Elevated CO2 delays the early development of scleractinian coral Acropora gemmifera.

The effects of elevated CO2 on the early life stages of coral were investigated by culturing the pelagic larvae and new recruits of Acropora gemmifera at three concentrations of CO2 (corresponding to pH = 8.1, 7.8 and 7.5, respectively). Acidified seawater resulted in fewer A. gemmifera larvae settling, and led to the production of smaller new recruits by slowing the development of the skeleton. The delayed development of new recruits due to elevated CO2 was consistent with the downregulation of calcification related genes. Several genes related to HCO3- and Ca2+ transporters were downregulated by elevated CO2, with solute carriers (SLC) (membrane transport proteins) possibly playing an important role. The downregulation of these membrane transport proteins might suppress the transport of calcium, bicarbonate and organic matter, resulting in the delayed development of A. gemmifera.

Introduction

Coral calcification is believed to be largely controlled by the degree of aragonite saturation (ΩA), and is significantly decreased by elevated atmospheric partial pressure CO2 (pCO2)[1-3] The early life stages of many marine organisms seem to be particularly vulnerable to acidified seawater. Consequently, there is an increasing concern about the potential impacts of increasing pCO2 on corals during their early life stages[4].

There are both pelagic and benthic phases in the coral life-cycle[5]. The planktonic larvae of stony corals are non-calcifying until they settle, with a previous study documenting their morphological changes[6] (Fig. 1). After coral larvae settle, new recruits develop a calcifying base, and form a synapticular ring and septa to establish the structure of the coral skeleton. The skeletal morphology changes rapidly during the early life stage, suggesting that the expression of calcification related genes also changes[7]. Coral growth and calcification are closely related to various protein transporters of Ca2+, H+ and HCO3− [8-11], as well as coral skeleton organic matrix proteins (SOMPs)[7,12,13]. There has been detailed information on the settlement and metamorphosis of early life stages of coral[14,15]. In addition, previous studies reported that high CO2 affected the early life stage of coral, by delaying calcification and settlement[16-20], modulating metabolism[21,22], changing skeleton morphology[19,23], and reducing survival and algal infection rates[24]. Also, some studies showed that elevated CO2 exhibited no significant effects on coral survival and corallite area[14,25].

Figure 1

Embryonic development and larval development of coral A. gemmifera (From zoom stereo microscope). (A) 2 cleavage (2 hr), (B) larvae (prawn chip, 6 hr), (C) rodlike planula (47 hr), (D) settled new recruits (5 d).

Gene expression has been analysed to understand the post-settlement success and skeleton formation of coral during the entire period of early development[26,27]. Moya, et al.[28] used the Illumina RNAseq approach to study how acute exposure to elevated CO2 affected the gene expression of the early life of Acropora millepora. The authors reported that the expression of most ion transport proteins was not affected by elevated CO2, while many membrane-associated or carbonic anhydrases were downregulated. Although corals lacked a strong response to elevated pCO2 in the study of Rocker, et al.[29], new recruits might have the capacity to acclimate rapidly to elevated pCO2 by upregulating specific heat shock proteins (HSPs) and a suite of anti-apoptotic proteins (e.g. Bcl-2 family members)[30]. Kaniewska, et al.[31] also demonstrated the upregulation of membrane transporters under high CO2 concentrations, as well as the regulation of genes involved in the cytoskeletal interactions and cytoskeletal remodelling of membranes. The expression of heat shock proteins, carbonic anhydrase, and rubisco protein has also been studied in coral larvae[32-34], supporting the assumption that elevated temperature and CO2 are impacting coral development.

Previous studies primarily used A. millepora as a model species in the analysis of gene expression. However, studies of other species might provide a more complete understanding of how coral communities respond to high CO2 concentrations. The rapidly growing branching coral, A. gemmifera, is widely distributed, and is an ecologically important genus in the South China Sea. In the current study, the pelagic larvae and new recruits of A. gemmifera were exposed to three pCO2 concentrations to investigate the transcriptome of the coral during the early life stages, with a focus on the adhesion and structural proteins involved in calcification. In previous studies, sequencing reads were usually mapped onto a transcriptome assembly of an A. millepora. The present study conducts a transcriptome analysis using de novo RNA-seq and gene expression analysis to gain deep insight into the responses of calcification related genes to climate changes.

Results

Settlement, survivorship, and morphological change

The settling proportion was lower in low pH treatments (p < 0.05), whereas survivorship exhibited no significant difference between the treatments (p > 0.05) (Fig. 2). Tank effects were not significant (p > 0.05). The first synapticular ring and primary septa in new coral recruits were detected after approximately 3 days after settlement. Three synapticular rings with secondary septa and theca were observed after 5 days (Fig. 3A–C). For treatments in which pH was 7.8 and 7.5, the ratios of new recruits with three synapticular rings were always lower than those in the control (Fig. 3D). All settled new recruits had more than three synapticular rings after 17 days at pH 8.1, with skeletal development being visibly suppressed at lower pH (Fig. 3D).

Figure 2

(A) The larval settlement ratios; and (B) survivorship of new recruits after 3-day and 10-day settlement at different pH values. *Denotes significant difference (p < 0.05), compared to the control (pH = 8.1).

Figure 3

Progressive morphological changes in A. gemmifera: (A) first day settlement; (B) formation of first synapticular ring and primary septa on the 2–7th days; (C) three synapticular rings with secondary septa and theca after 5 days; (D) the ratios of new recruits showing three synapticular rings; and (E) average diameter measurement of A. gemmifera (n = 3) at pH = 8.1, 7.8 and 7.5 respectively).

From 5 days after settlement, the diameter of the new recruits remained significantly smaller in the treatment with lower pH than the control (p < 0.05) (Fig. 3E). In addition, crystals were granule-like at pH 8.1, whereas crystals became increasingly distorted and needle-like in treatments with lower pH (Fig. 4A–F).

Figure 4

The skeletal structure on the 40th day after settlement (A) and (B) at pH = 8.1; (C) and (D) at pH = 7.8; and (E) and (F) pH = 7.5 by scanning electron microscopy imaging. In (A), (C) and (E) scale bar represents 10 µm, in (B), (D) and (F) scale represents 1 µm.

Differentially expressed genes

A total of 12,367,906 reads were obtained from the A. gemmifera new coral recruits, with ~60% of reads being mapped to the total de novo unigene assembly (Table S1). As new recruits developed, only ~6% of transcripts were differentially expressed between C1 (3 days after settlement) and C2 (40 days after settlement) (Fig. 5). In addition, ~3% transcripts were differentially expressed in both acute (3 days) and prolonged treatments (40 days) with elevated CO2 (Fig. 5).

Figure 5

The percentage of differentially expressed genes. (A) Control after 40 days vs 3 days (C2 vs C1), (B) high CO2 treatment after 3 days vs control after 3 days (H1 vs C1), (C) high CO2 treatment after 40 days vs control after 40 days (H2 vs C2).

Significant mortality of new recruits was observed in the treatments with elevated CO2 (Fig. 2B). Some apoptosis related genes were downregulated (Table 1) in response to elevated CO2, including apoptosis regulator BCL-2, caspase-3 and caspase-8. Some of these apoptosis-related genes are responsible for the negative regulation of apoptotic processes, while others might positively regulate apoptotic processes (Table 1).

Table 1

Differential expressions of apoptosis-related genes between the control in 40 days vs. control in 3 days after settlement (C2 vs. C1), the acidified treatment in 3 days vs. control in 3 days after settlement (H1 vs. C1), and acidified treatment in 40 days vs. control in 40 days after settlement (H2 vs. C2). All data were filtered with p < 0.0001 and FDR <0.0001.

Accession	Definition	Nr-Evalue	C2 vs C1	H1 vs C1	H2 vs C2
XM_015899700.1	apoptosis regulator BCL-2; negative regulation of apoptotic process	0	−2.18	−2.64	−5.83
XM_015900639.1	BCL2-associated athanogene 3; negative regulation of apoptotic process	2.00E-127	1.57	—	−2.51
XM_015919947.1	caspase-3-like; apoptotic signaling pathway	1.00E-72	—	−1.32	—
XM_015905634.1	caspase 8; positive regulation of apoptotic process	0	−1.38	−3.42	−2.51

A series of genes related to the HCO3− and Ca2+ transporters were downregulated in response to elevated CO2 (Table 2). Solute carriers (SLC) are membrane transport proteins located in the cell membrane that transport charged and uncharged inorganic and organic molecules. Solute carrier (SLC) genes were mostly upregulated after 40 days compared to 3 days (C2 vs C1), and were mostly downregulated in response to elevated CO2 after 40 days of settlement compared to 3 days of settlement (H1 vs C1 or H2 vs C2). SLC4 member 10 is responsible for transporting HCO3− (Table 2), while SLC8 and SCL24 are Ca2+ transporters. The plasma membrane Ca2+ transporting ATPase was also downregulated in response to elevated CO2 (Table 2). Many other members of various SLC families were also downregulated by the high CO2 treatment. For example, SLC12 and SLC25 were downregulated after 40 days under high CO2 (Table 2). Similarly, some skeleton organic matrix genes were downregulated by the high CO2 treatments, including cadherin, thrombospondin, hemicentin, actin, collagen, and galaxin after 3 days of settlement (Table 3).

Table 2

Differential expressions of ion transporter-related genes between the control in 40 days vs. control in 3 days after settlement (C2 vs. C1), the acidified treatment in 3 days vs. control in 3 days after settlement (H1 vs. C1), and acidified treatment in 40 days vs. control in 40 days after settlement (H2 vs. C2). All data were filtered with p < 0.0001 and FDR <0.0001.

KEGG entry	Definition	KEGG-Evalue	C2 vs C1	H1 vs C1	H2 vs C2
tad:TRIADDRAFT_54168	SLC4 (anion exchanger), member 2	1.00E-39	1.99	—	—
spu:587119	SLC4 (anion exchanger), member 3;	0	3.33	—	—
cfa:478766	SLC4 (sodium bicarbonate transporter), member 10	0	—	−1.93	−1.61
nve:NEMVE_v1g127372	SLC9 (sodium/hydrogen exchanger), member 3	2.00E-101	1.17	−1.78	—
nve:NEMVE_v1g166011	Ca2+ transporting ATPase, plasma membrane	0	1.79	−1.00	−1.04
nve:NEMVE_v1g239709	SLC8 (sodium/calcium exchanger)	2.00E-113	—	−1.61	−1.44
mdo:100023316	SLC24 (sodium/potassium/calcium exchanger), member 1	5.00E-81	−3.87	—	—
nve:NEMVE_v1g206699	SLC24 (sodium/potassium/calcium exchanger), member 2	8.00E-52	—	−3.42	−3.51
dre:100334346	SLC24 (sodium/potassium/calcium exchanger), member 4	2.00E-111	—	−1.34	—
nve:NEMVE_v1g80232	SLC26 (sodium-independent sulfate anion transporter), member 11	2.00E-115	2.12	—	—

Table 3

Differential expressions of skeletal organic matrix-related genes between the control in 40 days vs.

KEGG entry	KEGG Orthology	Definition	C2 vs C1	H1 vs C1	H2 vs C2
dre:407978	K06813	cadherin 23	1.11	1.30	—
ptr:457086	K04601	cadherin EGF LAG seven-pass G-type receptor 2 (flamingo)	−2.08	−1.95	—
tad:TRIADDRAFT_62266	K04600	cadherin EGF LAG seven-pass G-type receptor 1 (flamingo)	—	−1.51	—
dre:368436	K04600	cadherin EGF LAG seven-pass G-type receptor 1 (flamingo)	—	−1.42	−1.63
cin:100169670	K04659	thrombospondin	—	—	−1.63
bfo:BRAFLDRAFT_56687	K05692	actin beta/gamma 1	—	−1.07	—
cfa:475371	K13956	actin-binding protein IPP	−1.64	—	—
acs:100556853	K06236	collagen, type I/II/III/V/XI, alpha	−9.25	−1.06	−1.05
aml:100478752	K06237	collagen, type IV, alpha	—	−3.90	−1.05
acs:100558915	K06238	collagen, type VI, alpha	−1.38	—	1.95
xtr:100495209	K08132	collagen, type XII, alpha	—	−1.29	—
acs:100562332	K06823	collagen, type XVIII, alpha	−1.84	—	—

control in 3 days after settlement (C2 vs. C1), the acidified treatment in 3 days vs. control in 3 days after settlement (H1 vs. C1), and acidified treatment in 40 days vs. control in 40 days after settlement (H2 vs. C2). All data were filtered with p < 0.0001 and FDR < 0.0001.

Discussion

Survivorship and regulators of apoptosis

The survivorship of new recruits decreased after 40 days of exposure to high CO2 concentrations, but not significantly (Fig. 2B). As previous studies showed that the growth rates and colony size of hermatypic corals are inversely proportional to mortality risk[35,36], the slow development of skeleton synapticular rings under elevated CO2 may potentially increase the risk of morality. In addition, suppressed growth under elevated CO2 is unfavourable for new recruits that compete for space with algae and other benthic organisms, because it reduces the fitness of new recruits, affecting population dynamics[37].

Previous studies showed that the expression of apoptotic genes is generally related to cellular mortality and survivorship, with the expression being either pro- or anti-apoptosis[30]. Caspase 8 is essential for programmed cell death, and was downregulated in the high CO2 treatments of the current study. In addition, anti-apoptotic proteins (e.g. Bcl-2 family members) were also downregulated (Table 1), whereas heat shock proteins (HSPs) and heat shock factors (HSFs) were not differentially expressed (data not shown). A previous study showed that new recruits of A. millepora could acclimate to elevated pCO2 by upregulating the expression of HSPs, as well as Bcl-2 family members[30]; however, the current study indicated that this mechanism does not exist in A. gemmifera. Thus, different coral species might trigger different molecular mechanisms in responses to elevated pCO2.

Delayed development and calcification related genes

In this study, the settlement, diameter, skeleton structure, and crystal shape of new recruits were affected by elevated CO2 concentrations. These results were consistent with previous studies where new recruits reared in OA had smaller diameters than did the control[38-40]. The current study showed that, in addition to diameter, the ratio of new recruits with three synapticular rings was lower before 28 days under higher CO2 concentrations. To our knowledge, only a few studies demonstrate the effects of elevated CO2 on the development of skeleton synapticular rings[23]. The slow development of the coral skeleton prompted us to conduct a more extensive survey of the major genes related to calcification, and to investigate their expression levels. Two major components contribute to the calcification process: (1) transporters of Ca2+, H+ and inorganic carbon, and (2) organic matrix proteins that catalyse the crystals to form macroscopic structures[41].

Various transporters of Ca2+, H+ and inorganic carbon have been examined by previous studies[9-11]. Among these transporters, Ca2+ transporting ATPase was presumably a transporter of Ca2+ and H+ [9]. In our study, Ca2+ transporting ATPase was only differentially expressed during the first 3 days under high CO2 concentrations, but was downregulated after 40 days of exposure. Carbonic anhydrases contribute to the interconversion of carbon dioxide and bicarbonate[11], which were also not differentially expressed under high CO2 in this study.

In addition, solute carriers (SLC) are membrane transport proteins located in the cell membrane that transport charged and uncharged inorganic and organic molecules. Zoccola, et al.[42] reported that the SLC4 and SLC26 families are both bicarbonate anion transporters in the coral Stylophora pistillata. SLC4 (anion exchanger) member 2 was neither differentially expressed in response to elevated CO2 in A. millepora[28] nor A. gemmifera (this study); however, SLC4 member 10 (bicarbonate anion transporter) was downregulated in under high CO2 concentrations in the current study (Table 2). This result suggests that the bicarbonate transports were suppressed by elevated CO2, with SLC4 member 10 either supplying bicarbonate anion at the site of calcification or aiding in pH regulation[42]. A previous study showed that SLC26 was differentially expressed by different temperatures[43]; however, SLC26 member 11 was not differentially expressed by high CO2 in our study (Table 2). Hence, elevated CO2 might reduce bicarbonate anion transport by suppressing the expression of SLC4 member 10 rather than SLC26. In addition to bicarbonate anion transport, the calcium transporters (SLC8 and SLC24) were also downregulated by elevated CO2, including SLC 24 members 2 and 4 (Table 2). The members of the SLC24 gene family encode K+-dependent Na+/Ca2+ exchangers (NCKX) that utilise both inward Na+ and outward K+ gradients to extrude Ca2+ from cells[44]. However, it remains unclear whether SLC24 is located on the membrane of tissue cells or the calicoblastic cells. Consequently, it is also unclear whether SLC24 is able to regulate coral calcification. Both HCO3− and Ca2+ transporters were downregulated under elevated CO2 concentrations, which probably led to slower calcification rates and the delayed development of new recruits. In addition to HCO3− and Ca2+, the transporters of organic matter (such as oligopeptides, monocarboxylic acid, fatty acids, and amino acids) were also downregulated (Table S2). The presence of fewer organic matter transporters might decrease the energy supply available for the calcification and growth of coral.

It has been long hypothesized that the precipitation of aragonite is catalysed by and organized on an extracellular organic matrix. A recent study identified 36 coral of coral skeleton organic matrix proteins (SOMPs) in S. pistillata[12]. In our study, only five out of these 36 skeletal proteins were differentially expressed, including cadherin, thrombospondin, hemicentin, actin, and collagen (Table 3). However, these proteins were usually downregulated in H1 vs. C1, but not in H2 vs C2. The specific functions of some organic matrix proteins have yet to be determined in coral species, but their functions have been studied in human and other animals. Cadherin plays an important role in cell adhesion, forming junctions to bind cells together within tissues[45]. Collagens are also important in the regulation of cell-cell adhesion, differentiation, and wound healing[46]. Coral acid-rich protein (CARPs) members have been reported as putative calcification-related proteins in A. millepora[13] and S. pistillata[12,47], but were not differentially expressed in response to elevated CO2 in our study (data not shown).

Conclusions

The present study explored the effects of elevated pCO2 on the post-settlement development of new coral recruits of A. gemmifera. Elevated CO2 slowed the formation of the skeleton structure and crystal microstructure of new recruits, slowing settlement and reducing the diameter of new recruits. Many solute carriers (SLC) (membrane transport proteins) were downregulated in response to elevated CO2, as well as the SLC4 family members responsible for supplying HCO3− to the site of calcification. The downregulation of membrane transporters proteins might represent the mechanism underlying the delayed development of new coral recruits.

Materials and Methods

Sampling and incubation

In April 2015, 5 colonies of A. gemmifera (~40 cm diameter) were collected from Luhuitou fringing reef, Sanya Bay, China (18° 15′ N; 109° 25′ E) at ~2–5 m depth. Before spawning, colonies were transferred to outdoor flow-through aquaria in Sanya Bay, Hainan Island, outside the Tropical Marine Biological Research Laboratory. Ten colonies of A. gemmifera (~40 cm diameter) were collected. These colonies were >5 m away from each other, assuming their genotypes were not the same. Gametes were collected from these 10 colonies without separate crossings.

In our CO2 system, seawater chemistry was manipulated by continuous and direct bubbling of pure CO2 (except for the control treatment). The bubbling rates were controlled by high precision pressure gauges and valves (DC01-01, Dici, China) and pH controller (pH2010, WEIPRO, China) to create the desired pCO2 (Table 4). Seawater was pumped from the reef water (~200 m away from our culture tank) at a depth of 5 m and run through a sand- filter. As the seawater was not further filtered, no extra food and zooxanthellae were added into culture aquaria to create. Each aquarium was covered with a screen to provide a light field that was approximately 50% of the surface solar irradiance, a condition similar to that at a depth of 3–5 m. Treated seawater was then pumped to the 90 L experimental tanks (three replicate tanks per treatment) via PVC-pipes. The water-exchange rate was 600 ± 10 mL min−1 (Fig. S1). The tanks were partially immersed in a 2000 L flow-through aquarium.

Table 4

Values of pH, temperature (T), salinity, total alkalinity (TA), dissolved inorganic carbon (DIC), pCO2 and aragonite saturation state (ΩA) during incubations. All values are means ± SD.

pH	T (°C)	Salinity	TA (μmol L−1)	DIC (μmol L−1)	pCO2 (μatm)	ΩA
8.1 ± 0.14	27 ± 2	34 ± 0.02	2219 ± 26	1902 ± 32	389 ± 24	3.4 ± 0.06
7.8 ± 0.16	27 ± 2	34 ± 0.02	2225 ± 45	2021 ± 87	700 ± 75	2.4 ± 0.08
7.5 ± 0.18	27 ± 2	34 ± 0.02	2224 ± 31	2110 ± 96	1214 ± 102	1.6 ± 0.10

Larvae were cultivated in flow-through tanks (90 L) at a density of ~1 larvae/ml under ambient conditions (pH NBS 8.16 ± 0.01, 27.5 °C, total alkalinity (TA) 2250.8 ± 5 μM, salinity 33 psu), ~750 ppm CO2 (pH = 7.8) or 1200 ppm CO2 (pH = 7.5) (Table 4), reflecting the control condition, intermediate and high CO2 concentrations based on IPCC predictions for the 21st century (2007). There were four replicates in each treatment, and the turnover time of seawater of each tank was 12 hours. The outflow of each tank was covered with a 180 μm mesh to avoid larvae loss. About 10–15 preconditioned terrocota tiles with a mixed community of crustose coralline algae were placed into each tank to induce larval settlement. After four days, larvae were randomly sampled for settlement assays. Six days later, all swimming larvae were flushed away, and new recruits on tiles were reared in continuous flow-through tanks for observing survivorship, diameter, and skeleton structure (90 L) (Fig. S1). The survivorship of new recruits on tiles was assessed on the 3rd and 10th days after settlement, by observing it using a stereomicroscope (Olympus, SZ51). Death was defined as the time point when live tissue was no longer present. Survivorship was expressed as the proportion surviving within each tank. The number of new recruits was counted, and image of new recruits was taken using a stereomicroscope. The diameter of live tissue was measured with the program ToupView 3.7. The settled recruits were collected at the end of 40-day incubation, and their skeletons was examined by scanning electron microscopy (SEM, ZEISS Supra55).

Settling proportion

The settling proportion was estimated in a separate experiment. In this separate experiment, about 300 larvae were sampled from each treatment tank and transferred to lidded chambers (10 L) filled with seawater with the corresponding experimental treatments. A preconditioned terrocota tile with a mixed community of crustose coralline algae was placed at the bottom of the chambers. Half of the seawater in each chamber was replaced every 12 hours. Larval settlement was assessed after two days using a stereomicroscope (Olympus, SZ51). Settling proportion was estimated by the number of new recruits/total initial larvae.

TA and pH

Water samples were collected every three days from each tank, and total alkalinity (TA) was measured by an open-cell automatic titrator (Metrohm 877 titrino plus) using 0.1 M HCl for each 70 g seawater sample. Accuracy of the measurements was checked against certified seawater reference material (Batch 118) obtained from Dr A. Dickson. The pH in culture tanks was continuously monitored using a Ross semi-micro glass combination pH electrode (Orion). The other carbonate system parameters (i.e. dissolved inorganic carbon (DIC), Ω and pCO2) were calculated using a spreadsheet version of the CO2SYS program[48], based on measurements of temperature, salinity, pH and alkalinity. The calculation used the CO2 equilibrium constants K1 and K2[49].

De novo transcriptome sequencing

On the 3rd and 40th day after settlement, settled new recruits (~10–50 new recruits per biological sample) of each tank were randomly sampled from ~10–15 tiles with a sterile scalpel, and 1 sample per experimental treatment tank were obtained. The samples of control and high CO2 treatments (1200 μatm CO2) were snap frozen the samples in liquid nitrogen and then stored the samples at −80 °C until further processing. TRI-Reagent (Sigma) was used for RNA extraction according to the manufacturer’s manual. Samples were stored at −80 °C, until transcriptome sequencing was carried out for de novo assembly and analysis by the Huada Gene Company (http://www.genomics.cn/index).

After the mRNAs were fragmented into short fragments as templates, double-stranded cDNA was synthesized. The ligated fragments were then generated by a series of reaction processes that included purification of PCR products, end repair, and ligation of Illumina adapters. AMPure XP system was used for the purification PCR products, and the Agilent Bioanalyzer 2100 system was used to assess the library quality. An Illumina HiSeq™ 2000 sequencing platform was employed to sequence the cDNA library (NEB, USA).

Data filtering, de novo assembly and annotation

We filtered the raw data to generate clean reads by removing adapter sequences, reads with unknown bases (N) >10%, and low-quality sequences (the percentage of low quality bases of quality value <5). After obtaining clean reads, the clean reads were de novo assembled by the Trinity program into contigs[50]. The read coverage in each sample roughly exhibited a similar distribution. All unigenes were annotated using the BLASTx against the NCBI Nr (http://www.ncbi.nlm.nih.gov/genbank/), and KEGG pathway (http://www.genome.jp/kegg/pathway.html) databases, with an E-value cut-off of 1E-5. To further analyze the annotation results, the GO function of unigenes were classified in terms of molecular function, biological process, as well as cellular component (http://www.geneontology.org/) using Blast2GO[51].

Differential expression analysis

Clean reads of each treatment were mapped to reference genes transcriptome generated by total de novo RNA-seq[52,53]. The gene expression level was calculated by the value of FPKM (Fragments Per Kilobase of transcript per Million). The differentially expressed genes were annotated using GO and KEGG enrichment analyses according to a method similar to that described by[52,53]. The best BLAST hit was used to assess differential gene expression, which was estimated with log2fold change. The triplicate samples were compared between control 3 days after settlement (C1), control 40 days after settlement (C2), acidified treatment 3 days after settlement (H1), and acidified treatment 40 days after settlement (H2).

Statistical analyses

Two-way analyses of variance (ANOVA) tested the effects of pCO2 and different tanks on coral biological parameters (e.g. settling proportion, survivorship, diameter, and gene expression). Different treatments of pCO2 and different tanks were fixed, whereas each coral biological parameter was a random factor. Post hoc Tukey tests were conducted if significant effects were obtained (p < 0.05). Statistical analyses were performed using SPSS 19 System for Windows. The differential gene expression analysis of the two experimental groups (high CO2 treatment vs control) was determined using Expdiff. A q value (or FDR) of <0.005 & |log2fold change|>1 was set as the threshold for significantly different expressions.

Availability of raw data

The raw data used for assembly, annotated expression data and annotated data were deposited in the National Center for Biotechnology Information (NCBI) Gene Expression Omnibus (GEO) under accession number GSE96935.