Trophic niche partitioning in giant clams

Isis GUIBERT; Inga Elizabeth CONTI-JERPE; Leonard PONS; Kuselah TAYABAN; Sherry Lyn SAYCO; Patrick CABAITAN; Cecilia CONACO; David Michael BAKER

doi:10.1038/s42003-025-09313-z

Trophic niche partitioning in giant clams

Isis GUIBERT
, Inga Elizabeth CONTI-JERPE
, Leonard PONS
, Kuselah TAYABAN
, Sherry Lyn SAYCO
, Patrick CABAITAN
, Cecilia CONACO
, David Michael BAKER^*

^*Corresponding author for this work

Division of Science

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

Abstract

Ecosystems are influenced by competition for limited resources, a driver of niche partitioning. Over time, the emergence of novel traits facilitating new resource exploitation can reduce competition. However, additional layers of complexity, like symbiosis, complicate our understanding of the patterns shaping reef communities. Therefore, empirical evidence of niche partitioning reducing competition in symbiotic benthic communities is limited. Using a unique common garden experiment, we examined the nutritional strategies of six giant clam holobionts and characterized their symbiont assemblages. Variation in trophic strategies confirmed trophic niche partitioning, as species fell along a continuum from highly heterotrophic to highly autotrophic. Tridacna gigas and T. derasa, listed as critically endangered and endangered, respectively, were the most autotrophic and fast-growing species. We found significant phylogenetic signals in trophic niche scores, growth rate, and shell length, indicating the role of natural selection in shaping giant clam nutritional ecology. We conclude that niche partitioning is a driver of giant clam evolution with benefits and costs; high autotrophy reliance results in greater growth rates yet may increase vulnerability to disturbances. Given the impact of human activities on giant clams, conservation efforts should focus on these ecosystem engineers, especially highly autotrophic and geographically constrained species.

Original language	English
Journal	Communications Biology
DOIs	https://doi.org/10.1038/s42003-025-09313-z
Publication status	E-pub ahead of print - 6 Dec 2025

Bibliographical note

We deeply thank Dr. R. Estrellada, Director of the Semirara Marine Hatchery Laboratory (SMHL), as well as the staff of SMHL for hosting Dr. I. Guibert and for field assistance; J. I. P. Baquiran for logistics in the field; O. So for helping with all necessary orders; A. Y. T. Chan for technical assistance at the University of Hong Kong; Dr. O. Habimana for lending materials; and Dr. S. McIlroy for valuable discussion.

Funding

This study was funded by the University of Hong Kong Division of Ecology and Biodiversity PDF Research Award, by the General Research Fund (GRF-17108620), by the Environment and Conservation Fund and the Collaborative Research Fund (ECF-67/2016 and CRF7G_C7013-19G) and by the Department of Science and Technology Philippine Council for Agriculture, Aquatic and Natural Resources Research and Development (DOST-PCAARRD; QMSR-MRRD-MEC-295-1449, 314-1542 and 314-1545).

Keywords

Community ecology
Evolutionary ecology
Molecular ecology
Stable isotope analysis

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https://www.nature.com/articles/s42003-025-09313-z

Cite this

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title = "Trophic niche partitioning in giant clams",

abstract = "Ecosystems are influenced by competition for limited resources, a driver of niche partitioning. Over time, the emergence of novel traits facilitating new resource exploitation can reduce competition. However, additional layers of complexity, like symbiosis, complicate our understanding of the patterns shaping reef communities. Therefore, empirical evidence of niche partitioning reducing competition in symbiotic benthic communities is limited. Using a unique common garden experiment, we examined the nutritional strategies of six giant clam holobionts and characterized their symbiont assemblages. Variation in trophic strategies confirmed trophic niche partitioning, as species fell along a continuum from highly heterotrophic to highly autotrophic. Tridacna gigas and T. derasa, listed as critically endangered and endangered, respectively, were the most autotrophic and fast-growing species. We found significant phylogenetic signals in trophic niche scores, growth rate, and shell length, indicating the role of natural selection in shaping giant clam nutritional ecology. We conclude that niche partitioning is a driver of giant clam evolution with benefits and costs; high autotrophy reliance results in greater growth rates yet may increase vulnerability to disturbances. Given the impact of human activities on giant clams, conservation efforts should focus on these ecosystem engineers, especially highly autotrophic and geographically constrained species.",

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author = "Isis GUIBERT and CONTI-JERPE, \{Inga Elizabeth\} and Leonard PONS and Kuselah TAYABAN and SAYCO, \{Sherry Lyn\} and Patrick CABAITAN and Cecilia CONACO and BAKER, \{David Michael\}",

note = "We deeply thank Dr. R. Estrellada, Director of the Semirara Marine Hatchery Laboratory (SMHL), as well as the staff of SMHL for hosting Dr. I. Guibert and for field assistance; J. I. P. Baquiran for logistics in the field; O. So for helping with all necessary orders; A. Y. T. Chan for technical assistance at the University of Hong Kong; Dr. O. Habimana for lending materials; and Dr. S. McIlroy for valuable discussion.",

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language = "English",

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AU - GUIBERT, Isis

AU - CONTI-JERPE, Inga Elizabeth

AU - PONS, Leonard

AU - TAYABAN, Kuselah

AU - SAYCO, Sherry Lyn

AU - CABAITAN, Patrick

AU - CONACO, Cecilia

AU - BAKER, David Michael

N1 - We deeply thank Dr. R. Estrellada, Director of the Semirara Marine Hatchery Laboratory (SMHL), as well as the staff of SMHL for hosting Dr. I. Guibert and for field assistance; J. I. P. Baquiran for logistics in the field; O. So for helping with all necessary orders; A. Y. T. Chan for technical assistance at the University of Hong Kong; Dr. O. Habimana for lending materials; and Dr. S. McIlroy for valuable discussion.

PY - 2025/12/6

Y1 - 2025/12/6

N2 - Ecosystems are influenced by competition for limited resources, a driver of niche partitioning. Over time, the emergence of novel traits facilitating new resource exploitation can reduce competition. However, additional layers of complexity, like symbiosis, complicate our understanding of the patterns shaping reef communities. Therefore, empirical evidence of niche partitioning reducing competition in symbiotic benthic communities is limited. Using a unique common garden experiment, we examined the nutritional strategies of six giant clam holobionts and characterized their symbiont assemblages. Variation in trophic strategies confirmed trophic niche partitioning, as species fell along a continuum from highly heterotrophic to highly autotrophic. Tridacna gigas and T. derasa, listed as critically endangered and endangered, respectively, were the most autotrophic and fast-growing species. We found significant phylogenetic signals in trophic niche scores, growth rate, and shell length, indicating the role of natural selection in shaping giant clam nutritional ecology. We conclude that niche partitioning is a driver of giant clam evolution with benefits and costs; high autotrophy reliance results in greater growth rates yet may increase vulnerability to disturbances. Given the impact of human activities on giant clams, conservation efforts should focus on these ecosystem engineers, especially highly autotrophic and geographically constrained species.

AB - Ecosystems are influenced by competition for limited resources, a driver of niche partitioning. Over time, the emergence of novel traits facilitating new resource exploitation can reduce competition. However, additional layers of complexity, like symbiosis, complicate our understanding of the patterns shaping reef communities. Therefore, empirical evidence of niche partitioning reducing competition in symbiotic benthic communities is limited. Using a unique common garden experiment, we examined the nutritional strategies of six giant clam holobionts and characterized their symbiont assemblages. Variation in trophic strategies confirmed trophic niche partitioning, as species fell along a continuum from highly heterotrophic to highly autotrophic. Tridacna gigas and T. derasa, listed as critically endangered and endangered, respectively, were the most autotrophic and fast-growing species. We found significant phylogenetic signals in trophic niche scores, growth rate, and shell length, indicating the role of natural selection in shaping giant clam nutritional ecology. We conclude that niche partitioning is a driver of giant clam evolution with benefits and costs; high autotrophy reliance results in greater growth rates yet may increase vulnerability to disturbances. Given the impact of human activities on giant clams, conservation efforts should focus on these ecosystem engineers, especially highly autotrophic and geographically constrained species.

KW - Community ecology

KW - Evolutionary ecology

KW - Molecular ecology

KW - Stable isotope analysis

U2 - 10.1038/s42003-025-09313-z

DO - 10.1038/s42003-025-09313-z

M3 - Journal Article (refereed)

C2 - 41353278

SN - 2399-3642

JO - Communications Biology

JF - Communications Biology

ER -

Trophic niche partitioning in giant clams

Abstract

Bibliographical note

Funding

Keywords

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