Ecology and Environment Research Centre, Department of Natural Sciences, Faculty of Science and Engineering, Manchester Metropolitan University, Manchester, UK.
School of Science, Engineering and Environment, University of Salford, Salford, UK.
Am J Bot. 2021 Aug;108(8):1331-1342. doi: 10.1002/ajb2.1715. Epub 2021 Aug 29.
Host-plant genetic variation can shape associated communities of organisms. These community-genetic effects include (1) genetically similar hosts harboring similar associated communities (i.e., the genetic similarity rule) and (2) host-plant heterozygosity increasing associated community diversity. Community-genetic effects are predicted to be less prominent in plant systems with limited genetic variation, such as those at distributional range limits. Yet, empirical evidence from such systems is limited.
We sampled a natural population of a mangrove foundation species (Avicennia germinans) at an expanding range limit in Florida, USA. We measured genetic variation within and among 40 host trees with 24 nuclear microsatellite loci and characterized their foliar endophytic fungal communities with internal transcribed spacer (ITS1) gene amplicon sequencing. We evaluated relationships among host-tree genetic variation, host-tree spatial location, and the associated fungal communities.
Genetic diversity was low across all host trees (mean: 2.6 alleles per locus) and associated fungal communities were relatively homogeneous (five sequence variants represented 78% of all reads). We found (1) genetically similar host trees harbored similar fungal communities, with no detectable effect of interhost geographic distance. (2) Host-tree heterozygosity had no detectable effect, while host-tree absolute spatial location affected community alpha diversity.
This research supports the genetic similarity rule within a range limit population and helps broaden the current scope of community genetics theory by demonstrating that community-genetic effects can occur even at expanding distributional limits where host-plant genetic variation may be limited. Our findings also provide the first documentation of community-genetic effects in a natural mangrove system.
宿主植物遗传变异可以塑造相关的生物群落。这些群落-遗传效应包括(1)遗传相似的宿主拥有相似的相关群落(即遗传相似性法则),以及(2)宿主植物杂合性增加相关群落多样性。群落-遗传效应在遗传变异有限的植物系统中预计不太明显,例如分布范围限制的系统。然而,来自这些系统的经验证据有限。
我们在美国佛罗里达州的一个红树林基础物种(Avicennia germinans)的扩展分布范围限制处,对一个自然种群进行了采样。我们使用 24 个核微卫星基因座,对 40 株宿主树木的遗传变异进行了测量,并通过内部转录间隔区(ITS1)基因扩增子测序,对其叶片内生真菌群落进行了特征描述。我们评估了宿主树遗传变异、宿主树空间位置和相关真菌群落之间的关系。
所有宿主树的遗传多样性都很低(平均值:每个基因座 2.6 个等位基因),相关的真菌群落相对单一(5 个序列变异体代表了所有读数的 78%)。我们发现:(1)遗传相似的宿主树拥有相似的真菌群落,宿主间地理距离没有明显影响。(2)宿主树杂合性没有明显影响,而宿主树绝对空间位置影响群落的 alpha 多样性。
这项研究支持了在分布范围限制种群中的遗传相似性法则,并通过证明群落-遗传效应甚至可以在宿主植物遗传变异可能有限的扩展分布限制处发生,帮助拓宽了当前群落遗传学理论的范围。我们的研究结果还首次提供了自然红树林系统中群落-遗传效应的证据。
