scholarly journals Intra-genomic variation in symbiotic dinoflagellates: Recent divergence or natural hybridization?

2021 ◽  
Author(s):  
◽  
Shaun Peter Wilkinson
Keyword(s):  
Field Experiments ◽  
Genetic Material ◽  
Photosynthetic Performance ◽  
Genomic Variation ◽  
Natural Hybridization ◽  
Coral Host ◽  
Pocillopora Damicornis ◽  
Evolutionary Potential ◽  
Lord Howe Island ◽  
Putative Hybrids

<p>The perpetuity of coral reefs will ultimately depend on the ability of corals to adapt to changing conditions. Inter-specific hybridization can provide the raw genetic material necessary for adaptation, and stimulate macro-evolutionary leaps during periods of environmental upheaval. Though well-documented in corals, hybridization has yet to be identified in their dinoflagellate symbionts (genus Symbiodinium), despite growing evidence of sexual reproduction in this genus. The integral roles that these symbiotic algae play in coral productivity, reef accretion and ‘coral bleaching’ emphasize the need to better understand their short-term evolutionary potential. In this thesis, I develop new molecular and statistical methodology, and combine lab- and field-based analysis to explore the potential for hybridization between divergent Symbiodinium taxa.  To screen for putative Symbiodinium hybrids, intra-genomic variation was examined within individual symbionts isolated from the reef-building coral Pocillopora damicornis at Lord Howe Island (Australia). A nested quantitative PCR (qPCR) assay was developed to quantify polymorphic internal transcribed spacer 2 (ITS2) sequences within the genome of each symbiont cell. Three genetically distinct Symbiodinium populations were detected co-existing within the symbiont consortium of P. damicornis. Mixed populations of ‘pure’ Symbiodinium types C100 and C109 coexisted with a population of cells hosting co-dominant C100 and C109 ITS2 repeats. Genetically heterogeneous Symbiodinium cells were more common than homogeneous symbionts in four of the six colonies analysed, with a maximum proportional abundance of 89%.  Morphological, functional and ecological attributes of heterogeneous Symbiodinium cells were characterized to assess their candidacy as putative hybrids. The proportional abundance of genetically heterogeneous symbionts was spatially and temporally conserved within colonies, indicating a lack of competition between Symbiodinium populations. However, this abundance ratio varied considerably between colonies separated by metres to tens of metres, and to a greater extent between sites isolated by hundreds to thousands of metres. The local thermal maximum emerged as a significant predictor of the proportional abundance of genetically heterogeneous Symbiodinium cells, suggesting that the distribution of these ‘putative hybrids’ is influenced by a reduced affinity for thermal stress.  Genetically heterogeneous Symbiodinium cells were around 50% larger (by volume) than homogeneous cells, occupied tissue of the coral host at reduced densities, and showed relatively poor light-harvesting efficiency. Colonies hosting a higher proportion of these symbionts suffered a reduction in overall photosynthetic performance (maximum gross photosynthesis normalised to respiration; P:R) at the ambient temperature of 25 °C. This disparity was maintained when the temperature was elevated to simulate the maximum experienced within the LHI lagoon (29 °C). Under these stressful conditions, colonies dominated by putative Symbiodinium hybrids were only marginally capable of net oxygen production.  The influence of putative Symbiodinium hybrids on the growth and survival of P. damicornis was tested by reciprocally transplanting coral colonies between reef sites featuring distinct temperature regimes. Neither calcification nor mortality was influenced by the proportional abundance of genetically heterogeneous cells in the symbiont consortium. This uncoupling of symbiont performance and host fitness may be explained by stochastic events such as predation and disease, which substantially increase variation in growth and mortality in field experiments. Alternatively, it may represent some unknown benefit associated with hosting hybrid symbionts, belying their relatively poor photosynthetic performance, and explaining the widespread abundance of these heterogeneous Symbiodinium cells on the Lord Howe Island reef.  Our inability to maintain many clade C Symbiodinium types in culture prevents direct observations of hybridization between C100 and C109. Unequivocal evidence of this phenomenon will therefore likely remain elusive until high-resolution, single-copy nuclear markers can be developed, since the incomplete displacement of ancestral polymorphisms can leave a similar genomic signature to that of hybridization. However, this study serves to provide an initial proof-of-principle for hybridization between divergent Symbiodinium taxa. In doing so, it highlights the need to better understand the evolutionary processes underpinning coral- and symbiont-adaptation in a changing climate.</p>

scholarly journals Intra-genomic variation in symbiotic dinoflagellates: Recent divergence or natural hybridization?

2021 ◽  
Author(s):  
◽  
Shaun Peter Wilkinson
Keyword(s):  
Field Experiments ◽  
Genetic Material ◽  
Photosynthetic Performance ◽  
Genomic Variation ◽  
Natural Hybridization ◽  
Coral Host ◽  
Pocillopora Damicornis ◽  
Evolutionary Potential ◽  
Lord Howe Island ◽  
Putative Hybrids

<p>The perpetuity of coral reefs will ultimately depend on the ability of corals to adapt to changing conditions. Inter-specific hybridization can provide the raw genetic material necessary for adaptation, and stimulate macro-evolutionary leaps during periods of environmental upheaval. Though well-documented in corals, hybridization has yet to be identified in their dinoflagellate symbionts (genus Symbiodinium), despite growing evidence of sexual reproduction in this genus. The integral roles that these symbiotic algae play in coral productivity, reef accretion and ‘coral bleaching’ emphasize the need to better understand their short-term evolutionary potential. In this thesis, I develop new molecular and statistical methodology, and combine lab- and field-based analysis to explore the potential for hybridization between divergent Symbiodinium taxa.  To screen for putative Symbiodinium hybrids, intra-genomic variation was examined within individual symbionts isolated from the reef-building coral Pocillopora damicornis at Lord Howe Island (Australia). A nested quantitative PCR (qPCR) assay was developed to quantify polymorphic internal transcribed spacer 2 (ITS2) sequences within the genome of each symbiont cell. Three genetically distinct Symbiodinium populations were detected co-existing within the symbiont consortium of P. damicornis. Mixed populations of ‘pure’ Symbiodinium types C100 and C109 coexisted with a population of cells hosting co-dominant C100 and C109 ITS2 repeats. Genetically heterogeneous Symbiodinium cells were more common than homogeneous symbionts in four of the six colonies analysed, with a maximum proportional abundance of 89%.  Morphological, functional and ecological attributes of heterogeneous Symbiodinium cells were characterized to assess their candidacy as putative hybrids. The proportional abundance of genetically heterogeneous symbionts was spatially and temporally conserved within colonies, indicating a lack of competition between Symbiodinium populations. However, this abundance ratio varied considerably between colonies separated by metres to tens of metres, and to a greater extent between sites isolated by hundreds to thousands of metres. The local thermal maximum emerged as a significant predictor of the proportional abundance of genetically heterogeneous Symbiodinium cells, suggesting that the distribution of these ‘putative hybrids’ is influenced by a reduced affinity for thermal stress.  Genetically heterogeneous Symbiodinium cells were around 50% larger (by volume) than homogeneous cells, occupied tissue of the coral host at reduced densities, and showed relatively poor light-harvesting efficiency. Colonies hosting a higher proportion of these symbionts suffered a reduction in overall photosynthetic performance (maximum gross photosynthesis normalised to respiration; P:R) at the ambient temperature of 25 °C. This disparity was maintained when the temperature was elevated to simulate the maximum experienced within the LHI lagoon (29 °C). Under these stressful conditions, colonies dominated by putative Symbiodinium hybrids were only marginally capable of net oxygen production.  The influence of putative Symbiodinium hybrids on the growth and survival of P. damicornis was tested by reciprocally transplanting coral colonies between reef sites featuring distinct temperature regimes. Neither calcification nor mortality was influenced by the proportional abundance of genetically heterogeneous cells in the symbiont consortium. This uncoupling of symbiont performance and host fitness may be explained by stochastic events such as predation and disease, which substantially increase variation in growth and mortality in field experiments. Alternatively, it may represent some unknown benefit associated with hosting hybrid symbionts, belying their relatively poor photosynthetic performance, and explaining the widespread abundance of these heterogeneous Symbiodinium cells on the Lord Howe Island reef.  Our inability to maintain many clade C Symbiodinium types in culture prevents direct observations of hybridization between C100 and C109. Unequivocal evidence of this phenomenon will therefore likely remain elusive until high-resolution, single-copy nuclear markers can be developed, since the incomplete displacement of ancestral polymorphisms can leave a similar genomic signature to that of hybridization. However, this study serves to provide an initial proof-of-principle for hybridization between divergent Symbiodinium taxa. In doing so, it highlights the need to better understand the evolutionary processes underpinning coral- and symbiont-adaptation in a changing climate.</p>

scholarly journals Evaluating the genetic variability of rubber hybrid progenies of the two crosses PB260 x RO44/71 and PB260 x RO62/54 by RAPD technique

2019 ◽  
Vol 2 (3) ◽  
pp. 36-43
Author(s):  
Thien Minh Nguyen ◽  
Tien Thi My Pham
Keyword(s):  
Genetic Variation ◽  
Genetic Variability ◽  
Genetic Similarity ◽  
Field Experiments ◽  
Agronomic Traits ◽  
Genetic Relationships ◽  
Genetic Material ◽  
Population Based ◽  
Shannon Index ◽  
Polymorphic Bands

The agronomic values of this population have been evaluated in the field experiments based on their phenotypic performance of agronomic traits, but the genetic variability of this population needs to be evaluated via techniques based on genetic material - DNA. In this study, the genetic variability in the investigated population of 71 hybrids and their parents was evaluated by RAPD technique, using eight selected arbitrarily primers; Genetic parameters and dendrogram expressing the genetic relationships among the investigated population were analyzed by GenALEx 6.1, Popgene 1.31 and NTSYSpc 2.1 softwares. Eight primers were used to generate the amplify products on each individual in the investigated population. From 74 genotypes, a total of 109 fragments were generated, among which, there were 89 polymorphic bands representing 81.65% with an average of 11 polymorphic bands/primer. Genetic similarity coefficient among the investigated population, based on DICE coefficient, ranged from 0.560 (LH05/0822 and PB260) to 0.991 (LH05/0781 and LH05/0841) with an average of 0,796, meaning that the genetic distance among ranged from 0.009 to 0.440 with an average of 0.231. The Shannon index and mean heterozygosity values were 0.328 and 0,176, respectively. This indicated that the progenies of the two investigated crosses possessed a relatively high range of genetic variability. The analysis of molecular variance (AMOVA) showed that genetic variation within population represented 62%, while genetic variation among two different crosses contributes 38% to the total genetic variability. Dendrogram based on DICE’s genetic similarity using UPGMA method showed that the hybrids divide into two major genetic groups (0.75), but the crosses were scattered independently of the hybrid.

scholarly journals Multi-model seascape genomics identifies distinct environmental drivers of selection among sympatric marine species

2020 ◽  
Author(s):  
Erica Nielsen ◽  
Romina Henriques ◽  
Maria Beger ◽  
Robert Toonen ◽  
Sophie von der Heyden
Keyword(s):  
Global Change ◽  
Outlier Detection ◽  
Genomic Variation ◽  
Sea Surface ◽  
Environmental Drivers ◽  
Comparative Approach ◽  
Evolutionary Potential ◽  
Environmental Selection ◽  
Outlier Loci ◽  
Isolation By Environment

Abstract Background: As global change and anthropogenic pressures continue to increase, conservation and management increasingly needs to consider species’ potential to adapt to novel environmental conditions. Therefore, it is imperative to characterise the main selective forces acting on ecosystems, and how these may influence the evolutionary potential of populations and species. Using a multi-model seascape genomics approach, we compare putative environmental drivers of selection in three sympatric southern African marine invertebrates with contrasting ecology and life histories: Cape urchin (Parechinus angulosus), Common shore crab (Cyclograpsus punctatus), and Granular limpet (Scutellastra granularis). Results: Using pooled (Pool-seq), restriction-site associated DNA sequencing (RAD-seq), and seven outlier detection methods, we characterise genomic variation between populations along a strong biogeographical gradient. Of the three species, only S. granularis showed significant isolation-by-distance, and isolation-by-environment driven by sea surface temperatures (SST). In contrast, sea surface salinity (SSS) and range in air temperature correlated more strongly with genomic variation in C. punctatus and P. angulosus. Differences were also found in genomic structuring between the three species, with outlier loci contributing to two clusters in the East and West Coasts for S. granularis and P. angulosus, but not for C. punctatus. Conclusion: The findings illustrate distinct evolutionary potential across species, suggesting that species-specific habitat requirements and responses to environmental stresses may be better predictors of evolutionary patterns than the strong environmental gradients within the region. We also found large discrepancies between outlier detection methodologies, and thus offer a novel multi-model approach to identifying the principal environmental selection forces acting on species. Overall, this work highlights how adding a comparative approach to seascape genomics (both with multiple models and species) can elucidate the intricate evolutionary responses of ecosystems to global change.

scholarly journals Multi-model seascape genomics identifies distinct environmental drivers of selection among sympatric marine species

2020 ◽  
Author(s):  
Erica Nielsen ◽  
Romina Henriques ◽  
Maria Beger ◽  
Robert Toonen ◽  
Sophie von der Heyden
Keyword(s):  
Global Change ◽  
Outlier Detection ◽  
Genomic Variation ◽  
Sea Surface ◽  
Environmental Drivers ◽  
Comparative Approach ◽  
Evolutionary Potential ◽  
Environmental Selection ◽  
Outlier Loci ◽  
Isolation By Environment

Abstract Background: As global change and anthropogenic pressures continue to increase, conservation and management increasingly needs to consider species’ potential to adapt to novel environmental conditions. Therefore, it is imperative to characterise the main selective forces acting on ecosystems, and how these may influence the evolutionary potential of populations and species. Using a multi-model seascape genomics approach, we compare the dominant environmental drivers of selection in three sympatric southern African marine invertebrates with contrasting ecology and life histories: Cape urchin ( Parechinus angulosus ), Common shore crab ( Cyclograpsus punctatu s), and Granular limpet ( Scutellastra granularis ). Results: Using pooled (Pool-seq), restriction-site associated DNA sequencing (RAD-seq), and seven outlier detection methods, we characterise genomic variation between populations along a strong biogeographical gradient. Of the three species, only S. granularis showed significant isolation-by-distance, and isolation-by-environment driven by sea surface temperatures (SST). In contrast, sea surface salinity (SSS) and range in air temperature correlated more strongly with genomic variation in C. punctatus and P. angulosus . Differences were also found in genomic structuring between the three species, with outlier loci contributing to two clusters in the East and West Coasts for S. granularis and P. angulosus , but not for C. punctatus . Conclusion: The findings illustrate distinct evolutionary potential across species, suggesting that species-specific habitat requirements and responses to environmental stresses better predict evolutionary patterns than the strong environmental gradients within the region. We also found large discrepancies between outlier detection methodologies, and thus offer a novel multi-model approach to identifying the principal environmental selection forces acting on species. Overall, this work highlights how adding a comparative approach to seascape genomics (both with multiple models and species) can elucidate the intricate evolutionary responses of ecosystems to global change.

scholarly journals Intraspecific genomic variation and local adaptation in a young hybrid species

2019 ◽  
Author(s):  
Angélica Cuevas ◽  
Mark Ravinet ◽  
Glenn-Peter Sætre ◽  
Fabrice Eroukhmanoff
Keyword(s):  
Genetic Variation ◽  
Local Adaptation ◽  
Climatic Variation ◽  
Genomic Variation ◽  
Population Divergence ◽  
Parent Species ◽  
Evolutionary Potential ◽  
Variable Environment ◽  
Hybrid Species ◽  
Species Population

ABSTRACTHybridization increases genetic variation, hence hybrid species may have a strong evolutionary potential once their admixed genomes have stabilized and incompatibilities have been purged. Yet, little is known about how such hybrid lineages evolve at the genomic level following their formation, in particular the characteristics of their adaptive potential, i.e. constraints and facilitations of diversification. Here we investigate how the Italian sparrow (Passer italiae), a homoploid hybrid species, has evolved and locally adapted to its variable environment. Using restriction site-associated DNA sequencing (RAD-seq) on several populations across the Italian peninsula, we evaluate how genomic constraints and novel genetic variation have influenced population divergence and adaptation. We show that population divergence within this hybrid species has evolved in response to climatic variation. As in non-hybrid species, climatic differences may even reduce gene flow between populations, suggesting ongoing local adaptation. We report outlier genes associated with adaptation to climatic variation, known to be involved in beak morphology in other species. Most of the strongly divergent loci among Italian sparrow populations seem not to be differentiated between its parent species, the house and Spanish sparrow. Within the parental species, population divergence has occurred mostly in loci where different alleles segregate in the parent species, unlike in the hybrid, suggesting that novel combinations of parental alleles in the hybrid have not necessarily enhanced its evolutionary potential. Rather, our study suggests that constraints linked to incompatibilities may have restricted the evolution of this admixed genome, both during and after hybrid species formation.

scholarly journals Microscale tracking of coral disease reveals timeline of infection and heterogeneity of polyp fate

2018 ◽  
Author(s):  
Assaf R. Gavish ◽  
Orr H. Shapiro ◽  
Esti Kramarsky-Winter ◽  
Assaf Vardi
Keyword(s):  
Disease Progression ◽  
Defense Mechanism ◽  
Coral Disease ◽  
Coral Host ◽  
Pocillopora Damicornis ◽  
Spatial And Temporal Scales ◽  
Infection Dynamics ◽  
Key Steps ◽  
Coral Pathogen ◽  
Gastrovascular System

AbstractCoral disease is often studied at scales ranging from single colonies to the entire reef. This is particularly true for studies following disease progression through time. To gain a mechanistic understanding of key steps underlying infection dynamics, it is necessary to study disease progression, and host-pathogen interactions, at relevant microbial scales. Here we provide a dynamic view of the interaction between the model coral pathogen Vibrio coralliilyticus and its coral host Pocillopora damicornis at unprecedented spatial and temporal scales. This view is achieved using a novel microfluidics-based system specifically designed to allow microscopic study of coral infection in-vivo under controlled environmental conditions. Analysis of exudates continuously collected at the system’s outflow, allows a detailed biochemical and microbial analyses coupled to the microscopic observations of the disease progression. The resulting multilayered dataset provides the most detailed description of a coral infection to-date, revealing distinct pathogenic processes as well as the defensive behavior of the coral host. We provide evidence that infection in this system occurs following ingestion of the pathogen, and may then progress through the gastrovascular system. We further show infection may spread when pathogens colonize lesions in the host tissue. Copious spewing of pathogen-laden mucus from the polyp mouths results in effective expulsion of the pathogen from the gastrovascular system, possibly serving as a first line of defense. A secondary defense mechanism entails the severing of calicoblastic connective tissues resulting in the controlled isolation of diseased polyps, or the survival of individual polyps within infected colonies. Further investigations of coral-pathogen interactions at these scales will help to elucidate the complex interactions underlying coral disease, as we as the versatile adaptive response of the coral ecosystems to fluctuating environments.

Hybridization in leopard frogs (Rana pipiens complex): terrestrial performance of newly metamorphosed hybrid and parental genotypes in field enclosures

2001 ◽  
Vol 79 (9) ◽  
pp. 1552-1558 ◽  
Author(s):  
Matthew J Parris
Keyword(s):  
Growth Rates ◽  
Life Histories ◽  
Parental Species ◽  
Natural Populations ◽  
Life Cycles ◽  
Natural Hybridization ◽  
Evolutionary Potential ◽  
Leopard Frogs ◽  
Rana Blairi ◽  
Advanced Generation

Terrestrial ecology has been largely neglected in the study of amphibian life histories because it is difficult to manipulate most species during the terrestrial stage. I examined the terrestrial performance of Rana blairi, Rana sphenocephala, and four hybrid (two F1 and two advanced generation) genotypes in replicated experimental enclosures to test for differences in traits related to juvenile terrestrial fitness. I produced all genotypes by means of artificial fertilizations using frogs collected from natural populations in central Missouri, and juvenile frogs were obtained from larvae reared in experimental ponds. Following metamorphosis, froglets were raised in single-genotype groups in terrestrial enclosures through the first overwintering. The proportion surviving did not vary among genotypes, but the power to detect significant differences was low. F1 hybrid genotypes BS and SB demonstrated significantly higher growth rates than either parental species or advanced-generation hybrid genotypes. Observation of growth rates of advanced-generation hybrids equal to those of the parental species, and heterosis in F1 hybrids for growth rate, suggests that natural hybridization between R. blairi and R. sphenocephala can produce novel and relatively fit hybrid genotypes. Direct measurement of multiple fitness components for hybrid and parental genotypes is critical for assessing the evolutionary potential of natural hybridization in organisms with complex life cycles.

Intra-genomic variation in Symbiodinium correlates negatively with photosynthetic efficiency and coral host performance

Coral Reefs ◽  
2018 ◽  
Vol 37 (3) ◽  
pp. 691-701 ◽  
Author(s):  
Shaun P. Wilkinson ◽  
Joshua I. Brian ◽  
Stefanie Pontasch ◽  
Paul L. Fisher ◽  
Simon K. Davy
Keyword(s):  
Photosynthetic Efficiency ◽  
Genomic Variation ◽  
Coral Host

scholarly journals Bivariate analysis of barley scald resistance with relative maturity reveals a new major QTL on chromosome 3H

2019 ◽  
Author(s):  
Xuechen Zhang ◽  
Ben Ovenden ◽  
Beverley A. Orchard ◽  
Meixue Zhou ◽  
Robert F. Park ◽  
...  
Keyword(s):  
Growth Stage ◽  
Field Experiments ◽  
Natural Infection ◽  
Genetic Material ◽  
Seedling Stage ◽  
Bivariate Analysis ◽  
Doubled Haploid Population ◽  
Seedling Resistance ◽  
Adult Growth ◽  
Major Qtl

AbstractThe disease scald of barley is caused by the pathogen Rhynchosporium commune and can cause up to 30-40% yield loss in susceptible varieties. In this study, the Australian barley cultivar Yerong was demonstrated to have resistance that differed from Turk (Rrs1) based on seedling tests with 11 R. commune isolates. A doubled haploid population with 177 lines derived from a cross between Yerong and Franklin was used to identify quantitative trait loci (QTL) for scald resistance. Scald resistance against four pathogen isolates was assessed at the seedling growth stage in a glasshouse experiment and at the adult growth stage in field experiments with natural infection over three consecutive years. A QTL on chromosome 3H was identified with large effect, consistent with a major gene conferring scald resistance at the seedling stage. Under field conditions, scald percentage was negatively correlated with early relative maturity. A bivariate analysis was used to model scald percentage and relative maturity together, residuals from the regression of scald percentage on relative maturity were used as our phenotype for QTL analysis. This analysis identified one major QTL on chromosome 3H, which mapped to the same position as the QTL identified for scald resistance at seedling stage. The identified QTL on 3H is proposed to be different from the Rrs1 on the basis of seedling resistance against different R. commune isolates and physical map position. The analysis also identified an additional novel QTL on chromosome 7H. This study increases the current understanding of scald resistance and identifies genetic material possessing QTLs useful for the marker-assisted selection of scald resistance in barley breeding programs.

scholarly journals Effect of feeding and thermal stress on photosynthesis, respiration and the carbon budget of the scleractinian coral Pocillopora damicornis

2018 ◽  
Author(s):  
Niclas Heidelberg Lyndby ◽  
Jacob Boiesen Holm ◽  
Daniel Wangpraseurt ◽  
Renaud Grover ◽  
Cécile Rottier ◽  
...  
Keyword(s):  
Thermal Stress ◽  
High Temperature ◽  
Carbon Budget ◽  
Limiting Factor ◽  
Coral Host ◽  
Symbiotic Association ◽  
Pocillopora Damicornis ◽  
Fixed Carbon ◽  
Heterogeneous Distribution ◽  
Macro Scale

AbstractStudying carbon dynamics in the coral holobiont provides essential knowledge of nutritional strategies and is thus central to understanding coral ecophysiology. In this study, the first aim was to investigate the effect of daily feeding and thermal stress on oxygen (O2) rates measured at polyp-scale with microsensors and at whole fragment scale using incubation methods. The second aim was to assess the carbon budget of the symbiotic association using H13CO3, under the different conditions. Micro- and macro-scale measurements revealed enhanced O2 evolution rates for fed compared to unfed corals. However, gross O2 production in fed corals was increased at high temperature on a macroscale but not on a microscale basis, likely due to a heterogeneous distribution of photosynthesis over the coral surface. Starved corals always exhibited reduced photosynthetic activity at high temperature, which suggests that the nutritional status of the coral host is a key limiting factor for coral productivity under thermal stress. Quantification of photosynthate translocation and carbon budgets showed very low incorporation rates, for both symbionts and host (0.03 - 0.6 μg C cm-2 h-1) equivalent to only 0.008 - 0.6 %, of the photosynthetically fixed carbon for P. damicornis, in all treatments. Carbon loss (via respiration and/or mucus release) was about 41 - 47 % and 52 - 76% of the fixed carbon for starved and fed corals, respectively. Such high loss of translocated carbon suggests that P. damicornis is nitrogen and/or phosphorus limited. Heterotrophy might thus cover a larger portion of the nutritional demand for P. damicornis than previously assumed. Our results suggest that active feeding plays a fundamental role in metabolic dynamics and bleaching susceptibility of corals.

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