The roles of age, parentage and environment on bacterial and algal endosymbiont communities in <i>Acropora</i> corals

Chan, Wing Yan; Peplow, Lesa M.; Menéndez, Patricia; Hoffmann, Ary A.; Oppen, Madeleine J. H. van

doi:10.1111/mec.15187

Cited by 23 publications

(30 citation statements)

References 90 publications

Supporting

Mentioning

Contrasting

Order By: Relevance

“…The bacterial and microalgal endosymbiont (Symbiodiniaceae spp.) communities associated with these corals did not differ between the reciprocal hybrids and their maternal and paternal purebreds (Chan et al, 2019). Since these microorganisms carry vital functions to the coral hosts and can contribute to holobiont fitness differences (Blackall et al, 2015;Rosenberg et al, 2007), this finding suggests that the microbial communities were unlikely responsible for the observed holobiont fitness differences, and that these are probably underpinned by coral host genetic and/or nongenetic transgenerational factors.…”

mentioning

confidence: 86%

“…Chan et al 2018Size (7 months) Offspring groups were not different in size under both ambient and elevated conditions Elevated temperature and pCO 2 conditions resulted in smaller size of all purebred and hybrid offspring groups Chan et al (2018) Size (1 year) Hybrid LT and its maternal purebred LL grew bigger (290-366 mm 2 ) than hybrid TL (47 mm 2 ). Purebred TT had no survivors Chan et al (2018) Bacterial community (7 months) Offspring groups were not associated with different bacterial communities as determined with 16S rRNA gene metabarcoding Chan et al (2019) Microalgal symbiont community (7 months) Offspring groups were not associated with different microalgal symbiont communities as determined with ITS2 metabarcoding Chan et al (2019) Interestingly, maternal effects were weaker in the hybrid cross of the other direction, with 334 and 661 DEGs observed when compared to its maternal and paternal population respectively (Videvall et al, 2016). Only one previous study has examined maternal effects in coral hybrid gene expression and only coral larvae were studied.…”

Section: Key Conclusion Referencementioning

confidence: 99%

See 1 more Smart Citation

Maternal effects in gene expression of interspecific coral hybrids

et al. 2020

Self Cite

View full text Add to dashboard Cite

Maternal effects can have a large impact on the fitness of offspring. In plants, maternal effects in seed traits (e.g., seed mass, germination time) and offspring fitness (e.g., growth rates) have been well documented (Donohue, 2009). Maternal age at reproduction is known to affect diapause (i.e., suspended development induced by unfavorable environmental conditions) in offspring of insects (Mousseau & Dingle, 1991), and in amphibians, maternal factors have well known effects in size and rates of development (Warne et al., 2013). Maternal effects can be the result of the direct effects of the environment on epigenetic marks, genomic imprinting, or maternal provisioning (which is influenced by both environmental and genetic effects). For example, the environment experienced by the mother can affect the expression of genes involved in germination of Arabidopsis thaliana offspring (for review, see Donohue, 2009). Genomic imprinting is the epigenetic silencing (e.g., via cytosine methylation or chromatin-mediated processes) of one of the parental chromosomes, leaving only expression from the non-silenced chromosome (Alleman & Doctor, 2000). In the case of maternal effects, only the maternal chromosomes are expressed and this can be transmitted to one or more subsequent generations (Bischoff & Müller-Schärer, 2010). Genomic imprinting has been observed in a few insect species, plants and placental mammals (for review, see Matsuura, 2020; Thamban et al., 2020), but not in egg-laying vertebrates such as birds, monotremes and reptiles by far (

show abstract

mentioning

confidence: 86%

Section: Key Conclusion Referencementioning

confidence: 99%

Maternal effects in gene expression of interspecific coral hybrids

et al. 2020

Self Cite

View full text Add to dashboard Cite

show abstract

“…In addition to the coral host, the host-associated microbiome can also have an impact on host gene expression (Barfield et al, 2018;Helmkampf et al, 2019). In our study, however, the bacterial and microalgal endosymbiont communities of the corals were similar at the time of sampling (Chan et al, 2019). The consistency between host gene expression and phenotypic results thus suggests that maternal host-related factors were likely the drivers behind the observed fitness differences.…”

Section: Discussionmentioning

confidence: 47%

“…The bacterial and microalgal endosymbiont (Symbiodiniaceae spp.) communities associated with these corals did not differ between the reciprocal hybrids and their maternal and paternal purebreds (Chan et al, 2019). Since these microorganisms carry vital functions to the coral hosts and can contribute to holobiont fitness differences (Blackall et al, 2015;Rosenberg et al, 2007), this finding suggests that the microbial communities were unlikely responsible for the observed holobiont fitness differences, and that these are likely underpinned by coral host genetic and/or non-genetic transgenerational factors .…”

Section: Introductionmentioning

confidence: 86%

“…However, exposure to elevated temperature and p CO 2 conditions did not result in differential coral gene expression. Although the composition of bacterial and microalgal endosymbiont communities of these corals was similar under ambient and elevated conditions and between hybrids and purebreds (Chan et al, 2019), these microbes may have expressed different genes and contributed to holobiont phenotypic differences. Other less studied members of the coral holobiont, such as viruses and fungi (that were not examined), may also have contributed to coral survival and size differences.…”

Section: Conclusion and Future Studiesmentioning

confidence: 96%

See 1 more Smart Citation

Maternal effects in gene expression of interspecific coral hybrids

et al.

Self Cite

View full text Add to dashboard Cite

Maternal effects have been well documented for offspring morphology and life history traits in plants and terrestrial animals, yet little is known about maternal effects in corals. Further, few studies have explored maternal effects in gene expression. In a previous study, F1 interspecific hybrid and purebred larvae of the coral species Acropora tenuis and A. loripes were settled and exposed to ambient or elevated temperature and pCO 2 conditions for seven months. At this stage, the hybrid coral recruits from both ocean conditions exhibited strong maternal effects in several fitness traits. We conducted RNA-sequencing on samples from the same experiment and showed that gene expression of the hybrid Acropora also showed clear maternal effects. Only 40 genes were differentially expressed between hybrids and their maternal progenitor. In contrast,˜2000 differentially expressed genes were observed between hybrids and their paternal progenitors, and between the reciprocal F1 hybrids. These results indicate that maternal effects in coral gene expression can be long-lasting. Unlike findings from most short-term stress experiments in corals, no genes were differentially expressed in the hybrid nor purebred offspring after seven months of exposure to elevated temperature and pCO 2 conditions.

show abstract

Genetic structure of dinoflagellate symbionts in coral recruits differs from that of parental or local adults

Coffroth

Leigh

McIlroy

et al. 2022

Ecology and Evolution

View full text Add to dashboard Cite

The symbiotic relationship between dinoflagellate algae in the family Symbiodiniaceae and scleractinian corals forms the base of the tropical reef ecosystem. In scleractinian corals, recruits acquire symbionts either “vertically” from the maternal colony or initially lack symbionts and acquire them “horizontally” from the environment. Regardless of the mode of acquisition, coral species and individual colonies harbor only a subset of the highly diverse complex of species/taxa within the Symbiodiniaceae. This suggests a genetic basis for specificity, but local environmental conditions and/or symbiont availability may also play a role in determining which symbionts within the Symbiodiniaceae are initially taken up by the host. To address the relative importance of genetic and environmental drivers of symbiont uptake/establishment, we examined the acquisition of these dinoflagellate symbionts in one to three‐month‐old recruits of Orbicella faveolata to compare symbiont types present in recruits to those of parental populations versus co‐occurring adults in their destination reef. Variation in chloroplast 23S ribosomal DNA and in three polymorphic microsatellite loci was examined. We found that, in general, symbiont communities within adult colonies differed between reefs, suggesting that endemism is common among symbiont populations of O. faveolata on a local scale. Among recruits, initial symbiont acquisition was selective. O. faveolata recruits only acquired a subset of locally available symbionts, and these generally did not reflect symbiont populations in adults at either the parental or the outplant reef. Instead, symbiont communities within new recruits at a given outplant site and region tended to be similar to each other, regardless of parental source population. These results suggest temporal variation in the local symbiont source pool, although other possible drivers behind the distinct difference between symbionts within O. faveolata adults and new generations of recruits may include different ontogenetic requirements and/or reduced host selectivity in early ontogeny.

show abstract

The roles of age, parentage and environment on bacterial and algal endosymbiont communities in Acropora corals

Cited by 23 publications

References 90 publications

Maternal effects in gene expression of interspecific coral hybrids

Maternal effects in gene expression of interspecific coral hybrids

Maternal effects in gene expression of interspecific coral hybrids

Genetic structure of dinoflagellate symbionts in coral recruits differs from that of parental or local adults

Contact Info

Product

Resources

About