Your search keyword '"Parravicini, Valeriano"' showing total 21 results

1. Host diet drives gut microbiome convergence between coral reef fishes and mammals.

Author

Degregori, Samuel, Schiettekatte, Nina M. D., Casey, Jordan M., Brandl, Simon J., Mercière, Alexandre, Amato, Katherine R., Mazel, Florent, Parravicini, Valeriano, and Barber, Paul H.

Subjects

CORAL reef fishes, GUT microbiome, FISH evolution, MAMMALS, VERTEBRATES

Abstract

Animal gut microbiomes are critical to host physiology and fitness. The gut microbiomes of fishes—the most abundant and diverse vertebrate clade—have received little attention relative to other clades. Coral reef fishes, in particular, make up a wide range of evolutionary histories and feeding ecologies that are likely associated with gut microbiome diversity. The repeated evolution of herbivory in fishes and mammals also allows us to examine microbiome similarity in relationship to diet across the entire vertebrate tree of life. Here, we generate a large coral reef fish gut microbiome dataset (n = 499 samples, 19 species) and combine it with a diverse aggregation of public microbiome data (n = 447) to show that host diet drives significant convergence between coral reef fish and mammalian gut microbiomes. We demonstrate that this similarity is largely driven by carnivory and herbivory and that herbivorous and carnivorous hosts exhibit distinct microbial compositions across fish and mammals. We also show that fish and mammal gut microbiomes share prominent microbial taxa, including Ruminoccocus spp. and Akkermansia spp., and predicted metabolic pathways. Despite the major evolutionary and ecological differences between fishes and mammals, our results reveal that their gut microbiomes undergo similar dietary selective pressures. Thus, diet, in addition to phylosymbiosis must be considered even when comparing the gut microbiomes of distantly related hosts. [ABSTRACT FROM AUTHOR]

Published

2024

2. The rise of dietary diversity in coral reef fishes.

Author

Ng, Isabelle, Bellwood, David R., Strugnell, Jan M., Parravicini, Valeriano, and Siqueira, Alexandre C.

Subjects

CORAL reef fishes, MASS extinctions, FISH diversity, REEF fishes, COMPARATIVE method

Abstract

Diet has been identified as a major driver of reef fish lineage diversification, producing one of the most speciose vertebrate assemblages today. Yet, there is minimal understanding of how, when and why diet itself has evolved. To address this, we used a comprehensive gut content dataset, alongside a recently developed phylogenetic comparative method to assess multivariate prey use across a diverse animal assemblage, coral reef fishes. Specifically, we investigated the diversification, transitions and phylogenetic conservatism of fish diets through evolutionary time. We found two major pulses of diet diversification: one at the end-Cretaceous and one during the Eocene, suggesting that the Cretaceous–Palaeogene mass extinction probably provided the initial ecological landscape for fish diets to diversify. The birth of modern families during the Eocene then provided the foundation for a second wave of dietary expansion. Together, our findings showcase the role of extinction rebound events in shaping the dietary diversity of fishes on present-day coral reefs. [ABSTRACT FROM AUTHOR]

Published

2024

3. Challenging trophic position assessments in complex ecosystems: Calculation method, choice of baseline, trophic enrichment factors, season and feeding guild do matter: A case study from Marquesas Islands coral reefs.

Author

Letourneur, Yves, Fey, Pauline, Dierking, Jan, Galzin, René, and Parravicini, Valeriano

Subjects

CORAL reefs & islands, CORAL reef fishes, NITROGEN isotopes, FOOD chains, STABLE isotopes

Abstract

Assessments of ecosystem functioning are a fundamental ecological challenge and an essential foundation for ecosystem‐based management. Species trophic position (TP) is essential to characterize food web architecture. However, despite the intuitive nature of the concept, empirically estimating TP is a challenging task due to the complexity of trophic interaction networks. Various methods are proposed to assess TPs, including using different sources of organic matter at the base of the food web (the 'baseline'). However, it is often not clear which methodological approach and which baseline choices are the most reliable. Using an ecosystem‐wide assessment of a tropical reef (Marquesas Islands, with available data for 70 coral reef invertebrate and fish species), we tested whether different commonly used TP estimation methods yield similar results and, if not, whether it is possible to identify the most reliable method. We found significant differences in TP estimates of up to 1.7 TPs for the same species, depending on the method and the baseline used. When using bulk stable isotope data, the choice of the baseline significantly impacted TP values. Indeed, while nitrogen stable isotope (δ15N) values of macroalgae led to consistent TP estimates, those using phytoplankton generated unrealistically low TP estimates. The use of a conventional enrichment factor (i.e. 3.4‰) or a 'variable' enrichment factor (i.e. according to feeding guilds) also produced clear discrepancies between TP estimates. TPs obtained with δ15N values of source amino acids (compound‐specific isotope analysis) were close to those assessed with macroalgae. An opposite seasonal pattern was found, with significantly lower TPs in winter than in summer for most species, with particularly pronounced differences for lower TP species. We use the observed differences to discuss possible drivers of the diverging TP estimates and the potential ecological implications. Based on a case study from a remote coral reef ecosystem in the Pacific Ocean, this work analyses how several potential sources of organic matter (i.e. 'baselines') and calculation methods strongly affect assessments of trophic positions. We also demonstrated that seasonal temporality and feeding guild are important parameters to be considered. [ABSTRACT FROM AUTHOR]

Published

2024

4. The role of fish feces for nutrient cycling on coral reefs.

Author

Schiettekatte, Nina M. D., Casey, Jordan M., Brandl, Simon J., Mercière, Alexandre, Degregori, Sam, Burkepile, Deron, Van Wert, Jacey C., Ghilardi, Mattia, Villéger, Sébastien, and Parravicini, Valeriano

Subjects

CORAL reefs & islands, NUTRIENT cycles, CORALS, CORAL reef fishes, BIOGEOCHEMICAL cycles

Abstract

Consumers play an important role in biogeochemical cycles through the consumption and release of essential elements such as carbon (C), nitrogen (N), and phosphorus (P). Indeed, a large proportion of consumed elements are released into the environment in inorganic (i.e. excretion) or organic form (i.e. egestion). On coral reefs, fishes represent the bulk of consumer biomass and thus play a key role in the recycling of nutrients. In recent years, excretion rates have been studied intensively, but less is known about the rate and quality of coral reef fish egestion. In this study, we quantify the elemental contents of fish feces, estimate absorption efficiencies and compare egestion and excretion rates for 51 coral reef fish species. We show that elemental concentrations decrease remarkably little from food to feces. This is due to extremely low absorption efficiencies, resulting in the egestion of large amounts of energy and nutrients. Moreover, we show that while the quality of fish feces varies across trophic guilds, it remains highly variable within trophic guilds. Finally, we demonstrate that the release of N and P through egestion outweighs the amount of nutrients recycled through excretion. Our study highlights the need to incorporate animal egestion into assessments of ecosystem functioning and food web structure. [ABSTRACT FROM AUTHOR]

Published

2023

5. Fish feces reveal diverse nutrient sources for coral reefs.

Author

Van Wert, Jacey C., Ezzat, Leïla, Munsterman, Katrina S., Landfield, Kaitlyn, Schiettekatte, Nina M. D., Parravicini, Valeriano, Casey, Jordan M., Brandl, Simon J., Burkepile, Deron E., and Eliason, Erika J.

Subjects

CORAL reefs & islands, CORALS, CORAL reef fishes, MICRONUTRIENTS, FECES, NUTRIENT cycles

Abstract

Consumers mediate nutrient cycling through excretion and egestion across most ecosystems. In nutrient‐poor tropical waters such as coral reefs, nutrient cycling is critical for maintaining productivity. While the cycling of fish‐derived inorganic nutrients via excretion has been extensively investigated, the role of egestion for nutrient cycling has remained poorly explored. We sampled the fecal contents of 570 individual fishes across 40 species, representing six dominant trophic guilds of coral reef fishes in Moorea, French Polynesia. We measured fecal macro‐ (proteins, carbohydrates, lipids) and micro‐ (calcium, copper, iron, magnesium, manganese, zinc) nutrients and compared the fecal nutrient quantity and quality across trophic guilds, taxa, and body size. Macro‐ and micronutrient concentrations in fish feces varied markedly across species. Genera and trophic guild best predicted fecal nutrient concentrations. In addition, nutrient composition in feces was unique among species within both trophic guilds (herbivores and corallivores) and genera (Acanthurus and Chaetodon). Particularly, certain coral reef fishes (e.g., Thalassoma hardwicke, Chromis xanthura, Chaetodon pelewensis and Acanthurus pyroferus) harbored relatively high concentrations of micronutrients (e.g., Mn, Mg, Zn and Fe, respectively) that are known to contribute to ocean productivity and positively impact coral physiological performances. Given the nutrient‐rich profiles across reef fish feces, conserving holistic reef fish communities ensures the availability of nutritional pools on coral reefs. We therefore suggest that better integration of consumer egestion dynamics into food web models and ecosystem‐scale processes will facilitate an improved understanding of coral reef functioning. [ABSTRACT FROM AUTHOR]

Published

2023

6. Combining stereo‐video monitoring and physiological trials to estimate reef fish metabolic demands in the wild.

Author

Schiettekatte, Nina M. D., Conte, Francesca, French, Beverly, Brandl, Simon J., Fulton, Christopher J., Mercière, Alexandre, Norin, Tommy, Villéger, Sébastien, and Parravicini, Valeriano

Subjects

PATIENT monitoring, CORAL reefs & islands, CORAL reef fishes, BODY size, AQUATIC animals, GULLS, REEF fishes

Abstract

Organismal metabolic rates (MRs) are the basis of energy and nutrient fluxes through ecosystems. In the marine realm, fishes are some of the most prominent consumers. However, their metabolic demand in the wild (field MR [FMR]) is poorly documented, because it is challenging to measure directly. Here, we introduce a novel approach to estimating the component of FMR associated with voluntary activity (i.e., the field active MR [AMRfield]). Our approach combines laboratory‐based respirometry, swimming speeds, and field‐based stereo‐video systems to estimate the activity of individuals. We exemplify our approach by focusing on six coral reef fish species, for which we quantified standard MR and maximum MR (SMR and MMR, respectively) in the laboratory, and body sizes and swimming speeds in the field. Based on the relationships between MR, body size, and swimming speeds, we estimate that the activity scope (i.e., the ratio between AMRfield and SMR) varies from 1.2 to 3.2 across species and body sizes. Furthermore, we illustrate that the scaling exponent for AMRfield varies across species and can substantially exceed the widely assumed value of 0.75 for SMR. Finally, by scaling organismal AMRfield estimates to the assemblage level, we show the potential effect of this variability on community metabolic demand. Our approach may improve our ability to estimate elemental fluxes mediated by a critically important group of aquatic animals through a non‐destructive, widely applicable technique. [ABSTRACT FROM AUTHOR]

Published

2022

7. Ecological dependencies make remote reef fish communities most vulnerable to coral loss.

Author

Strona, Giovanni, Beck, Pieter S. A., Cabeza, Mar, Fattorini, Simone, Guilhaumon, François, Micheli, Fiorenza, Montano, Simone, Ovaskainen, Otso, Planes, Serge, Veech, Joseph A., and Parravicini, Valeriano

Subjects

REEF fishes, FISHING villages, FISH communities, CORAL reef fishes, CORAL bleaching, BIOLOGICAL extinction, CORAL reefs & islands

Abstract

Ecosystems face both local hazards, such as over-exploitation, and global hazards, such as climate change. Since the impact of local hazards attenuates with distance from humans, local extinction risk should decrease with remoteness, making faraway areas safe havens for biodiversity. However, isolation and reduced anthropogenic disturbance may increase ecological specialization in remote communities, and hence their vulnerability to secondary effects of diversity loss propagating through networks of interacting species. We show this to be true for reef fish communities across the globe. An increase in fish-coral dependency with the distance of coral reefs from human settlements, paired with the far-reaching impacts of global hazards, increases the risk of fish species loss, counteracting the benefits of remoteness. Hotspots of fish risk from fish-coral dependency are distinct from those caused by direct human impacts, increasing the number of risk hotspots by ~30% globally. These findings might apply to other ecosystems on Earth and depict a world where no place, no matter how remote, is safe for biodiversity, calling for a reconsideration of global conservation priorities. Coral reefs face both local and global stressors. Here, the authors show how a positive relationship between distance from human settlements and ecological specialisation makes remote coral reef fish communities more vulnerable to coral loss. [ABSTRACT FROM AUTHOR]

Published

2021

8. Phylogeny, body morphology, and trophic level shape intestinal traits in coral reef fishes.

Author

Ghilardi, Mattia, Schiettekatte, Nina M. D., Casey, Jordan M., Brandl, Simon J., Degregori, Samuel, Mercière, Alexandre, Morat, Fabien, Letourneur, Yves, Bejarano, Sonia, and Parravicini, Valeriano

Subjects

CORAL reef fishes, INTESTINES, FOOD chains, FISH morphology, MORPHOLOGY

Abstract

Trait‐based approaches are increasingly used to study species assemblages and understand ecosystem functioning. The strength of these approaches lies in the appropriate choice of functional traits that relate to the functions of interest. However, trait–function relationships are often supported by weak empirical evidence.Processes related to digestion and nutrient assimilation are particularly challenging to integrate into trait‐based approaches. In fishes, intestinal length is commonly used to describe these functions. Although there is broad consensus concerning the relationship between fish intestinal length and diet, evolutionary and environmental forces have shaped a diversity of intestinal morphologies that is not captured by length alone.Focusing on coral reef fishes, we investigate how evolutionary history and ecology shape intestinal morphology. Using a large dataset encompassing 142 species across 31 families collected in French Polynesia, we test how phylogeny, body morphology, and diet relate to three intestinal morphological traits: intestinal length, diameter, and surface area.We demonstrate that phylogeny, body morphology, and trophic level explain most of the interspecific variability in fish intestinal morphology. Despite the high degree of phylogenetic conservatism, taxonomically unrelated herbivorous fishes exhibit similar intestinal morphology due to adaptive convergent evolution. Furthermore, we show that stomachless, durophagous species have the widest intestines to compensate for the lack of a stomach and allow passage of relatively large undigested food particles.Rather than traditionally applied metrics of intestinal length, intestinal surface area may be the most appropriate trait to characterize intestinal morphology in functional studies. [ABSTRACT FROM AUTHOR]

Published

2021

9. Congruent trophic pathways underpin global coral reef food webs.

Author

Pozas-Schacre, Chloé, Casey, Jordan M., Brandl, Simon J., Kulbicki, Michel, Harmelin-Vivien, Mireille, Strona, Giovanni, and Parravicini, Valeriano

Subjects

CORAL reefs & islands, CORALS, CORAL reef fishes, CORAL communities, ENVIRONMENTAL degradation

Abstract

Ecological interactions uphold ecosystem structure and functioning. However, as species richness increases, the number of possible interactions rises exponentially. More than 6,000 species of coral reef fishes exist across the world's tropical oceans, resulting in an almost innumerable array of possible trophic interactions. Distilling general patterns in these interactions across different bioregions stands to improve our understanding of the processes that govern coral reef functioning. Here, we show that across bioregions, tropical coral reef food webs exhibit a remarkable congruence in their trophic interactions. Specifically, by compiling and investigating the structure of six coral reef food webs across distinct bioregions, we show that when accounting for consumer size and resource availability, these food webs share more trophic interactions than expected by chance. In addition, coral reef food webs are dominated by dietary specialists, which makes trophic pathways vulnerable to biodiversity loss. Prey partitioning among these specialists is geographically consistent, and this pattern intensifies when weak interactions are disregarded. Our results suggest that energy flows through coral reef communities along broadly comparable trophic pathways. Yet, these critical pathways are maintained by species with narrow, specialized diets, which threatens the existence of coral reef functioning in the face of biodiversity loss. [ABSTRACT FROM AUTHOR]

Published

2021

10. Phylogenetic conservatism drives nutrient dynamics of coral reef fishes.

Author

Allgeier, Jacob E., Weeks, Brian C., Munsterman, Katrina S., Wale, Nina, Wenger, Seth J., Parravicini, Valeriano, Schiettekatte, Nina M. D., Villéger, Sébastien, and Burkepile, Deron E.

Subjects

CORAL reef fishes, CORAL reefs & islands, NUTRIENT cycles, CONSERVATISM, CORALS, PARSIMONIOUS models

Abstract

The relative importance of evolutionary history and ecology for traits that drive ecosystem processes is poorly understood. Consumers are essential drivers of nutrient cycling on coral reefs, and thus ecosystem productivity. We use nine consumer "chemical traits" associated with nutrient cycling, collected from 1,572 individual coral reef fishes (178 species spanning 41 families) in two biogeographic regions, the Caribbean and Polynesia, to quantify the relative importance of phylogenetic history and ecological context as drivers of chemical trait variation on coral reefs. We find: (1) phylogenetic relatedness is the best predictor of all chemical traits, substantially outweighing the importance of ecological factors thought to be key drivers of these traits, (2) phylogenetic conservatism in chemical traits is greater in the Caribbean than Polynesia, where our data suggests that ecological forces have a greater influence on chemical trait variation, and (3) differences in chemical traits between regions can be explained by differences in nutrient limitation associated with the geologic context of our study locations. Our study provides multiple lines of evidence that phylogeny is a critical determinant of contemporary nutrient dynamics on coral reefs. More broadly our findings highlight the utility of evolutionary history to improve prediction in ecosystem ecology. The relative importance of evolutionary history and ecology for traits that drive ecosystem processes is poorly understood. Analyzing nine traits associated with fish stoichiometry from 1,572 individuals yields multiple lines of evidence that phylogeny is a critical determinant of nutrient cycling in coral reefs. [ABSTRACT FROM AUTHOR]

Published

2021

11. Delineating reef fish trophic guilds with global gut content data synthesis and phylogeny.

Author

Parravicini, Valeriano, Casey, Jordan M., Schiettekatte, Nina M. D., Brandl, Simon J., Pozas-Schacre, Chloé, Carlot, Jérémy, Edgar, Graham J., Graham, Nicholas A. J., Harmelin-Vivien, Mireille, Kulbicki, Michel, Strona, Giovanni, and Stuart-Smith, Rick D.

Subjects

*REEF fishes, *CORAL reefs & islands, *CORAL reef fishes, *PHYLOGENETIC models, *PHYLOGENY, *GUILDS, *TROPHIC cascades

Abstract

Understanding species' roles in food webs requires an accurate assessment of their trophic niche. However, it is challenging to delineate potential trophic interactions across an ecosystem, and a paucity of empirical information often leads to inconsistent definitions of trophic guilds based on expert opinion, especially when applied to hyperdiverse ecosystems. Using coral reef fishes as a model group, we show that experts disagree on the assignment of broad trophic guilds for more than 20% of species, which hampers comparability across studies. Here, we propose a quantitative, unbiased, and reproducible approach to define trophic guilds and apply recent advances in machine learning to predict probabilities of pairwise trophic interactions with high accuracy. We synthesize data from community-wide gut content analyses of tropical coral reef fishes worldwide, resulting in diet information from 13,961 individuals belonging to 615 reef fish. We then use network analysis to identify 8 trophic guilds and Bayesian phylogenetic modeling to show that trophic guilds can be predicted based on phylogeny and maximum body size. Finally, we use machine learning to test whether pairwise trophic interactions can be predicted with accuracy. Our models achieved a misclassification error of less than 5%, indicating that our approach results in a quantitative and reproducible trophic categorization scheme, as well as high-resolution probabilities of trophic interactions. By applying our framework to the most diverse vertebrate consumer group, we show that it can be applied to other organismal groups to advance reproducibility in trait-based ecology. Our work thus provides a viable approach to account for the complexity of predator–prey interactions in highly diverse ecosystems. The diversity of life on our planet has produced a remarkable variety of biological traits that characterize different species, and such traits are widely considered an alternative to taxonomy to increase our understanding of biodiversity and ecosystem functioning. This study presents an unbiased and fully reproducible framework to delineate trophic guilds in reef fishes. [ABSTRACT FROM AUTHOR]

Published

2020

12. Liste des poissons côtiers de Polynésie française

Author

Siu, Gilles, Bacchet, Philippe, Bernardi, Giacomo, Brooks, Andrew J., Carlot, Jeremy, Causse, Romain, Claudet, Joachim, Clua, Eric, Delrieu-trottin, Erwan, Espiau, Benoit, Harmelin-vivien, Mireille, Keith, Philippe, Lecchini, David, Madi-moussa, Rakamaly, Parravicini, Valeriano, Planes, Serge, Ponsonnet, Cedric, Randall, John E., Sasal, Pierre, Taquet, Marc, Williams, Jeffrey T., and Galzin, Rene

Subjects

Deep and Pelagic fishes, Endemic fishes, Coral reef fishes, Inventory, French Polynesia, Freshwater fishes

Abstract

On the occasion of the 10th Indo-Pacific Fish Conference (http://ipfc10.criobe.pf/) to be held in Tahiti in October 2017, it seemed timely to update Randall's 1985 list of the fishes known from French Polynesia. Many studies focusing on fishes in this area have been published since 1985, but Randall's list remains the authoritative source. Herein we present an expanded species list of 1,301 fishes now known to occur in French Polynesia and we review the expeditions and information sources responsible for the over 60% increase in the number of known species since the publication of Randall's checklist in 1985. Our list of the fishes known from French Polynesia includes only those species with a reliably verifiable presence in these waters. In cases where there was any doubt about the identity of a species, or of the reliability of a reported sighting, the species was not included in our list., À l’occasion de l’organisation de la 10e conférence sur les poissons de l’Indo-Pacifique (http://ipfc10.criobe. pf/) à Tahiti du 2 au 6 octobre 2017, il nous a semblé opportun de fournir une liste actualisée des poissons de Polynésie française. La liste qui fait actuellement référence est celle de Randall publiée en 1985, et mentionnant 800 espèces. Plusieurs articles scientifiques concernant les poissons de cette zone ont été publiés depuis cette date, mais celui de Randall (1985) fait encore autorité. Nous mentionnons ici 1 301 espèces qui fréquentent les eaux des rivières, lagons, îles et océan de la zone exclusive économique de la Polynésie française. Nous avons repris, et vérifié, les informations trouvées dans les travaux scientifiques et les rapports des expéditions effectuées dans cette zone depuis 1985, ce qui augmente de plus de 60% le nombre d’espèces entre les deux listes. Notre liste ne contient que les espèces dont la présence dans les eaux de la Polynésie française est incontestable. En cas de doutes sur l’identification d’une espèce ou sur sa présence dans la zone, elle n’est pas mentionnée dans notre liste.

Published

2017

13. Reconstructing hyperdiverse food webs: Gut content metabarcoding as a tool to disentangle trophic interactions on coral reefs.

Author

Casey, Jordan M., Meyer, Christopher P., Morat, Fabien, Brandl, Simon J., Planes, Serge, Parravicini, Valeriano, and Mahon, Andrew

Subjects

CORAL reefs & islands, INTERNET content, CORAL reef fishes, STABLE isotopes, MARINE food chain, CORAL reef ecology, FOOD chains, STABLE isotope analysis

Abstract

Copyright of Methods in Ecology & Evolution is the property of Wiley-Blackwell and its content may not be copied or emailed to multiple sites or posted to a listserv without the copyright holder's express written permission. However, users may print, download, or email articles for individual use. This abstract may be abridged. No warranty is given about the accuracy of the copy. Users should refer to the original published version of the material for the full abstract. (Copyright applies to all Abstracts.)

Published

2019

14. Synchrony patterns reveal different degrees of trophic guild vulnerability after disturbances in a coral reef fish community.

Author

Viviani, Jérémie, Moritz, Charlotte, Parravicini, Valeriano, Lecchini, David, Siu, Gilles, Galzin, René, Viriot, Laurent, and Sorte, Cascade

Subjects

CORAL reef ecology, CORAL reef fishes, FISH communities, SYNCHRONIC order, CORAL reefs & islands, GUILDS

Abstract

Aim: Chronic anthropogenic stressors are increasing in intensity, making ecosystems more vulnerable to acute disturbances. Recovery processes are not always well understood due to the complexity of ecosystems and the lack of appropriate indicators. Temporal synchrony is a valuable metric for assessing whether fluctuations in abundance of different species are homogeneous or heterogeneous over time. Theoretically, a great diversity of responses by species facing disturbances is associated with a stable ecosystem, with species turnover guaranteeing the persistence of key ecological processes. We analysed the fluctuations of synchrony of a fish community to assess its resilience in an ecosystem exposed to various disturbances. Location: Moorea (French Polynesia). Methods: Using one of the longest time series available for coral reefs (ca. 35 years), we examined the variations in substrate cover, and the abundance, synchrony and composition of different fish trophic guilds. Multivariate analyses involving synchrony were used to determine the stability of trophic guilds. Results: Changes in fish community composition indicated incomplete taxonomic resilience. However, community synchrony was lower during periods of low coral cover, indicating greater response diversity, while total fish abundance remained fairly stable. Synchrony drop was due to relationships with coral cover that differed by trophic guild, or the differences in species responses within guilds. Some guilds such as sessile invertebrate feeders exhibited a strong homogeneity of response over time, indicating a greater vulnerability. We also highlighted that various types of disturbances had different effects on the synchrony of particular guilds. Main conclusions: The fish community appeared functionally resilient, with stability of total abundance and most trophic guilds. This could be a factor explaining the rapid recovery of Moorea's coral reefs from disturbances. However, the homogeneous responses of some fish groups to disturbances may compromise the reef recovery potential on the long term if disturbances become more frequent. [ABSTRACT FROM AUTHOR]

Published

2019

15. The biogeography of tropical reef fishes: endemism and provinciality through time.

Author

Cowman, Peter F., Parravicini, Valeriano, Kulbicki, Michel, and Floeter, Sergio R.

Subjects

*CORAL reef fishes, *BIOGEOGRAPHY, *FISH phylogeny, *SPECIES diversity

Abstract

ABSTRACT The largest marine biodiversity hotspot straddles the Indian and Pacific Oceans, driven by taxa associated with tropical coral reefs. Centred on the Indo- Australian Archipelago ( IAA), this biodiversity hotspot forms the 'bullseye' of a steep gradient in species richness from this centre to the periphery of the vast Indo- Pacific region. Complex patterns of endemism, wide-ranging species and assemblage differences have obscured our understanding of the genesis of this biodiversity pattern and its maintenance across two-thirds of the world's oceans. But time-calibrated molecular phylogenies coupled with ancestral biogeographic estimates have provided a valuable framework in which to examine the origins of coral reef fish biodiversity across the tropics. Herein, we examine phylogenetic and biogeographic data for coral reef fishes to highlight temporal patterns of marine endemism and tropical provinciality. The ages and distribution of endemic lineages have often been used to identify areas of species creation and demise in the marine tropics and discriminate among multiple hypotheses regarding the origins of biodiversity in the IAA. Despite a general under-sampling of endemic fishes in phylogenetic studies, the majority of locations today contain a mixture of potential paleo- and neo-endemic fishes, pointing to multiple historical processes involved in the origin and maintenance of the IAA biodiversity hotspot. Increased precision and sampling of geographic ranges for reef fishes has permitted the division of discrete realms, regions and provinces across the tropics. Yet, such metrics are only beginning to integrate phylogenetic relatedness and ancestral biogeography. Here, we integrate phylogenetic diversity with ancestral biogeographic estimation of lineages to show how assemblage structure and tropical provinciality has changed through time. [ABSTRACT FROM AUTHOR]

Published

2017

16. Shore fishes of French Polynesia.

Author

SIU, Gilles, BACCHET, Philippe, BERNARDI, Giacomo, BROOKS, Andrew J., CARLOT, Jeremy, CAUSSE, Romain, CLAUDET, Joachim, CLUA, Éric, DELRIEU-TROTTIN, Erwan, ESPIAU, Benoit, HARMELIN-VIVIEN, Mireille, KEITH, Philippe, LECCHINI, David, MADI-MOUSSA, Rakamaly, PARRAVICINI, Valeriano, PLANES, Serge, PONSONNET, Cédric, RANDALL, John E., SASAL, Pierre, and TAQUET, Marc

Subjects

FISH research, PELAGIC fishes, FRESHWATER fishes, NATIVE fishes

Abstract

Copyright of Cybium: International Journal of Ichthyology is the property of Societe Francaise d'Ichtyologie (SFI) and its content may not be copied or emailed to multiple sites or posted to a listserv without the copyright holder's express written permission. However, users may print, download, or email articles for individual use. This abstract may be abridged. No warranty is given about the accuracy of the copy. Users should refer to the original published version of the material for the full abstract. (Copyright applies to all Abstracts.)

Published

2017

17. Responses of coral reef fishes to past climate changes are related to life-history traits.

Author

Ottimofiore, Eduardo, Albouy, Camille, Leprieur, Fabien, Descombes, Patrice, Kulbicki, Michel, Mouillot, David, Parravicini, Valeriano, and Pellissier, Loïc

Subjects

CLIMATE change, CORAL reef fishes, DISPERSAL (Ecology), SPECIES distribution

Abstract

Coral reefs and their associated fauna are largely impacted by ongoing climate change. Unravelling species responses to past climatic variations might provide clues on the consequence of ongoing changes. Here, we tested the relationship between changes in sea surface temperature and sea levels during the Quaternary and present-day distributions of coral reef fish species. We investigated whether species-specific responses are associated with life-history traits. We collected a database of coral reef fish distribution together with life-history traits for the Indo-Pacific Ocean. We ran species distribution models ( SDMs) on 3,725 tropical reef fish species using contemporary environmental factors together with a variable describing isolation from stable coral reef areas during the Quaternary. We quantified the variance explained independently by isolation from stable areas in the SDMs and related it to a set of species traits including body size and mobility. The variance purely explained by isolation from stable coral reef areas on the distribution of extant coral reef fish species largely varied across species. We observed a triangular relationship between the contribution of isolation from stable areas in the SDMs and body size. Species, whose distribution is more associated with historical changes, occurred predominantly in the Indo-Australian archipelago, where the mean size of fish assemblages is the lowest. Our results suggest that the legacy of habitat changes of the Quaternary is still detectable in the extant distribution of many fish species, especially those with small body size and the most sedentary. Because they were the least able to colonize distant habitats in the past, fish species with smaller body size might have the most pronounced lags in tracking ongoing climate change. [ABSTRACT FROM AUTHOR]

Published

2017

18. Unexpected high vulnerability of functions in wilderness areas: evidence from coral reef fishes.

Author

D'agata, Stéphanie, Vigliola, Laurent, Graham, Nicholas A. J., Wantiez, Laurent, Parravicini, Valeriano, Villéger, Sébastien, Mou-Tham, Gerard, Frolla, Philippe, Friedlander, Alan M., Kulbicki, Michel, and Mouillot, David

Subjects

WILDERNESS areas, CORAL reef fishes, ECOSYSTEMS, FISHING, PREDATORY animals

Abstract

High species richness is thought to support the delivery of multiple ecosystem functions and services under changing environments. Yet, some species might performunique functional roleswhile others are redundant. Thus, the benefits of high species richness in maintaining ecosystem functioning are uncertain if functions have little redundancy, potentially leading to high vulnerability of functions.We studied the natural propensity of assemblages to be functionally buffered against loss prior to fishing activities, using functional trait combinations, in coral reef fish assemblages across unfished wilderness areas of the Indo-Pacific: Chagos Archipelago, New Caledonia and French Polynesia. Fish functional diversity in these wilderness areas is highly vulnerable to fishing, explained by species- and abundance-based redundancy packed into a small combination of traits, leaving most other trait combinations (60%) sensitive to fishing, with no redundancy. Functional vulnerability peaks for mobile and sedentary top predators, and large species in general. Functional vulnerability decreases for certain functional entities in New Caledonia, where overall functional redundancy was higher. Uncovering these baseline patterns of functional vulnerability can offer early warning signals of the damaging effects from fishing, and may serve as baselines to guide precautionary and even proactive conservation actions. [ABSTRACT FROM AUTHOR]

Published

2016

19. The challenge of delineating biogeographical regions: nestedness matters for Indo-Pacific coral reef fishes.

Author

Mouillot, David, De Bortoli, Julien, Leprieur, Fabien, Parravicini, Valeriano, Kulbicki, Michel, Bellwood, David R., and Jetz, Walter

Subjects

BIOGEOGRAPHY, SPECIES diversity, FISH nests, CORAL reef fishes, PARSIMONIOUS models

Abstract

Aim The delineation of regions is a critical procedure in biogeography, but there is still no consensus about the best approach. Traditionally, a compositional dissimilarity index and a clustering algorithm are used to partition locations into regions. However, the choice of index and algorithm may have a profound impact on the final result, particularly when locations display different levels of species richness and when they are nested within each other. Our objective was to estimate the influence of species nestedness among locations on the delineation of biogeographical regions. Location As a case study, we used coral reef fishes (families Chaetodontidae, Pomacentridae and Labridae) from the Indo-Pacific, where a large richness gradient extends, often as a series of nested assemblages, from the species-rich Indo-Australian Archipelago (Coral Triangle) to species-poor peripheral locations. Methods We used the turnover and nestedness components of the Sørensen and Jaccard dissimilarity indices to estimate the effect of nestedness on the delineation of biogeographical regions. In addition, we compared the results with those obtained using a parsimony analysis of endemicity ( PAE). Results Low Mantel correlation values revealed that the PAE method assembled locations in a very different way than methods based on dissimilarity indices for Indo-Pacific coral reef fishes. We also found that nestedness mattered when delineating biogeographical units because, for both the Sørensen and the Jaccard indices, reef fish assemblages were grouped differently depending on whether we used the turnover component of each index or the complete index, including the nestedness component. The turnover component ignored variation in species richness attributable to differences in habitat area between locations, and permitted a delineation based solely on species replacement. Main conclusions We demonstrate that the choice of the component used to measure dissimilarity between species assemblages is critical, because it may strongly influence regional delineations, at least for Indo-Pacific coral reef fishes. We conclude that the two components of the dissimilarity indices can reveal complementary insights into the role that history may have played in shaping extant patterns of biodiversity. [ABSTRACT FROM AUTHOR]

Published

2013

20. Individual back-calculated size-at-age based on otoliths from Pacific coral reef fish species.

Author

Morat, Fabien, Wicquart, Jérémy, Schiettekatte, Nina M. D., de Sinéty, Guillemette, Bienvenu, Jean, Casey, Jordan M., Brandl, Simon J., Vii, Jason, Carlot, Jérémy, Degregori, Samuel, Mercière, Alexandre, Fey, Pauline, Galzin, René, Letourneur, Yves, Sasal, Pierre, and Parravicini, Valeriano

Subjects

OTOLITHS, CORAL reef fishes, ECOSYSTEMS, BIOMASS, DEEP learning

Abstract

Somatic growth is a critical biological trait for organismal, population, and ecosystem-level processes. Due to its direct link with energetic demands, growth also represents an important parameter to estimate energy and nutrient fluxes. For marine fishes, growth rate information is most frequently derived from sagittal otoliths, and most of the available data stems from studies on temperate species that are targeted by commercial fisheries. Although the analysis of otoliths is a powerful tool to estimate individual growth, the time-consuming nature of otolith processing is one barrier for collection of comprehensive datasets across multiple species. This is especially true for coral reef fishes, which are extremely diverse. Here, we provide back-calculated size-at-age estimates (including measures of uncertainty) based on sagittal otoliths from 710 individuals belonging to 45 coral reef fish species from French Polynesia. In addition, we provide Von Bertalanffy growth parameters which are useful to predict community level biomass production. Measurement(s) growth Technology Type(s) otolithometry Sample Characteristic - Organism Actinopterygii Sample Characteristic - Environment coral reef Sample Characteristic - Location French Polynesia Machine-accessible metadata file describing the reported data: 10.6084/m9.figshare.13027817 [ABSTRACT FROM AUTHOR]

Published

2020

21. Shore fishes of French Polynesia

Author

Siu, Gilles, Bacchet, Philippe, Bernardi, Giacomo, Brooks, Andrew J., Carlot, Jeremy, Causse, Romain, Joachim Claudet, Clua, Eric, Delrieu-Trottin, Erwan, Espiau, Benoit, Harmelin-Vivien, Mireille, Keith, Philippe, Lecchini, David, Madi-Moussa, Rakamaly, Parravicini, Valeriano, Planes, Serge, Ponsonnet, Cedric, Randall, John E., Sasal, Pierre, Taquet, Marc, Williams, Jeffrey T., Galzin, Rene, Institut méditerranéen d'océanologie (MIO), Institut de Recherche pour le Développement (IRD)-Aix Marseille Université (AMU)-Institut national des sciences de l'Univers (INSU - CNRS)-Université de Toulon (UTLN)-Centre National de la Recherche Scientifique (CNRS), and Institut de Recherche pour le Développement (IRD)-Aix Marseille Université (AMU)-Institut national des sciences de l'Univers (INSU - CNRS)-Centre National de la Recherche Scientifique (CNRS)-Université de Toulon (UTLN)

Subjects

Deep and Pelagic fishes, Endemic fishes, Coral reef fishes, Inventory, [SDE]Environmental Sciences, French Polynesia, Freshwater fishes, ComputingMilieux_MISCELLANEOUS

Abstract

On the occasion of the 10th Indo-Pacific Fish Conference (http://ipfc10.criobe.pf/) to be held in Tahiti in October 2017, it seemed timely to update Randall’s 1985 list of the fishes known from French Polynesia. Many studies focusing on fishes in this area have been published since 1985, but Randall’s list remains the authoritative source. Herein we present an expanded species list of 1,301 fishes now known to occur in French Polynesia and we review the expeditions and information sources responsible for the over 60% increase in the number of known species since the publication of Randall’s checklist in 1985. Our list of the fishes known from French Polynesia includes only those species with a reliably verifiable presence in these waters. In cases where there was any doubt about the identity of a species, or of the reliability of a reported sighting, the species was not included in our list.