The role of the cryptobiome and its associated microbial community in coral reef biogeochemical cycling

Daraghmeh, Nauras

03 1900

Tropical coral reefs are highly productive ecosystems thriving in oligotrophic waters, a phenomenon facilitated by efficient but delicate biogeochemical cycling within reef communities. Global climate change and local stressors are driving phase shifts from coral- to non-calcifier-dominated states in reefs worldwide, substantially altering reef biogeochemical functioning. While major benthic players such as coral and macroalgae have been investigated in detail regarding carbon and nutrient dynamics, the less conspicuous “reef cryptobiome” (sensu Carvalho et al., 2019) – comprising most of reef diversity – has only recently gained attention. Autonomous Reef Monitoring Structures (ARMS) have recently been developed to sample coral reef cryptobenthic communities in a non-destructive and standardised way, allowing exploration of these often overlooked biota. Here, 16 ARMS were deployed for seven months in four distinct habitats dominated by different benthic players (i.e., four units per habitat) in a nearshore Red Sea coral reef to investigate the cryptobiome associated with proxies of varying benthic states. Two of these habitats were coral-dominated, and one each dominated by turf algae or coral rubble. To assess the biogeochemical fluxes of pioneering cryptobenthic communities, ARMS were incubated in situ prior to retrieval using customised chambers. Subsequently, 16S rRNA gene amplicon and shotgun metagenomic sequencing of the ARMS sessile (i.e., encrusting) fractions were performed to link observed fluxes with prokaryotic taxonomic and functional profiles, particularly regarding nitrogen cycling. The results show that the pioneering cryptobiome represents a significant source of inorganic nutrients and that its associated microbial communities facilitate the mineralisation and assimilation of organic matter and provide crucial genetic functional pathways for nitrogen cycling. Functional similarities among habitats suggested functional redundancy despite variation in bacterial community composition. Hence, the reef cryptobiome can be considered an important biogeochemical player in coral reefs, actively shaping the abiotic conditions within niches of the reef framework and driving the recruitment and persistence of crytobenthic and other reef organisms. As communities associated with the algae-dominated reef habitat were most distinct compositionally and biogeochemically, and as non-calcifiers are becoming more dominant in many reefs, this has implications for intensifying phase shifts in coral reefs worldwide. Future ARMS studies will also benefit from adjustment of sample processing and molecular protocols, resulting in higher sample throughput and lower costs in times of increased application of ARMS.

Autonomous Reef Monitoring Structures

cryptobiome

reef cryptobenthos

nitrogen cycling

reef microbiome

reef biogeochemical functioning

Analyse et modélisation de l'eutrophisation de la Loire / Analysing and modelling eutrophisation in the Loire river

Minaudo, Camille

04 December 2015

Ce travail a pour objectif d’étudier les conditions physicochimiques qui causent dans la Loire des développements excessifs de phytoplancton, et de mettre en évidence les modifications des équilibres biogéochimiques qui en résultent. L’analyse des variables de l’eutrophisation a été conduite sur plusieurs niveaux d’échelle temporelle et spatiale, sur la base de longues chroniques de qualité de l’eau (1980- 2012), de données acquises à l’échelle journalière pendant la thèse (2012-2014), et d’un modèle numérique biogéochimique à résolution horaire. Depuis les conditions hypereutrophes des années 1980, la biomasse phytoplanctonique qui se développe en période estivale a été réduite d’un facteur 2,5 dans la Loire et dans ses affluents, de manière concomitante avec la baisse généralisée d’un facteur 3 des teneurs en phosphore biodisponible, liée au contrôle des rejets ponctuels urbains et industriels. Le fleuve de la Loire (France) reste cependant sensible à l’eutrophisation, du fait d’une forte pression agricole et urbaine, des étiages prononcés, et une morphologie fluviale à chenaux multiples qui ralentit l’écoulement, laissant pleinement au phytoplancton le temps de se développer. Lorsque les conditions hydrologiques le permettent, le développement du phytoplancton impacte fortement le fonctionnement de l’écosystème, en agissant significativement sur les cycles biogéochimiques des nutriments, du carbone et de l’oxygène. / This thesis aims at studying the physical and chemical causes and consequences that result from excessive phytoplankton growth in the Loire River. The analysis identified some parameters characterizing river eutrophication and was conducted on several spatial and temporal scales. This was based on long-term water quality time-series (1980-2012), a daily survey carried out during this work (2012-2014), and the numerical modeling of the river biogeochemical functioning with an hourly resolution. Phytoplankton development in summer was reduced 2.5-fold in the Loire River and in the main tributaries, synchronously with the generalized reduction 3-fold of bioavailable phosphorus as a result of controlling and limiting phosphorus point sources. However, the Loire River remains sensitive to eutrophication, with a significant urban and agricultural pressure, low water levels in summer, and its multiple channels morphology slowing down the water velocity. All these factors combined favor phytoplankton development. When hydrological conditions are favorable, phytoplankton grows and significantly affects the ecosystem functioning, with an impact on nutrients, carbon and oxygen biogeochemical cycles.

Eutrophisation des fleuves

Évolutions long-terme

Fonctionnement biogéochimique

Modélisation hydrobiogéochimique

Nutriments

Carbone organique

Loire

River eutrophication

Long-term trends

Biogeochemical functioning

Hydrobiogeochemical modelling

Nutrients

Organic carbon

Loire River