Integrating Science into Aquatic Conservation

33. Integrating_Science_into_Aquatic_Conservation.jpg

Dublin Core

Title

Integrating Science into Aquatic Conservation

Subject

Mischief Reef; Pinctada fucata; introduced population; geographic origin; population genetics; Quasipaa spinosa; MaxEnt; ArcGIS; potential habitat; environment variable; marine protected areas; connectivity; larval dispersal; biophysical modeling; network; Pelodiscus sinensis; mitochondrial genome; structural variation; control region; phylogenetic relationship; parrotfish; mitogenome; gene rearrangement; phylogeny; divergence time; population structure; East China Sea; South China Sea; horn-eyed ghost crab; conservation; Siamese crocodile; saltwater crocodile; introgression; hybridization; post-occipital scutes; yellow cheek carp; leptin; gene structure; tissue expression; fasting and refeeding; polychaete; biological invasions; distribution; aquaculture; vessel biofouling; ballast; molecular systematics; overfishing; habitat decline; individual size; food habits; conservation status; passive acoustic monitoring; remote monitoring; remote census; Spheniscus demersus; vocalisations; Holocentridae; mitogenome; codon usage; gene rearrangement; phylogeny; selection pressure; marine fish; ancient lineages; mitogenome; phylogeny; evolution; oceanography

Description

As a key support for human survival and development, how to protect aquatic ecosystems is a hotspot of global concern. This Special Issue was built with the hope of providing scientific references for the conservation of aquatic organisms and ecosystems. Papers cover both freshwater and marine ecosystems, focusing on a single species and multiple species or specific ecosystems. For single-species studies mainly used molecular tools and statistic models to focus on the evolutionary relationships among species, the differentiations among populations within species, and the responses of species to the environment changes. The results of these studies shed light on the evolution, spatial dispersal, and future changes of these species and provided recommendations for the management of population dynamics in these study populations. In multi-species research, biophysical modeling, acoustic technology, and ground surveys were mainly used to predict biodiversity in ecosystems, spatial distribution of different species, and population connectivity among communities. The results of these multi-species studies revealed the spatial patterns of biodiversity, community composition, and ecological corridors from different perspectives, which offer a direct reference for the selection and delineation of marine protected areas. In summary, these papers utilized different tools to reveal the changes or threads faced by important components of water ecosystems from the micro to macro level and provide scientific advice for the conservation and management of protected animals and ecosystems on different spatial scales from local to global.

Creator

Cong Zeng (editor)
Deliang Li (editor)

Publisher

MDPI - Multidisciplinary Digital Publishing Institute

Date

2024

Contributor

Jadik Wijayanto

Rights

© by the authors

Relation

https://res.mdpi.com/bookfiles/book/8828/Integrating_Science_into_Aquatic_Conservation.pdf?v=1709043456

Format

PDF

Language

English

Type

Textbooks

Identifier

ISBN : 978-3-7258-0221-0 (Hardback)
ISBN : 978-3-7258-0222-7 (PDF)
DOI : https://doi.org/10.3390/books978-3-7258-0222-7

Coverage

Basel, Switzerland, 2024

Document Viewer