Thesis Bento Bivalve Trophic Ecology Assessed With Metabarcoding And Relation To Phycotoxin Acc[...]

Thesis Bento Bivalve Trophic Ecology Assessed With Metabarcoding And Relation To Phycotoxin Accumulation M/F - Plouzané - CDD

The DYNECO research unit (Dynamics of Coastal Ecosystems) develops an integrated, multidisciplinary approach to understand the functioning and evolution of coastal marine ecosystems under natural and anthropogenic pressures. In this field, the unit carries out research and provides expert analysis aimed at understanding, modelling and predicting the spatial and temporal dynamics of interactions among marine biodiversity, habitats and humans. Field observations, experimental approaches and numerical modelling are used to investigate physical, biogeochemical and ecological processes structuring these systems.

Among the topics covered, the unit places a strong emphasis on trophic ecology, focusing on benthic‑pelagic coupling and the structure of coastal food webs. Research in our unit examines the trophic niches of ecosystem engineers and their associated fauna, as well as other keystone species, and how resource partitioning shapes coastal communities and ecosystem functioning. The effects of global change on different biological compartments are of particular interest, especially how shifts in phytoplankton communities influence benthic suspension feeders, which act as key mediators of energy flow between the water column and the seafloor.

What is the topic of the thesis?

Understanding the resilience of coastal marine ecosystems under global change is a major scientific and societal challenge. Coastal systems are increasingly exposed to multiple stressors, including climate change and shifts in biodiversity, which can alter ecosystem functioning and the services they provide. Central to these dynamics are the trophic links between pelagic primary producers and benthic communities. Changes in phytoplankton communities, the main source of energy entering marine food webs, can cascade to higher trophic levels, affecting the structure, functioning, and stability of benthic ecosystems, including key ecosystem engineers and commercially important shellfish species.

Suspension‑feeding bivalves play a pivotal role in this benthic‑pelagic coupling. By filtering large volumes of seawater, they transfer organic matter and nutrients from the water column to the seafloor, structuring food webs and regulating water quality. Their ecological importance is matched by their economic value in shellfish production. However, their growth, health, and survival are tightly linked to the availability and quality of phytoplankton resources. Ongoing environmental changes are driving shifts in phytoplankton biomass, species composition, phenology, and biochemical quality, as well as increasing the frequency and distribution of harmful algal blooms (HABs). These changes may profoundly affect trophic interactions and the functioning of benthic communities, yet their impacts on bivalve feeding ecology remain poorly understood under natural conditions.

Bivalves are generally considered omnivorous species, primarily consuming phytoplankton but also relying on alternative sources such as resuspended microphytobenthos. While some phytoplankton taxa (e.g., certain diatoms) are associated with enhanced growth, others, including harmful and/or spiculated diatoms and dinoflagellates, can negatively affect growth. Current knowledge on their in situ diet is largely based on bulk trophic markers (e.g., stable isotopes, fatty acids), which lack taxonomic resolution and integrate diet over long timescales, limiting our ability to identify specific prey taxa and short‑term dietary responses.

What will your mission and activities be?

• Participate in field sampling and laboratory-based data acquisition (seawater filtration for phytoplankton, biometric measurements and dissections of bivalves, maintenance of bivalves in aquaria for faeces collection)
• Acquire DNA metabarcoding data (DNA extractions, PCR-based Illumina library preparation)
• Preparation of samples for lipid, stable isotope and phycotoxin data acquisition
• Bioinformatic and biostatistical data analysis
• Time‑series analysis of phytoplankton data
• Manuscript writing and publication of results
• Oral presentation of results in scientific conferences and project meetings
• Joint supervision of Masters students

How are your activities organised?

• The PhD will be based at DYNECO on the Ifremer Brittany Center, with fieldwork in Brittany and regular visits to the Institut Universitaire Européen de la Mer (IUEM) and Laboratoire des sciences de l'Environnement Marin (LEMAR) joint research unit, as well as occasional visits to the Ifremer station in Concarneau.
• Molecular laboratory experiments will be conducted at Ifremer (DYNECO).
• Lipids and stable isotopes will be analysed respectively at the LIPIDOCEAN platform at LEMAR and the PSO platform at IUEM.
• Phycotoxins will be analysed at the Ifremer station in Concarneau.
• Bioinformatic analysis will be conducted with support from the SeBiMER (Ifremer's Bioinformatic Service), with access to Ifremer's computing cluster DATARMOR.
• Biostatistics and time series analysis will be conducted on a computer provided by the institute.
• Possible interactions with collaborators from the Japan Fisheries Research and Education Agency.

Who are you?

• Masters degree in the fields of biology, marine ecology, environment or bioinformatics (university or engineering school).

You have the following skills, knowledge and experience:

• Interest in trophic ecology, and the functioning of trophic networks on coastal marine environments.
• Skills in statistical numerical analysis are required (R, RStudio).
• Experience in the use of molecular tools (DNA extraction, PCR, Illumina library prep) is recommended, but not required.
• Experience coding in bash or python is a plus.
• Demonstrated written and oral communication skills in French and English.

You have the following qualities:

• Intellectual curiosity, liveliness and spirit of synthesis because he/she will have to appropriate various disciplinary fields (physiology of marine invertebrates; phytoplankton taxonomy; genetics; trophic markers; phycotoxins).
• Rigor and organisational skills.
• Tenacity and perseverance.

What are your benefits?

• Teleworking agreement and 12 comp time days (after 6 months' seniority) and supra statutory leave.
• Allocation of a significant budget to developing skills, through individual or collective training actions.
• CSR policy inspired by the purposes of the institute (sustainable mobility allowance, etc.).

Job details

Title: Thesis Bento Bivalve Trophic Ecology Assessed With Metabarcoding And Relation To Phycotoxin Accumulation M/F - Plouzané - CDD

Published:

Deadline for applications: :59 (Europe/Paris)

Location: Plouzané, France