Introduction

Corals are host to a diverse consortium of microbial partners, some of which are essential to the health and function of the coral holobiont (reviewed in [1]). Initial establishment of these microbial communities in each new generation of coral can occur through horizontal [2, 3] or vertical [4, 5] transmission, or a combination of both (i.e., “mixed mode transmission”, [6]). In corals, the transmission of microalgal endosymbionts in the family Symbiodiniaceae is often correlated with reproductive mode, where brooders exhibit vertical or mixed mode transmission and broadcast spawners exhibit horizontal transmission [7]. However, this pattern is not well defined for bacteria, as previous studies on bacterial transmission have found variability within coral reproductive modes. For instance, horizontal transmission of bacteria occurs in a number of broadcast spawning corals including Pocillopora meandrina [3] and Montastrea, Acropora and Diploria species [8], whereas other broadcast spawners, such as Mussimilia hispida [5] and Acropora gemmifera [9], and the brooding coral Porites astreoides [10] have been suggested to vertically transfer some key bacterial taxa from parents to gametes prior to spawning.

Laboratory or ex situ studies on microbial transmission mode may not reveal the complete picture due to the artificial composition of the environmental microbial community. To remove this bias, we investigated the drivers of Symbiodiniaceae and bacterial establishment in the coral Pocillopora damicornis, a cosmopolitan branching species, in the field. We conducted an in situ reciprocal transplant experiment between two adjacent reef habitat types, the reef flat and slope, where both brooding parental whole coral colonies and newly settled recruits were cross-transplanted to both habitats (for detailed methods, see Supplementary Information SI.1). From each habitat, ten adult P. damicornis (i.e., parental environment) were placed individually into settlement boxes (acrylic boxes fit with 300 μm plankton mesh on two sides and the base covered in nine 11 × 11 cm settlement tiles) and reciprocally transplanted prior to planulation. Once planulae settled and metamorphosed on the settlement tiles (i.e., planulation environment), these were again reciprocally transplanted between habitats (i.e., transplant environment) and recruits were sampled after 1 week. Recruits were defined by their parental, planulation and transplant environments, referred to as experimental groups. Symbiodiniaceae and bacterial community composition were determined by Illumina sequencing of ITS2 rDNA and 16S rRNA gene amplicons (see Supplementary Information SI.2).

Results and Discussion

The establishment of bacterial communities in P. damicornis offspring was driven by both parental and planulation environments, with the majority of uptake occurring horizontally through chance encounter in the environment. Bacterial communities of recruits differed significantly from both parents and water samples from the reef flat and slope, and also displayed much greater dispersion than the parents or water samples (Fig. 1a; Fig. S1; see Supplementary Information SI.3). Recruits significantly varied according to the parental (PERMANOVA: df = 1, F = 3.848, p = 0.001) and planulation environments (PERMANOVA: df = 1, F = 4.1384, p = 0.001), but not by transplant environment (Fig. 1b–d), suggesting parental and very early life stage environments (e.g., prior to or immediately following settlement) shape the bacterial communities of young recruits. Further, each cohort of recruits and respective parent shared a small number of bacterial amplicon sequence variants (ASVs) in several genera including Endozoicomonas, Vibrio, Alteromonas and Ruegeria (Table S1). Only one ASV of Burkholderia-Paraburkholderia was shared among all parents and all recruits. While its consistent presence among all coral samples could represent potential evidence for vertical transmission, this ASV may also be acquired after planulation from the seawater; fluorescent in situ hybridisation is required for verification. Vertical transmission of Burkholderia has previously been suggested for the spawning coral, Mussimillia hispida [5]. As a possible nitrogen fixer [11, 12], it could provide otherwise limited nitrogen to the Symbiodiniaceae and assist in the survival and protection of early recruits [13, 14].

Fig. 1
figure 1

Non-parametric multi-dimensional scaling (nMDS) visualisation of bacterial beta-diversity of a all samples grouped by sample type; parent, recruit or water, b recruit samples grouped by parental environment, c recruit samples grouped by planulation environment and d recruit samples grouped by transplant environment. p-values represent results from PERMANOVA

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Symbiodiniaceae communities were also driven by both parental and planulation environments. Parental colonies and their respective offspring harboured similar Symbiodiniaceae communities and shared dominant strains (Fig. 2a–c). Alpha diversity remained consistent across all sample types, but richness was significantly lower in water compared to coral samples. Recruit communities correlated significantly with both the parental (PERMANOVA: df = 1, F = 135.94, p= 0.001) and the planulation environment (PERMANOVA: df = 1, F = 15.2, p= 0.001), but not the transplant environment. The significant effect of planulation environment found here, with evidence of low abundance background strains that were present in recruits but not parents (Table S2), suggests that in addition to vertically receiving some Symbiodinaceae strains from their parents (e.g., [15]), recruits horizontally acquired some strains from their environment at this early life stage. This is consistent with recent reports on other pocilloporids (e.g, Stylophora pistillata, [16]; Seriatopora hystrix, [6]).

Fig. 2
figure 2

a Alpha diversity and b richness (p-value represents results from ANOVA) of Symbiodiniaceae between sample types; parent, recruit and water. c Principal component analysis plot of parent and recruit samples labelled according to sample type and parental ID where appropriate, clearly showing parents (circles outlined in black) clustering with respective recruits (p-value represents results from PERMANOVA). Inset graph represents dispersion by sample type (p-value represents results from PERMDISP)

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Recruits harboured more variable bacterial and Symbiodiniaceae communities in comparison to their parents. This confirms earlier studies showing a “winnowing” of microbial assemblages, where these are fine-tuned until a microbiome is achieved that is suited for local environmental conditions [17,18,19]. Thus, while parental and planulation environments were found to influence initial establishment, the host continues to play an active role in shaping the microbiome throughout life history.

In conclusion, the results presented here suggest the P. damicornis microbiome is driven by both parental and planulation environments. The dominant Symbiodiniaceae types in recruits were the same as in their respective parents, but also harboured additional environmentally acquired background strains. Bacterial communities were primarily influenced by planulation environment, but at least one bacterial strain was likely acquired within the parental environment. Thus, we hypothesize that the establishment of the microbiome in P. damicornis is likely facilitated by mixed mode transmission, but future research is needed for validation.