Sequencing Ultraconserved Elements (UCEs) for Marine Population Genomics: A Proof-of-Concept Using a Deep-Sea Mussel Species

Yi-Xuan LI; Ting XU; Maeva PEREZ; Chong CHEN; Hiromi Kayama WATANABE; Jack Chi-Ho IP; Jian-Wen QIU

doi:10.1111/eva.70195

Sequencing Ultraconserved Elements (UCEs) for Marine Population Genomics: A Proof-of-Concept Using a Deep-Sea Mussel Species

Yi-Xuan LI
, Ting XU
, Maeva PEREZ
, Chong CHEN
, Hiromi Kayama WATANABE
, Jack Chi-Ho IP
, Jian-Wen QIU^*

^*Corresponding author for this work

Division of Science

Research output: Journal Publications › Journal Article (refereed) › peer-review

Abstract

Ultraconserved elements (UCEs) have emerged as a powerful tool for resolving deep evolutionary relationships due to their low DNA quality requirements and broad taxonomic applicability. While their utility for intraspecific and shallow-divergence studies is growing, only a few studies have explored their performance in marine taxa, some of them with metapopulations spanning thousands of kilometers. Here, we employed the UCE approach to investigate the population genomics of Gigantidas platifrons—a deep-sea mussel with a long larval dispersal period that exhibits a panmictic genetic structure across its extensive distribution range in the chemosynthetic ecosystems of the Western Pacific. With its published whole genome and prior restriction site-associated DNA sequencing using IIB restriction enzymes (2b-RAD seq) study, this species is an excellent candidate for evaluating the effectiveness of UCEs. We conducted UCE target capture sequencing on 123 individuals collected from two hydrocarbon seeps and four hydrothermal vents, yielding 1960 UCEs. To assess the impact of different reference choices, we identified 11,870 single-nucleotide polymorphisms (SNPs) by mapping against the published genome and 8936 SNPs by mapping to the representative 1960 UCEs. Both datasets were similar, with over 80% of the SNPs located in intronic and intergenic regions. Analyses based on both datasets consistently implied a clear genetic divergence between the South China Sea (SCS) and Okinawa Trough-Sagami Bay (OT-SB) populations, with predominant gene flow from OT to SB, consistent with previously published 2b-RAD seq findings. Additionally, UCE-based SNPs identified a dynamic decline in population size for individuals in the three regions and revealed selective adaptation signals to their environments. Overall, our study serves as a proof-of-concept demonstrating that UCEs provide a comparable resolution to RAD-Seq in detecting shallow-level genetic divergence and delineating conservation units in a high-dispersal marine species, even when lacking a sequenced genome.

Original language	English
Article number	e70195
Journal	Evolutionary Applications
Volume	19
Issue number	1
Early online date	13 Jan 2026
DOIs	https://doi.org/10.1111/eva.70195
Publication status	Published - Jan 2026

Bibliographical note

We thank the captains and crews of R/Vs Natsushima, Kaiyo, and Xiangyanghong 9 and the operation teams of HOV Jiaolong and Hyper-Dolphin for sampling during the relevant research cruises. We thank the cruise chief scientists for leading the relevant cruises: Ken Takai (JAMSTEC), KY14-01; Shinsuke Kawagucci (JAMSTEC), KY14-02; Hidetaka Nomaki (JAMSTEC), KY11-01 Leg 1; Hiroshi Miyake (Kitasato University), KY11-02 Leg 2; Katsunori Fujikura (JAMSTEC), and NT09-06 Leg 1. Bioinformatic analyses were conducted using high-performance servers at the Department of Biology at Hong Kong Baptist University.

Publisher Copyright:
© 2026 The Author(s). Evolutionary Applications published by John Wiley & Sons Ltd.

Funding

We acknowledge the financial support from the Research Grants Council of Hong Kong: General Research Fund (grant numbers 12101021, 12102222, and 16309324) and Collaborative Research Fund (grant number C2013‐22GF). Natsushima Kaiyo Xiangyanghong 9 Jiaolong Hyper‐Dolphin

UN SDGs

This output contributes to the following UN Sustainable Development Goals (SDGs)

SDG 14 Life Below Water

Keywords

bivalves
deep sea
population genetics
pseudoreference
target capture

Access to Document

10.1111/eva.70195Licence: CC BY

Cite this

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title = "Sequencing Ultraconserved Elements (UCEs) for Marine Population Genomics: A Proof-of-Concept Using a Deep-Sea Mussel Species",

abstract = "Ultraconserved elements (UCEs) have emerged as a powerful tool for resolving deep evolutionary relationships due to their low DNA quality requirements and broad taxonomic applicability. While their utility for intraspecific and shallow-divergence studies is growing, only a few studies have explored their performance in marine taxa, some of them with metapopulations spanning thousands of kilometers. Here, we employed the UCE approach to investigate the population genomics of Gigantidas platifrons—a deep-sea mussel with a long larval dispersal period that exhibits a panmictic genetic structure across its extensive distribution range in the chemosynthetic ecosystems of the Western Pacific. With its published whole genome and prior restriction site-associated DNA sequencing using IIB restriction enzymes (2b-RAD seq) study, this species is an excellent candidate for evaluating the effectiveness of UCEs. We conducted UCE target capture sequencing on 123 individuals collected from two hydrocarbon seeps and four hydrothermal vents, yielding 1960 UCEs. To assess the impact of different reference choices, we identified 11,870 single-nucleotide polymorphisms (SNPs) by mapping against the published genome and 8936 SNPs by mapping to the representative 1960 UCEs. Both datasets were similar, with over 80\% of the SNPs located in intronic and intergenic regions. Analyses based on both datasets consistently implied a clear genetic divergence between the South China Sea (SCS) and Okinawa Trough-Sagami Bay (OT-SB) populations, with predominant gene flow from OT to SB, consistent with previously published 2b-RAD seq findings. Additionally, UCE-based SNPs identified a dynamic decline in population size for individuals in the three regions and revealed selective adaptation signals to their environments. Overall, our study serves as a proof-of-concept demonstrating that UCEs provide a comparable resolution to RAD-Seq in detecting shallow-level genetic divergence and delineating conservation units in a high-dispersal marine species, even when lacking a sequenced genome.",

keywords = "bivalves, deep sea, population genetics, pseudoreference, target capture",

author = "Yi-Xuan LI and Ting XU and Maeva PEREZ and Chong CHEN and WATANABE, \{Hiromi Kayama\} and IP, \{Jack Chi-Ho\} and Jian-Wen QIU",

note = "We thank the captains and crews of R/Vs Natsushima, Kaiyo, and Xiangyanghong 9 and the operation teams of HOV Jiaolong and Hyper-Dolphin for sampling during the relevant research cruises. We thank the cruise chief scientists for leading the relevant cruises: Ken Takai (JAMSTEC), KY14-01; Shinsuke Kawagucci (JAMSTEC), KY14-02; Hidetaka Nomaki (JAMSTEC), KY11-01 Leg 1; Hiroshi Miyake (Kitasato University), KY11-02 Leg 2; Katsunori Fujikura (JAMSTEC), and NT09-06 Leg 1. Bioinformatic analyses were conducted using high-performance servers at the Department of Biology at Hong Kong Baptist University. Publisher Copyright: {\textcopyright} 2026 The Author(s). Evolutionary Applications published by John Wiley \& Sons Ltd.",

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AU - PEREZ, Maeva

AU - CHEN, Chong

AU - WATANABE, Hiromi Kayama

AU - IP, Jack Chi-Ho

AU - QIU, Jian-Wen

N1 - We thank the captains and crews of R/Vs Natsushima, Kaiyo, and Xiangyanghong 9 and the operation teams of HOV Jiaolong and Hyper-Dolphin for sampling during the relevant research cruises. We thank the cruise chief scientists for leading the relevant cruises: Ken Takai (JAMSTEC), KY14-01; Shinsuke Kawagucci (JAMSTEC), KY14-02; Hidetaka Nomaki (JAMSTEC), KY11-01 Leg 1; Hiroshi Miyake (Kitasato University), KY11-02 Leg 2; Katsunori Fujikura (JAMSTEC), and NT09-06 Leg 1. Bioinformatic analyses were conducted using high-performance servers at the Department of Biology at Hong Kong Baptist University. Publisher Copyright: © 2026 The Author(s). Evolutionary Applications published by John Wiley & Sons Ltd.

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N2 - Ultraconserved elements (UCEs) have emerged as a powerful tool for resolving deep evolutionary relationships due to their low DNA quality requirements and broad taxonomic applicability. While their utility for intraspecific and shallow-divergence studies is growing, only a few studies have explored their performance in marine taxa, some of them with metapopulations spanning thousands of kilometers. Here, we employed the UCE approach to investigate the population genomics of Gigantidas platifrons—a deep-sea mussel with a long larval dispersal period that exhibits a panmictic genetic structure across its extensive distribution range in the chemosynthetic ecosystems of the Western Pacific. With its published whole genome and prior restriction site-associated DNA sequencing using IIB restriction enzymes (2b-RAD seq) study, this species is an excellent candidate for evaluating the effectiveness of UCEs. We conducted UCE target capture sequencing on 123 individuals collected from two hydrocarbon seeps and four hydrothermal vents, yielding 1960 UCEs. To assess the impact of different reference choices, we identified 11,870 single-nucleotide polymorphisms (SNPs) by mapping against the published genome and 8936 SNPs by mapping to the representative 1960 UCEs. Both datasets were similar, with over 80% of the SNPs located in intronic and intergenic regions. Analyses based on both datasets consistently implied a clear genetic divergence between the South China Sea (SCS) and Okinawa Trough-Sagami Bay (OT-SB) populations, with predominant gene flow from OT to SB, consistent with previously published 2b-RAD seq findings. Additionally, UCE-based SNPs identified a dynamic decline in population size for individuals in the three regions and revealed selective adaptation signals to their environments. Overall, our study serves as a proof-of-concept demonstrating that UCEs provide a comparable resolution to RAD-Seq in detecting shallow-level genetic divergence and delineating conservation units in a high-dispersal marine species, even when lacking a sequenced genome.

AB - Ultraconserved elements (UCEs) have emerged as a powerful tool for resolving deep evolutionary relationships due to their low DNA quality requirements and broad taxonomic applicability. While their utility for intraspecific and shallow-divergence studies is growing, only a few studies have explored their performance in marine taxa, some of them with metapopulations spanning thousands of kilometers. Here, we employed the UCE approach to investigate the population genomics of Gigantidas platifrons—a deep-sea mussel with a long larval dispersal period that exhibits a panmictic genetic structure across its extensive distribution range in the chemosynthetic ecosystems of the Western Pacific. With its published whole genome and prior restriction site-associated DNA sequencing using IIB restriction enzymes (2b-RAD seq) study, this species is an excellent candidate for evaluating the effectiveness of UCEs. We conducted UCE target capture sequencing on 123 individuals collected from two hydrocarbon seeps and four hydrothermal vents, yielding 1960 UCEs. To assess the impact of different reference choices, we identified 11,870 single-nucleotide polymorphisms (SNPs) by mapping against the published genome and 8936 SNPs by mapping to the representative 1960 UCEs. Both datasets were similar, with over 80% of the SNPs located in intronic and intergenic regions. Analyses based on both datasets consistently implied a clear genetic divergence between the South China Sea (SCS) and Okinawa Trough-Sagami Bay (OT-SB) populations, with predominant gene flow from OT to SB, consistent with previously published 2b-RAD seq findings. Additionally, UCE-based SNPs identified a dynamic decline in population size for individuals in the three regions and revealed selective adaptation signals to their environments. Overall, our study serves as a proof-of-concept demonstrating that UCEs provide a comparable resolution to RAD-Seq in detecting shallow-level genetic divergence and delineating conservation units in a high-dispersal marine species, even when lacking a sequenced genome.

KW - bivalves

KW - deep sea

KW - population genetics

KW - pseudoreference

KW - target capture

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DO - 10.1111/eva.70195

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AN - SCOPUS:105027544061

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ER -

Sequencing Ultraconserved Elements (UCEs) for Marine Population Genomics: A Proof-of-Concept Using a Deep-Sea Mussel Species

Abstract

Bibliographical note

Funding

UN SDGs

Keywords

Access to Document

Other files and links

Fingerprint

(Non-LU) Genomic Insights into Environmental Adaptation and Diversity of Deep-sea Siboglinidae

Cite this

Sequencing Ultraconserved Elements (UCEs) for Marine Population Genomics: A Proof-of-Concept Using a Deep-Sea Mussel Species

Abstract

Bibliographical note

Funding

UN SDGs

Keywords

Access to Document

Other files and links

Fingerprint

Projects

(Non-LU) Genomic Insights into Environmental Adaptation and Diversity of Deep-sea Siboglinidae

Cite this