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Distinct genomic routes underlie transitions to specialised symbiotic lifestyles in deep-sea annelid worms

Author

Listed:
  • Giacomo Moggioli

    (Queen Mary University of London)

  • Balig Panossian

    (Queen Mary University of London)

  • Yanan Sun

    (The Hong Kong University of Science and Technology
    Hong Kong Baptist University
    Southern Marine Science and Engineering Guangdong Laboratory (Guangzhou))

  • Daniel Thiel

    (University of Exeter)

  • Francisco M. Martín-Zamora

    (Queen Mary University of London)

  • Martin Tran

    (Queen Mary University of London)

  • Alexander M. Clifford

    (University of California, San Diego)

  • Shana K. Goffredi

    (Occidental College)

  • Nadezhda Rimskaya-Korsakova

    (Friedrich Schiller University Jena, Faculty of Biological Sciences, Institute of Zoology and Evolutionary Research)

  • Gáspár Jékely

    (University of Exeter)

  • Martin Tresguerres

    (University of California, San Diego)

  • Pei-Yuan Qian

    (The Hong Kong University of Science and Technology
    Southern Marine Science and Engineering Guangdong Laboratory (Guangzhou))

  • Jian-Wen Qiu

    (Hong Kong Baptist University
    Southern Marine Science and Engineering Guangdong Laboratory (Guangzhou))

  • Greg W. Rouse

    (University of California, San Diego)

  • Lee M. Henry

    (Queen Mary University of London)

  • José M. Martín-Durán

    (Queen Mary University of London)

Abstract

Bacterial symbioses allow annelids to colonise extreme ecological niches, such as hydrothermal vents and whale falls. Yet, the genetic principles sustaining these symbioses remain unclear. Here, we show that different genomic adaptations underpin the symbioses of phylogenetically related annelids with distinct nutritional strategies. Genome compaction and extensive gene losses distinguish the heterotrophic symbiosis of the bone-eating worm Osedax frankpressi from the chemoautotrophic symbiosis of deep-sea Vestimentifera. Osedax’s endosymbionts complement many of the host’s metabolic deficiencies, including the loss of pathways to recycle nitrogen and synthesise some amino acids. Osedax’s endosymbionts possess the glyoxylate cycle, which could allow more efficient catabolism of bone-derived nutrients and the production of carbohydrates from fatty acids. Unlike in most Vestimentifera, innate immunity genes are reduced in O. frankpressi, which, however, has an expansion of matrix metalloproteases to digest collagen. Our study supports that distinct nutritional interactions influence host genome evolution differently in highly specialised symbioses.

Suggested Citation

  • Giacomo Moggioli & Balig Panossian & Yanan Sun & Daniel Thiel & Francisco M. Martín-Zamora & Martin Tran & Alexander M. Clifford & Shana K. Goffredi & Nadezhda Rimskaya-Korsakova & Gáspár Jékely & Mar, 2023. "Distinct genomic routes underlie transitions to specialised symbiotic lifestyles in deep-sea annelid worms," Nature Communications, Nature, vol. 14(1), pages 1-17, December.
    • Handle: RePEc:nat:natcom:v:14:y:2023:i:1:d:10.1038_s41467-023-38521-6
    DOI: 10.1038/s41467-023-38521-6
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    References listed on IDEAS

    as
    1. Oleg Simakov & Ferdinand Marletaz & Sung-Jin Cho & Eric Edsinger-Gonzales & Paul Havlak & Uffe Hellsten & Dian-Han Kuo & Tomas Larsson & Jie Lv & Detlev Arendt & Robert Savage & Kazutoyo Osoegawa & Pi, 2013. "Insights into bilaterian evolution from three spiralian genomes," Nature, Nature, vol. 493(7433), pages 526-531, January.
    2. Francisco M. Martín-Zamora & Yan Liang & Kero Guynes & Allan M. Carrillo-Baltodano & Billie E. Davies & Rory D. Donnellan & Yongkai Tan & Giacomo Moggioli & Océane Seudre & Martin Tran & Kate Mortimer, 2023. "Annelid functional genomics reveal the origins of bilaterian life cycles," Nature, Nature, vol. 615(7950), pages 105-110, March.
    3. Sanne Nygaard & Haofu Hu & Cai Li & Morten Schiøtt & Zhensheng Chen & Zhikai Yang & Qiaolin Xie & Chunyu Ma & Yuan Deng & Rebecca B. Dikow & Christian Rabeling & David R. Nash & William T. Wcislo & Se, 2016. "Reciprocal genomic evolution in the ant–fungus agricultural symbiosis," Nature Communications, Nature, vol. 7(1), pages 1-9, November.
    4. Andrea D. Nussbaumer & Charles R. Fisher & Monika Bright, 2006. "Horizontal endosymbiont transmission in hydrothermal vent tubeworms," Nature, Nature, vol. 441(7091), pages 345-348, May.
    5. Océane Seudre & Allan M. Carrillo-Baltodano & Yan Liang & José M. Martín-Durán, 2022. "ERK1/2 is an ancestral organising signal in spiral cleavage," Nature Communications, Nature, vol. 13(1), pages 1-14, December.
    6. Yi Lan & Jin Sun & Chong Chen & Yanan Sun & Yadong Zhou & Yi Yang & Weipeng Zhang & Runsheng Li & Kun Zhou & Wai Chuen Wong & Yick Hang Kwan & Aifang Cheng & Salim Bougouffa & Cindy Lee Van Dover & Ji, 2021. "Hologenome analysis reveals dual symbiosis in the deep-sea hydrothermal vent snail Gigantopelta aegis," Nature Communications, Nature, vol. 12(1), pages 1-15, December.
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