种子适应春季萌发,而在汇泉湾,它们适应秋季萌发(10月初至11月底)。汇泉湾的种子库密度非常低,值为254.35±613.34粒/平方米(10月初)。然而,汇泉湾的种子明显比天鹅湖的种子更大更重(大小:P = 0.004;重量:P < 0.001)。幼苗补充在汇泉湾仅占种群补充的2.53%。我们在秋季进行的实验室种子萌发实验表明,在最佳萌发温度(10和15°C;P < 0.001)下,汇泉湾的种子萌发率显著高于天鹅湖。在适宜温度下进行实验室种子萌发试验可能是一种潜在的新方法,用于识别不同地理种群之间的生态差异。建议鳗草种群补充可能有不同的策略并适应特定的当地条件,如在天鹅湖和汇泉湾,温度状况可能控制形态和物候变化。
