Three-dimensional conservation planning of fish biodiversity metrics to achieve the deep-sea 30×30 conservation target.

IF 5.2 1区 环境科学与生态学 Q1 BIODIVERSITY CONSERVATION
Laetitia Mathon, Florian Baletaud, Anne Lebourges-Dhaussy, Gaël Lecellier, Christophe Menkes, Céline Bachelier, Claire Bonneville, Tony Dejean, Mahé Dumas, Sylvie Fiat, Jacques Grelet, Jérémie Habasque, Stéphanie Manel, Laura Mannocci, David Mouillot, Maëlis Peran, Gildas Roudaut, Christine Sidobre, David Varillon, Laurent Vigliola
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引用次数: 0

Abstract

Accelerating rate of human impact and environmental change severely affects marine biodiversity and increases the urgency to implement the Convention on Biological Diversity (CBD) 30×30 plan for conserving 30% of sea areas by 2030. However, area-based conservation targets are complex to identify in a 3-dimensional (3D) ocean where deep-sea features such as seamounts have been seldom studied mostly due to challenging methodologies to implement at great depths. Yet, the use of emerging technologies, such as environmental DNA combined with modern modeling frameworks, could help address the problem. We collected environmental DNA, echosounder acoustic, and video data at 15 seamounts and deep island slopes across the Coral Sea. We modeled 7 fish community metrics and the abundances of 45 individual species and molecular operational taxonomic units (MOTUs) in benthic and pelagic waters (down to 600-m deep) with boosted regression trees and generalized joint attribute models to describe biodiversity on seamounts and deep slopes and identify 3D protection solutions for achieving the CBD area target in New Caledonia (1.4 million km2). We prioritized the identified conservation units in a 3D space, based on various biodiversity targets, to meet the goal of protecting at least 30% of the spatial domain, with a focus on areas with high biodiversity. The relationship between biodiversity protection targets and the spatial area protected by the solution was linear. The scenario protecting 30% of each biodiversity metric preserved almost 30% of the considered spatial domain and accounted for the 3D distribution of biodiversity. Our study paves the way for the use of combined data collection methodologies to improve biodiversity estimates in 3D structured marine environments for the selection of conservation areas and for the use of biodiversity targets to achieve area-based international targets.

鱼类生物多样性指标的三维保护规划,以实现深海 30×30 保护目标。
人类影响和环境变化速度的加快严重影响了海洋生物多样性,也增加了实施《生物多样性公约》(CBD)30×30 计划的紧迫性,即到 2030 年保护 30% 的海域。然而,在三维(3D)海洋中确定基于区域的保护目标非常复杂,而在三维海洋中,海隆等深海特征很少被研究,这主要是由于在深海中实施方法具有挑战性。然而,环境 DNA 等新兴技术与现代建模框架的结合使用有助于解决这一问题。我们在珊瑚海的 15 座海山和深岛斜坡收集了环境 DNA、回声测深仪声学和视频数据。我们利用提升回归树和广义联合属性模型对海底和中上层水域(深达 600 米)的 7 个鱼类群落指标以及 45 个物种和分子操作分类单元(MOTU)的丰度进行了建模,以描述海山和深坡的生物多样性,并为实现新喀里多尼亚生物多样性公约的面积目标(140 万平方公里)确定三维保护方案。我们根据不同的生物多样性目标,在三维空间中对确定的保护单位进行了优先排序,以实现保护至少 30% 的空间领域的目标,重点是生物多样性较高的区域。生物多样性保护目标与解决方案保护的空间面积之间呈线性关系。保护每个生物多样性指标 30% 的方案保护了近 30% 的空间区域,并考虑到了生物多样性的三维分布。我们的研究为利用综合数据收集方法改进三维结构海洋环境中的生物多样性估算,以选择保护区域和利用生物多样性目标实现基于区域的国际目标铺平了道路。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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来源期刊
Conservation Biology
Conservation Biology 环境科学-环境科学
CiteScore
12.70
自引率
3.20%
发文量
175
审稿时长
2 months
期刊介绍: Conservation Biology welcomes submissions that address the science and practice of conserving Earth's biological diversity. We encourage submissions that emphasize issues germane to any of Earth''s ecosystems or geographic regions and that apply diverse approaches to analyses and problem solving. Nevertheless, manuscripts with relevance to conservation that transcend the particular ecosystem, species, or situation described will be prioritized for publication.
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