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1. Acquisition of obligate mutualist symbionts during the larval stage is not beneficial for a coral host

   https://doi.org/10.1111/mec.14967  

   Hartmann, Aaron C. ; Marhaver, Kristen L. ; Klueter, Anke ; Lovci, Michael T. ; Closek, Collin J. ; Diaz, Erika ; Chamberland, Valérie F. ; Archer, Frederick I. ; Deheyn, Dimitri D. ; Vermeij, Mark J. A. ; et al ( January 2019 , Molecular Ecology)

   Theory suggests that the direct transmission of beneficial endosymbionts (mutualists) from parents to offspring (vertical transmission) in animal hosts is advantageous and evolutionarily stable, yet many host species instead acquire their symbionts from the environment (horizontal acquisition). An outstanding question in marine biology is why some scleractinian corals do not provision their eggs and larvae with the endosymbiotic dinoflagellates that are necessary for a juvenile's ultimate survival. We tested whether the acquisition of photosynthetic endosymbionts (family Symbiodiniaceae) during the planktonic larval stage was advantageous, as is widely assumed, in the ecologically important and threatened Caribbean reef‐building coralOrbicella faveolata. Following larval acquisition, similar changes occurred in host energetic lipid use and gene expression regardless of whether their symbionts were photosynthesizing, suggesting the symbionts did not provide the energetic benefit characteristic of the mutualism in adults. Larvae that acquired photosymbionts isolated from conspecific adults on their natal reef exhibited a reduction in swimming, which may interfere with their ability to find suitable settlement substrate, and also a decrease in survival. Larvae exposed to two cultured algal species did not exhibit differences in survival, but decreased their swimming activity in response to one species. We conclude that acquiring photosymbionts during the larval stage confers no advantages and can in fact be disadvantageous to this coral host. The timing of symbiont acquisition appears to be a critical component of a host's life history strategy and overall reproductive fitness, and this timing itself appears to be under selective pressure.

    

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2. Formal recognition of host‐generalist species of dinoflagellate ( Cladocopium , Symbiodiniaceae) mutualistic with Indo‐Pacific reef corals

   https://doi.org/10.1111/jpy.13340  

   Butler, Caleb C. ; Turnham, Kira E. ; Lewis, Allison M. ; Nitschke, Matthew R. ; Warner, Mark E. ; Kemp, Dustin W. ; Hoegh‐Guldberg, Ove ; Fitt, William K. ; van Oppen, Madeleine J. H. ; LaJeunesse, Todd C. ( May 2023 , Journal of Phycology)

   The existence of widespread species with the capacity to endure diverse, or variable, environments are of importance to ecological and genetic research, and conservation. Such “ecological generalists” are more likely to have key adaptations that allow them to better tolerate the physiological challenges of rapid climate change. Reef‐building corals are dependent on endosymbiotic dinoflagellates (Family: Symbiodiniaceae) for their survival and growth. While these symbionts are biologically diverse, certain genetic types appear to have broad geographic distributions and are mutualistic with various host species from multiple genera and families in the order Scleractinia that must acquire their symbionts through horizontal transmission. Despite the considerable ecological importance of putative host‐generalist symbionts, they lack formal species descriptions. In this study, we used molecular, ecological, and morphological evidence to verify the existence of five new host‐generalist species in the symbiodiniacean genusCladocopium. Their geographic distribution and prevalence among host communities corresponds to prevailing environmental conditions at both regional and local scales. The influence that each species has on host physiology may partially explain regional differences in thermal sensitivities among coral communities. The potential increased prevalence of a generalist species that endures environmental instability is a consequential ecological response to warming oceans. Large‐scale shifts in symbiont dominance could ensure reef coral persistence and productivity in the near term. Ultimately, these formal designations should advance scientific communication and generate informed research questions on the physiology and ecology of coral‐dinoflagellate mutualisms.

    

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3. Cladocopium community divergence in two Acropora coral hosts across multiple spatial scales

   https://doi.org/10.1111/mec.15668  

   Davies, Sarah W. ; Moreland, Kelsey N. ; Wham, Drew C. ; Kanke, Matt R. ; Matz, Mikhail V. ( October 2020 , Molecular Ecology)

   Many broadly‐dispersing corals acquire their algal symbionts (Symbiodiniaceae) “horizontally” from their environment upon recruitment. Horizontal transmission could promote coral fitness across diverse environments provided that corals can associate with divergent algae across their range and that these symbionts exhibit reduced dispersal potential. Here we quantified community divergence ofCladocopiumalgal symbionts in two coral host species (Acropora hyacinthus, Acropora digitifera) across two spatial scales (reefs on the same island, and between islands) across the Micronesian archipelago using microsatellites. We find that both hosts associated with a variety of multilocus genotypes (MLG) within two genetically distinctCladocopiumlineages (C40, C21), confirming thatAcroporacoral hosts associate with a range ofCladocopiumsymbionts across this region. Both C40 and C21 included multiple asexual lineages bearing identical MLGs, many of which spanned host species, reef sites within islands, and even different islands. Both C40 and C21 exhibited moderate host specialization and divergence across islands. In addition, within every island, algal symbiont communities were significantly clustered by both host species and reef site, highlighting that coral‐associatedCladocopiumcommunities are structured across small spatial scales and within hosts on the same reef. This is in stark contrast to their coral hosts, which never exhibited significant genetic divergence between reefs on the same island. These results support the view that horizontal transmission could improve local fitness for broadly dispersingAcroporacoral species.

    

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4. Ecophysiology of mesophotic reef‐building corals in Hawai‘i is influenced by symbiont–host associations, photoacclimatization, trophic plasticity, and adaptation

   https://doi.org/10.1002/lno.11164  

   Padilla‐Gamiño, Jacqueline L. ; Roth, Melissa S. ; Rodrigues, Lisa J. ; Bradley, Christina J. ; Bidigare, Robert R. ; Gates, Ruth D. ; Smith, Celia M. ; Spalding, Heather L. ( April 2019 , Limnology and Oceanography)

   Mesophotic reef corals remain largely unexplored in terms of the genetic adaptations and physiological mechanisms to acquire, allocate, and use energy for survival and reproduction. In the Hawaiian Archipelago, theLeptoserisspecies complex form the most spatially extensive mesophotic coral ecosystem known and provide habitat for a unique community. To study how the ecophysiology ofLeptoserisspecies relates to symbiont–host specialization and understand the mechanisms responsible for coral energy acquisition in extreme low light environments, we examinedSymbiodinium(endosymbiotic dinoflagellate) photobiological characteristics and the lipids and isotopic signatures fromSymbiodiniumand coral hosts over a depth‐dependent light gradient (55–7μmol photons m⁻²s⁻¹, 60–132 m). Clear performance differences demonstrate different photoadaptation and photoacclimatization across this genus. Our results also show that flexibility in photoacclimatization depends primarily onSymbiodiniumtype. Colonies harboringSymbiodiniumsp.COI‐2showed significant increases in photosynthetic pigment content with increasing depth, whereas colonies harboringSymbiodiniumspp.COI‐1andCOI‐3showed variability in pigment composition, yield measurements for photosystem II, as well as size and density ofSymbiodiniumcells. Despite remarkable differences in photosynthetic adaptive strategies, there were no significant differences among lipids ofLeptoserisspecies with depth. Finally, isotopic signatures of both host andSymbiodiniumchanged with depth, indicating that coral colonies acquired energy from different sources depending on depth. This study highlights the complexity in physiological adaptations within this symbiosis and the different strategies used by closely related mesophotic species to diversify energy acquisition and to successfully establish and compete in extreme light‐limited environments.

    

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5. Fish predation on corals promotes the dispersal of coral symbionts

   https://doi.org/10.1186/s42523-021-00086-4  

   Grupstra, Carsten G. ; Rabbitt, Kristen M. ; Howe-Kerr, Lauren I. ; Correa, Adrienne M. ( December 2021 , Animal Microbiome)

   null (Ed.)

   Abstract Background The microbiomes of foundation (habitat-forming) species such as corals and sponges underpin the biodiversity, productivity, and stability of ecosystems. Consumers shape communities of foundation species through trophic interactions, but the role of consumers in dispersing the microbiomes of such species is rarely examined. For example, stony corals rely on a nutritional symbiosis with single-celled endosymbiotic dinoflagellates (family Symbiodiniaceae) to construct reefs. Most corals acquire Symbiodiniaceae from the environment, but the processes that make Symbiodiniaceae available for uptake are not resolved. Here, we provide the first comprehensive, reef-scale demonstration that predation by diverse coral-eating (corallivorous) fish species promotes the dispersal of Symbiodiniaceae, based on symbiont cell densities and community compositions from the feces of four obligate corallivores, three facultative corallivores, two grazer/detritivores as well as samples of reef sediment and water. Results Obligate corallivore feces are environmental hotspots of Symbiodiniaceae cells: live symbiont cell concentrations in such feces are 5–7 orders of magnitude higher than sediment and water environmental reservoirs. Symbiodiniaceae community compositions in the feces of obligate corallivores are similar to those in two locally abundant coral genera ( Pocillopora and Porites ), but differ from Symbiodiniaceae communities in the feces of facultative corallivores and grazer/detritivores as well as sediment and water. Combining our data on live Symbiodiniaceae cell densities in feces with in situ observations of fish, we estimate that some obligate corallivorous fish species release over 100 million Symbiodiniaceae cells per 100 m 2 of reef per day. Released corallivore feces came in direct contact with coral colonies in the fore reef zone following 91% of observed egestion events, providing a potential mechanism for the transfer of live Symbiodiniaceae cells among coral colonies. Conclusions Taken together, our findings show that fish predation on corals may support the maintenance of coral cover on reefs in an unexpected way: through the dispersal of beneficial coral symbionts in corallivore feces. Few studies examine the processes that make symbionts available to foundation species, or how environmental reservoirs of such symbionts are replenished. This work sets the stage for parallel studies of consumer-mediated microbiome dispersal and assembly in other sessile, habitat-forming species. 

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