Genomic analyses support locally derived crown-of-thorns seastar outbreaks in the Pacific

• Published in: BMC biology Vol. 23; no. 1; pp. 244 - 15
• Main Authors: Leiva, Carlos, Martín-Huete, Marta, Lemer, Sarah
• Format: Journal Article
• Language: English
• Published: England BioMed Central Ltd 06.08.2025; BioMed Central; BMC
• Subjects: Acanthaster; Analysis; Animals; Climate change; Climatic changes; Connectivity; Coral reef ecology; Coral Reefs; COTS; Datasets; DNA sequencing; Echinodermata - genetics; Environmental aspects; Gene sequencing; Genetic analysis; Genetic diversity; Genomes; Genomic analysis; Genomics; Health aspects; Human influences; Hypotheses; Keystone species; Mitochondrial DNA; Nucleotide sequencing; Outbreaks; Pacific Ocean; Phylogenetics; Phylogenomics; Phylogeny; Population; Population genomics; Populations; Predators; Protection and preservation; Whole genome sequencing; Pacific Ocean; Vanuatu; Fiji; Marshall Islands; Pohnpei; Japan; French Polynesia; Coral reefs; Acanthaster; COTS; Population genomics; Phylogenomics
• ISSN: 1741-7007; 1741-7007
• DOI: 10.1186/s12915-025-02350-4

Crown-of-thorns seastars (COTS, Acanthaster spp.) are the most notorious coral predators, whose devastating outbreaks cause recurrent and extensive coral depletion across Indo-Pacific reefs. However, the spread potential of COTS outbreaks and the anthropogenic role in their initiation have remained a subject of intense debate for over five decades. Here, using low-coverage whole-genome sequences of 247 COTS, we show that Pacific COTS populations are highly structured, indicating that outbreaks do not spread through open ocean, but instead are locally derived. Pacific COTS populations are grouped in three main lineages geographically restricted to Hawai'i, French Polynesia, and the West Pacific, with the latter showing further significant genetic substructure. Phylogenomic analyses indicated that the Hawai'i COTS lineage likely represents a different undescribed species and challenged the species status of both A. cf. solaris and the Eastern Pacific COTS species (A. ellisii), as the latter appeared as the sister group of the French Polynesia COTS lineage. Additionally, we show that current COTS populations present the highest effective sizes of the last million years, suggesting that human and/or climate change may influence COTS population sizes. Overall, our study highlights the improvements brought by low-coverage whole-genome sequencing approaches in resolving the phylogeny and connectivity patterns of a keystone species in understudied regions of the Pacific Ocean.