Cook Katie M, Yamagiwa Hirotaka, Beger Maria, Masucci Giovanni Diego, Ross Stuart, Lee Hui Yian Theodora, Stuart-Smith Rick D, Reimer James Davis
School of Biology Faculty of Biological Sciences University of Leeds Leeds UK.
Molecular Invertebrate Systematics and Ecology Laboratory Graduate School of Engineering and Science University of the Ryukyus Nishihara Japan.
Ecol Evol. 2022 Mar 22;12(3):e8736. doi: 10.1002/ece3.8736. eCollection 2022 Mar.
Urbanized coral reefs experience anthropogenic disturbances caused by coastal development, pollution, and nutrient runoff, resulting in turbid, marginal conditions in which only certain species can persist. Mortality effects are exacerbated by increasingly regular thermal stress events, leading to shifts towards novel communities dominated by habitat generalists and species with low structural complexity.There is limited data on the turnover processes that occur due to this convergence of anthropogenic stressors, and how novel urban ecosystems are structured both at the community and functional levels. As such, it is unclear how they will respond to future disturbance events.Here, we examine the patterns of coral reef community change and determine whether ecosystem functions provided by specialist species are lost post-disturbance. We present a comparison of community and functional trait-based changes for scleractinian coral genera and reef fish species assemblages subject to coastal development, coastal modification, and mass bleaching between two time periods, 1975-1976 and 2018, in Nakagusuku Bay, Okinawa, Japan.We observed an increase in fish habitat generalists, a dominance shift from branching to massive/sub-massive corals and increasing site-based coral genera richness between years. Fish and coral communities significantly reassembled, but functional trait-based multivariate space remained constant, indicating a turnover of species with similar traits. A compression of coral habitat occurred, with shallow (<5 m) and deep (>8 m) coral genera shifting towards the mid-depths (5-8 m).We show that although reef species assemblages altered post disturbance, new communities retained similar ecosystem functions. This result could be linked to the stressors experienced by urban reefs, which reflect those that will occur at an increasing frequency globally in the near future. Yet, even after shifts to disturbed communities, these fully functioning reef systems may maintain high conservation value.
城市化的珊瑚礁受到沿海开发、污染和营养物质径流等人为干扰,导致水质浑浊、环境边缘化,只有某些物种能够生存。日益频繁的热应激事件加剧了死亡率影响,导致向以栖息地通才和结构复杂性低的物种为主导的新型群落转变。关于由于这些人为压力源的共同作用而发生的更替过程,以及新型城市生态系统在群落和功能层面是如何构建的,数据有限。因此,目前尚不清楚它们将如何应对未来的干扰事件。在此,我们研究珊瑚礁群落变化的模式,并确定干扰后 specialist 物种提供的生态系统功能是否丧失。我们比较了 1975 - 1976 年和 2018 年两个时间段内,日本冲绳中城湾受沿海开发、海岸改造和大规模白化影响的石珊瑚属和珊瑚礁鱼类物种组合在群落和基于功能性状方面的变化。我们观察到鱼类栖息地通才数量增加,珊瑚从分支状向块状/亚块状的优势转变,以及多年间基于地点的珊瑚属丰富度增加。鱼类和珊瑚群落显著重新组合,但基于功能性状的多元空间保持不变,表明具有相似性状的物种发生了更替。珊瑚栖息地出现压缩,浅水区(<5 米)和深水区(>8 米)的珊瑚属向中深度(5 - 8 米)转移。我们表明,尽管干扰后珊瑚礁物种组合发生了改变,但新群落保留了相似的生态系统功能。这一结果可能与城市珊瑚礁所经历的压力源有关,这些压力源反映了在不久的将来全球范围内将越来越频繁发生的情况。然而,即使转变为受干扰的群落,这些功能齐全的珊瑚礁系统仍可能保持较高的保护价值。
