Population genetics of the coral<i>Acropora millepora</i>: Towards a genomic predictor of bleaching

Fuller, Zachary L.; Mocellin, Véronique J. L.; Morris, Luke A.; Cantin, Neal E.; Shepherd, Jihanne; Sarre, Luke; Peng, Julie; Liao, Yi; Pickrell, Joseph K.; Andolfatto, Peter; Matz, Mikhail V.; Bay, Line K.; Przeworski, Molly

doi:10.1101/867754

Cited by 39 publications

(44 citation statements)

References 72 publications

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“…The high completeness of our long-read assembly allowed us to resolve a substantially larger proportion of interspersed repeats (41.65%) compared with published acroporid assemblies from short reads ( A. digitifera 36 : (30.15%), A. millepora 37 (31.58%), A. tenuis 32 (34.32%). The only other available coral genome with comparable repeat resolution is a recently released long-read assembly for A. millepora 38 which identified a very similar proportion (40.69%) of interspersed repeats to our A. tenuis assembly. This increased ability to resolve repeats is reflected in a substantially increased proportion of unclassified elements in long-read assemblies (20.8% A. tenuis ; 21.2% A. millepora ) compared with short read assemblies (16.4% A. digitifera ; 16.5% A. millepora ), but the overall composition of known repeat classes was remarkably similar between Acropora genomes (Supp Figure S1).…”

Section: De-novo Assembly Of the Acropora Tenuis Genomementioning

confidence: 54%

“…As an additional check on the accuracy of our A. tenuis assembly we compared its high-level genomic organisation with that of its congeneric, A. millepora for which a chromosome-scale linkage map is available 38 . As expected given their small evolutionary distance (15Mya 32 ), macrosynteny analysis between the two Acropora genomes revealed a high degree of collinearity and limited rearrangements between linkage groups (an example is shown with arrows in Figure 1A).…”

Section: De-novo Assembly Of the Acropora Tenuis Genomementioning

confidence: 99%

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Signatures of selection in the coral holobiont reveal complex adaptations to inshore environments driven by Holocene climate change

Cooke

Ying

Fôret

et al. 2020

Preprint

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The inshore region of the Great Barrier Reef (GBR) became inundated at the start of the Holocene when sea levels rose. Like many inshore reefs worldwide it harbours extensive coral assemblages despite being subject to relatively high turbidity, freshwater input and thermal fluctuations. To investigate how the coral holobiont has adapted to these conditions we used shallow whole genome resequencing of 148 Acropora tenuis colonies from five inshore locations to model demographic history, identify signatures of selection and profile symbiont communities. We also assembled the genome of Acropora tenuis from long-read sequencing, providing one of the most contiguous and complete coral genomes to date. We show that corals from Magnetic Island are genetically distinct from reefs further north reflecting a Pleistocene (250-600Kya) split, whereas photosymbiont genotypes differed between reefs in a pattern more likely to reflect contemporary (Holocene) conditions. We also identified loci in the coral host genome with signatures of positive selection in the northern population and demonstrate using coalescent simulations that these are unlikely to be accounted for by demographic history. Associated with these we find genes with roles in a complex range of processes including heterotrophy, osmotic regulation, skeletal development and establishment and maintenance of symbiosis. Our results show that A. tenuis holobionts from the inshore GBR have been significantly shaped by their environment and provide an example of complex adaptations in response to past climate change.

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Section: De-novo Assembly Of the Acropora Tenuis Genomementioning

confidence: 54%

Section: De-novo Assembly Of the Acropora Tenuis Genomementioning

confidence: 99%

Signatures of selection in the coral holobiont reveal complex adaptations to inshore environments driven by Holocene climate change

Cooke

Ying

Fôret

et al. 2020

Preprint

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“…Reads were mapped to an annotated draft reference genome for Acorpora millepora that can currently available on the Przeworski laboratory website (Fuller et al 2018). The reference genome was generated using a combination of PacBio reads and Illumina paired-end reads with 10X Chromium barcodes and anchored into chromosomes with linkage mapping data from two previous studies (Wang et al 2009;Dixon et al 2015).…”

Section: Sequencing Data Processingmentioning

confidence: 99%

Meta-analysis of the General Coral Stress Response:Acroporacorals show opposing responses depending on stress intensity

Dixon

Abbott

Matz

2019

Preprint

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As climate change progresses, reef-building corals must contend more often with suboptimal conditions, motivating a need to understand coral stress response. Here we test the hypothesis that there is a stereotyped transcriptional response that corals enact under any stressful conditions, functionally characterized by downregulation of growth and activation of cell death, response to reactive oxygen species, immunity, and protein homeostasis. We analyze RNA-seq and Tag-Seq data from 14 previously published studies and supplement them with four new experiments involving different stressors, totaling over 600 gene expression profiles from the genus Acropora. Contrary to expectations, we found not one, but two distinct types of response. The type A response was observed under all kinds of highintensity stress, showed strong correlations between independent projects, and was functionally consistent with the hypothesized stereotyped response. Higher similarity of type A responses irrespective of stress type supports its role as the General Coral Stress Response providing a blanket solution to severely stressful conditions. The distinct type B response was observed under lower intensity stress and was weaker and more variable among studies than type A. Unexpectedly, the type B response was broadly opposite the type A response: biological processes up-regulated under type A response tended to be downregulated under type B response, and vice versa. Gene network analysis indicated that type B response does not involve specific co-regulated gene groups and is simply the opposite of type A response. We speculate that these paradoxically opposing responses may result from an inherent negative association between stress response and cell proliferation.

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“…Raw reads were trimmed and quality filtered using cutadapt simultaneously trimming low-quality bases from the 3' end (-q 20) and removing reads below 30 bp in length (-m 30) (Martin 2011). Trimmed reads were mapped to the A. millepora reference genome (Fuller et al 2019) with bowtie2 using the --local argument (Langmead and Salzberg 2012). Alignments were sorted and indexed using samtools (Li et al 2009), and PCR duplicates were removed using MarkDuplicates from Picard Toolkit (Broad Institute 2019).…”

Section: Mbd-seq Data Processingmentioning

confidence: 99%

Benchmarking DNA Methylation Assays for Marine Invertebrates

Dixon

Matz

2020

Preprint

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Interrogation of chromatin modifications, such as DNA methylation, has potential to improve forecasting and conservation of marine ecosystems. The standard method for assaying DNA methylation (Whole Genome Bisulfite Sequencing), however, is too costly to apply at the scales required for ecological research. Here we evaluate different methods for measuring DNA methylation for ecological epigenetics. We compare Whole Genome Bisulfite Sequencing (WGBS) with Methylated CpG Binding Domain Sequencing (MBD-seq), and a modified version of MethylRAD we term methylationdependent Restriction site-Associated DNA sequencing (mdRAD). We evaluate these three assays in measuring variation in methylation across the genome, between genotypes, and between polyp types in the reef-building coral Acropora millepora. We find that all three assays measure absolute methylation levels similarly, with tight correlations for methylation of gene bodies (gbM), as well as exons and 1Kb windows. Correlations for differential gbM between genotypes were weaker, but still concurrent across assays. We detected little to no reproducible differences in gbM between polyp types. We conclude that MBD-seq and mdRAD are reliable cost-effective alternatives to WGBS. Moreover, the considerably lower sequencing effort required for mdRAD to produce comparable methylation estimates makes it particularly useful for ecological epigenetics.

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Population genetics of the coralAcropora millepora: Towards a genomic predictor of bleaching

Cited by 39 publications

References 72 publications

Signatures of selection in the coral holobiont reveal complex adaptations to inshore environments driven by Holocene climate change

Signatures of selection in the coral holobiont reveal complex adaptations to inshore environments driven by Holocene climate change

Meta-analysis of the General Coral Stress Response:Acroporacorals show opposing responses depending on stress intensity

Benchmarking DNA Methylation Assays for Marine Invertebrates

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