Abstract
Coral morphology has important implications across scales, from differences in physiology, to the environments they are found, through to their role as ecosystem engineers. However, quantifying morphology across taxa is difficult, and so morphological variation is typically captured via coarse growth form categories (e.g. arborescent and massive). In this study, we develop an approach for quantifying coral morphology by identifying continuous three-dimensional shape variables. To do so, we contrast six variables estimated from 152 laser scans of coral colonies that ranged across seven growth form categories and three orders of magnitude of size. We found that 88% of the variation in shape was captured by two principal components. The main component was variation in volume compactness (cf. convexity), and the second component was a trade-off between surface complexity and top-heaviness. Variation in volume compactness also limited variation along the second axis, where surface complexity and top-heaviness ranged more freely when compactness was low. Traditional growth form categories occupied distinct regions within this morphospace; however, these regions overlapped due to scaling of shape variables with colony size. Nonetheless, with four of the shape variables we were able to predict traditional growth form categories with 70 to 95% accuracy, suggesting that the continuous variables captured most of the qualitative variations implied by these growth forms. Distilling coral morphology into continuous variables that capture shape variation will allow for better tests of the mechanisms that govern coral biology, ecology and ecosystem services such as reef building and provision of habitat.
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Introduction
The shape and size of organisms determines how they interact with the physical environment and with other organisms (Denny 1993; Vogel 1996). This is especially true for sessile colonial organisms, where variation in morphology has been linked to a range of biological and ecological processes (Jackson 1977, 1979). For example, growing upwards from the benthos reduces benthic competition, while growing laterally reduces whole colony mortality by spreading risk (Jackson 1979). Despite the fundamental importance of a colony’s morphology, there is no general framework for capturing morphological variation. Instead, scientists tend to lump individuals and species into discrete growth form categories [corals: (Veron 2000); bryozoans: (Bishop 1989); bacteria: (Shapiro 1995)] or use continuous metrics that cannot partition the effect of size and shape [e.g. surface area-to-volume ratio; (Naumann et al. 2009)]. Developing a quantitative framework is challenging for colonial organisms because they have geometrically complex forms, high intraspecific and interspecific variation in shape, and lack readily identifiable landmarks for comparative analysis. However, new technologies such as CT and laser scanning make it possible to accurately capture the diversity of shapes exhibited by colonial organisms (Lavy et al. 2015; House et al. 2018). Here, using reef corals as a study system, we develop a morphological schema using quantitative, three-dimensional shape variables.
Scleractinian corals are a prime example of colonial organisms whose morphology directly dictates life history strategies (Jackson 1979), demographic rates (Madin et al. 2014; Álvarez-Noriega et al. 2016; Dornelas et al. 2017) and provisioning of habitat for other taxa (Bell and Galzin 1984; Graham and Nash 2013; Richardson et al. 2017b). The aragonite skeleton that Scleractinian corals secrete as they grow provides support and shape; however, most of the live biomass is associated with the surface (Johannes and Wiebe 1970; Hoegh-Guldberg 1988). These characteristics have consequences for vital processes such as growth and survival, where higher surface area-to-volume ratios allow more biomass per unit investment in skeleton, but may increase the risk of partial colony mortality (Lirman 2000), dislodgement (Madin 2005), and susceptibility to thermal bleaching (Baird and Marshall 2002). In parallel, coral structures provide direct habitat for many taxa and can act as predator refuge for both adult and juvenile fishes (Friedlander and Parrish 1998; Kerry and Bellwood 2012). At the habitat scale, variation in the morphology of each colony in an assemblage contributes to the overall structural complexity of the habitat (Richardson et al. 2017a), which has been linked to ecosystem properties, such as microhabitat availability (Graham and Nash 2013) which in turn influences community structure (Almany 2004; Nash et al. 2014), and larval recruitment (Hata et al. 2017). Furthermore, variation in colony shape influences the persistence of colony skeleton following mortality and reef matrix building and infilling processes (Rasser and Riegl 2002; Glynn and Manzello 2015). Yet, despite the importance of morphology for the functioning of both the corals themselves and coral reef ecosystems, quantitative studies of coral morphology are sparse, presumably because of difficulties in measuring and dealing with the geometric complexity of coral forms.
Scleractinian corals exhibit high levels of variation in morphology within and among taxa. They vary from simple shapes, such as encrusting or hemispherical colonies, to tree-like branching shapes. There are also varying degrees of morphological plasticity within species driven by interactions with local environmental conditions (Foster 1979), though some variation among species is genetically constrained (Filatov et al. 2013). Additional phenomena such as partial mortality (Meesters et al. 1996), colony fragmentation (Karlson 1986) and indeterminate growth (Sebens 1987) add to the complexity and observed variation in morphology from colony to colony, even within species and conspecifics. Corals need access to free-flowing water for filter feeding, and light for photosynthesis, both of which are linked to morphological variation (Kaandorp et al. 1996; Hoogenboom et al. 2008). Additionally, competition for space results in many colonies growing up from the substrate to increase standing biomass without needing to continuously colonise new substrate (Jackson 1977). However, many sessile colonial organisms within marine environments are subjected to hydrodynamic forces that can dislodge entire colonies if they grow too far away from the substrate, restricting the range of available morphologies (Koehl 1999). Taken together, coral colonies exhibit multiple morphological trade-offs that result in the vast array of observed variation in morphology (Chappell 1980; Kaandorp et al. 1996).
Scleractinian corals are typically categorised into growth forms based on coarse morphological similarities. Growth forms are useful for species identification and monitoring changes in assemblage structure, but do not adequately capture geometric complexity or intraspecific variation in shape. Phenotypic plasticity is common among coral species, where the same species can exhibit different growth forms in different environments (Veron 2002). Despite these limitations, growth form is a useful metric because life processes can differ significantly among categories. For example, growth form is a good predictor of competitive ability (Connell et al. 2004; Hoogenboom et al. 2008) and zonation patterns (Chappell 1980; Done 2011). Growth form and size affect demographic rates including fecundity (Álvarez-Noriega et al. 2016), growth (Dornelas et al. 2017) and background mortality (Madin et al. 2014). While these results highlight differences between growth forms across a range of processes, they are unable to directly assess process-based hypotheses for the observed differences, nor can the results be generalised to other growth forms or taxa with similar morphological adaptations but different overall morphology (e.g. sponges, hydrozoans, algae, plants, etc.). As such, recent studies have begun to explore techniques for quantifying and comparing the three-dimensional shape of corals (Bythell et al. 2001; Filatov et al. 2010, 2013; Lavy et al. 2015; Reichert et al. 2017; House et al. 2018). We build on this work to develop a quantitative schema for coral morphology via variables that capture shape variation.
Many processes in corals have size-dependent relationships (Madin et al. 2014; Dornelas et al. 2017); however, these relationships change depending on growth form, suggesting that colony shape is also important. Quantitative variables that attempt to explain these differences should therefore aim to be causally linked to processes and partition the effects of shape and size separately. Morphology has previously been quantified using variables such as corallite area and branch spacing that may have implications locally within a colony or at the polyp scale (Bruno and Edmunds 1997; Shaish et al. 2007). Surface area-to-volume ratios are an example of whole colony information with expected causal links to processes (Hoegh-Guldberg 1988). However, surface area-to-volume ratio can change with either differences in shape or size or both, making the effects of shape and size on other processes difficult to disentangle when using this metric. Recent work within the genus Madracis has quantified coral branching patterns and growth processes using 3D imaging (Kaandorp et al. 1996; Filatov et al. 2010); however, measuring whole colony morphology across a broad taxonomic and morphological scale along multiple axes of variation simultaneously has been limited. By measuring multiple, size-independent variables across a wide range of morphological variation, trade-offs and broader patterns become clearer, including how shape changes as colonies get larger.
Variables that can capture how a colony is spatially distributed in the environment should capture functionally relevant axes of morphological variation. For example, variables that measure colony volume compactness may act as a good indicator of “branchiness” or how sturdy a colony is, capturing a continuous gradient from massive to arborescent colonies. Variation in compactness may therefore covary with processes such as growth rates, fragmentation and habitat provision (Gladfelter et al. 1978; Lirman 2000; Alvarez-Filip et al. 2011). Two variables that can capture volume compactness are convexity and sphericity, where convexity captures the ratio of the objects volume to the volume immediately surrounding it, and sphericity which captures how close an objects shape is to a sphere, which is the most compact shape possible in three dimensions.
Another axis of variation is how the surface area of a colony is distributed in space, which should capture a gradient from flatter, less convoluted surfaces to colonies with highly complex and convoluted surfaces. Variation in surface complexity may capture a functional trade-off axis between biomass packing (e.g. having more biomass for a given area of space) and decreased intra-colony competition for resources (e.g. increased light per unit biomass when surface area is spread out) (Hoogenboom et al. 2008; Wangpraseurt et al. 2012). Surface complexity can be captured with two shape variables, fractal dimension, which captures how surface area fills space at different scales and is an estimate of spatial complexity, and packing, which captures how much of an object’s surface area is situated internally versus externally in relation to its immediate environment.
The previous four shape variables are all rotationally and size invariant (i.e. the orientation or size of colony meshes has no bearing on the resulting value). However, a distinguishing feature of shape in competing benthic organisms is how volume and surface area are distributed vertically above the substrate, or “top-heaviness”. For instance, a tabular coral colony has volume and surface area distributed further away from the substrate than a hemispherical colony that is “bottom heavy”. To capture this feature, we used first moments of volume (VVOL) and surface area (VAREA), which are the sums of the products of volume and area, respectively, with their vertical distance from the colony attachment point. This axis can be expected to covary with processes such as whole colony dislodgment, benthic competition strategy and microhabitat diversity (Jackson 1979; Kerry and Bellwood 2012; Madin et al. 2014).
Morphology is important for corals and the ecosystems they build, but a comprehensive suite of quantitative traits for developing explanatory and generalised models for these processes has yet to be formalised. By measuring these axes of morphological variation, we can place coral colonies along multiple functional axes, moving from a subjective, categorical framework towards a quantitative, functional trait-based one. The aim of this study was to measure a set of morphological variables that capture biologically relevant axes of variation in corals. To achieve this aim, we first derived six morphological variables and measured them across a broad diversity of colony shapes and a wide range of sizes via high-resolution 3D laser scanning. We then asked: (i) how do corals occupy continuous morphological space? (ii) where do growth form classifications sit within this space? (iii) how does the shape of growth forms covary with size? and (iv) do continuous variables capture the subjective information encoded in growth forms? We show that the variables outlined in this study can place growth forms on three continuous axes of variation and provide a more precise, mechanistic toolkit for ongoing research.
Materials and methods
Data collection
Colony skeletons from coral collections at the Natural History Museum in London (UK), the Bell Pettigrew Museum at the University of St Andrews (UK) and the Museum of Tropical Queensland (Australia) were scanned using an optical laser scanner (EXAScan, Creaform.inc) and proprietary processing software (VXElements 5, Creaform.inc) to digitize their three-dimensional morphology. The scanner software builds a triangulated mesh during data collection to output a range of mesh file types without the need for further processing. Colonies were selected for scanning to capture a broad range of shapes and sizes across a diversity of traditional coral growth form classifications [arborescent, corymbose, digitate, laminar, massive, sub-massive or tabular; (Veron 2000)]. Colonies were also selected to be mostly intact with few breakages; however, in some cases a minor amount of damage was present. The final data set included seven growth forms, 38 species and ranged in size from 5.3 to 9242.5 cm3 (for further details, see Table S1). Specimens were from a broad range of environments and locations making the results of this study more variable than if specimens were collected from the same environment. The use of coral skeletons instead of live colonies means that some surface properties at the microstructural scale are likely to be different for colonies in situ, but is appropriate to capture whole colony morphology.
Scanning was conducted with a standard resolution of 0.5 mm2 but needed to be decreased to 1 mm2 for several large or complex colonies due to computational constraints. All colony scans were orientated with the z-axis aligned with the colony’s likely upward orientation when on the reef. Each scan consisted of a digital 3D mesh that was comprised of a single contiguous surface of connected triangles. In many cases, non-coral substrate was also included in the scan data and was removed prior to analysis. Meshes were rejected if the final mesh deviated in shape from the actual specimen due to issues associated with interpolating missing scan data. Growth form categories were selected if there were at least five observations of sufficient quality. The final dataset consisted of 152 meshes. To test the precision and accuracy of the laser scanner, 20 colonies previously scanned using a medical CT scanner (House et al. 2018) were rescanned using the laser scanning protocol and morphological measurements were compared (Fig. S1).
Size and shape variables
For each colony mesh, we calculated two size variables, volume and surface area, and six shape variables that pair off into three axes of shape variation: sphericity and convexity (capturing volume compactness), packing and fractal dimension (capturing surface complexity) and the first moments of area and volume (capturing top-heaviness). Further details of each shape variable follow, but further information and the equations for each variable are contained in Table S2. All variables were calculated in R (R Core Team 2015), and various functions are included as supplementary material.
The surface area of each mesh was calculated by totalling the area of each triangle in the mesh. Because corals are irregular objects, the volume of each mesh was approximated using the signed volume principal (Zhang and Chen 2001). For each triangle in the mesh, a tetrahedron was formed using the triangle and the origin, and its volume calculated. If the triangle faces away from the origin, its volume is positive, and if the triangle faces towards the origin it is negative. By totalling up the positive and negative volumes, a close approximation to the true volume of the mesh is obtained.
Volume compactness is captured here by two variables. Sphericity S is a size invariant measure of the compactness of an object’s volume (Wadell 1935). It is calculated as the ratio of the surface area of a sphere with the same volume as the object and the surface area of the object. Sphericity is bounded by zero (i.e. a theoretical shape that is entirely non-compact, like a plane) and one (i.e. a perfect sphere) and is size independent. Because sphericity is a ratio between zero and one, but never exactly zero or one, it was logit-transformed for analyses. Convexity C is a size invariant measure of the degree to which there is space between different parts of an object (Zunic and Rosin 2004). Convexity is calculated as the volume of an object divided by the volume of its convex hull, where the convex hull is the shape formed by the smallest possible boundary that has no concave areas around an object (Barber et al. 1996). Like sphericity, convexity is bounded by zero (i.e. a theoretical shape that has no volume but some convex volume) and one (i.e. a shape that is entirely convex) and was logit-transformed for analyses.
Surface complexity is also captured by two shape variables. Another form of convexity (which we call packing P for clarity) is a size invariant ratio of how much of an object’s surface area is situated internally versus externally in relation to its immediate environment (Zunic and Rosin 2004). It is calculated as the surface area of an object divided by the surface area of its convex hull. A packing value above one indicates that surface area is packed within the volume it occupies (i.e. it is more inverted). Values below one indicate that surface area is more spread out over the volume it occupies (i.e. it is more everted). Convex shapes have a packing equal to one, as the surface area is neither internally nor externally distributed, and objects with an equivalent amount of “inverted” and “everted” surface also have a packing equal to one. As packing is a proportion that can go above or below 1, it was log10 transformed for analyses. Fractal dimension D captures how surface area fills space and is an estimate of spatial complexity. We calculated fractal dimension using the “cube counting” algorithm, a 3D analogue of the well-known box counting method (Sarkar and Chaudhuri 1994). Fractal dimension is bounded between two (a plane) and three (a theoretical 2D surface that is completely volume filling) and is size invariant. Fractal dimension is calculated as the slope of log10(N) ~ log10(C), where N is the total number of cubes that contain any surface of the object and C is the number of equal sized cubes in the 3D cube array. For each colony, we generated a vector of 25 box sizes that were equally spaced on a log10 scale, with the largest box size having side lengths equal to the longest dimension of the coral. We then selected cube sizes where the smallest was double the size of the laser scanner resolution (0.5 mm3) and the largest was less than the size of longest dimension of the coral. The smaller cut-off was to ensure that boxes that should overlap with a surface, for example a box between two points that are connected, was still counted. The larger cut-off was because the chance of a box with the same size as the coral overlapping a point is 1, and so every colony would have the same value regardless of their shape.
Top-heaviness was captured by the first moments of volume (VVOL) and surface area (VAREA) with respect to the vertical distance from the attachment area. For VAREA, the area of each triangle in the mesh was calculated and multiplied by the vertical distance from the centroid of the triangle and the centroid of the attachment plane. For VVOL, a similar algorithm was used. For each triangle in the mesh, a tetrahedron between the triangle and the origin was calculated. The signed volume of each tetrahedron was multiplied by the vertical distance between the centroid of the tetrahedron and the centroid of the attachment plane. Both variables were log10 transformed for analysis. To ensure size invariance, colony meshes were converted to a standard volume of 1 mm3 before these variables were calculated.
Analysis
We used principal components analysis (PCA) to visualise the morphospace, how growth forms occupied this space, and to identify which shape variables explained most of the variation in colony shape [via the “prcomp” function in R (R Core Team 2015)]. Variables were standardised with a mean of zero and unit variance to reduce the influence of variable scale on the projection. For each principal component, variables were highlighted as important for a given component based on whether their loadings exceeded the null contribution value of 16.6% (100% divided by six variables). Pair-wise plots of raw data with Pearson’s correlations were used to identify how variables covary and which variables were highly collinear both within a given component and between the variables overall. A LOESS smooth regression was fitted to each variable pair to visualise relationships without making any assumptions about the distributions or linearity of the data.
To test whether shape remained constant with colony size, we used a linear regression approach, with shape variable as the response, and growth form, volume and their interaction as predictors (using the “lm” function in R). Each shape variable within each growth form was deemed to remain constant with size if zero was within the 95% confidence intervals for the slope estimate.
To infer whether the morphological variables captured a broad proportion of the subjective variation encoded in growth forms, we first added 95% confidence ellipses for each growth form to the PCA to visualise how growth forms occupied continuous shape space. We then used multinomial regression to see how well the shape variables could predict the correct growth form [via the “multinom” function from the R package “nnet” (Venables and Ripley 2002)]. We built the initial model based on a set of variables that captured different axes of variation in shape and had low covariance to minimise redundancy of information. No interactions between shape variables were included. Additionally, volume was not included as a main effect as size is not a determining characteristic for growth form. However, volume was included as an interaction effect with shape variables that were shown to vary as a function of volume. Finally, we used this model as the basis for a leave-one-out assessment of predictive accuracy, where a model that omitted an observation was fitted, and the omitted observation data used to generate probabilities of that observation belonging to any one growth form classification, as well as assigning a single class. This was repeated for every observation sequentially and the predicted probabilities and classes were pooled, with the probabilities used for a visual assessment of model performance and the classes used for the generation of a confusion matrix to assess classifier (in this case the multinomial model) performance. The predicted class dataset was assessed via kappa values and balanced accuracy estimates to assess classifier accuracy (Cohen 1960). The overall model was assessed for goodness of fit via McFaddens pseudo-R2.
Results
Corals in continuous shape space
87.5% of the observed variation in shape was captured by the first two principal components (PC) (Fig. 1). The first PC captured 60% of the variation across the six-dimensional shape space and was comprised of sphericity, convexity and the first moment of area (VAREA). All three variables had contribution values above 16% with sphericity and VAREA having joint highest at 25% and convexity at 22%, suggesting they were all important for explaining the variation along PC1. All three variables were highly correlated (Fig. 2), where sphericity and convexity were positively correlated, with both being negatively correlated with VAREA. Of these three variables, convexity was selected for the predictive model as it had the weakest correlation with the other three variables, therefore minimising redundancy. The second PC captured 27.5% of the variation and was comprised of packing, fractal dimension and the first moment of volume (VVOL). Of these variables, packing had the highest contribution at 35%, followed by fractal dimension (32%) and VVOL (24%) (Fig. 1). Packing and fractal dimension were highly correlated with each other (Fig. 2); however, both were uncorrelated with VVOL. Of these variables, both VVOL and packing were selected for the predictive model; VVOL because it was uncorrelated with the other two variables and packing as it was slightly less correlated with the other variables compared to fractal dimension.
Coral colony shape was constrained by compactness. When sphericity and convexity are high, there was less variation in surface complexity (captured by packing and fractal dimension), with a similar but less pronounced effect on VVOL (Fig. 2). Additionally, there was a nonlinear decrease in VAREA as a function of these two variables. Sphericity had the highest correlation scores with the other shape variables. In the PCA projection, we also observed this constraining effect, where the spread of points along PC2 is markedly restricted in extent and density at lower PC1 scores (i.e. higher sphericity and convexity) (Fig. 1). As sphericity and convexity decreased, however, the extent of occupied shape space along PC2 increased.
Growth forms in continuous shape space
There were two apparent gradients that captured how growth forms were distributed in continuous shape space (Fig. 1). The first was along PC1 where the massive and sub-massive growth forms were isolated from the branching growth forms. The second was along PC2 within the branching group, with the digitate, corymbose, tabular, laminar and arborescent growth forms distributed roughly in that order. The mean position for a given growth form overall was generally constrained within shape space; however at the colony level, many growth forms were found occupying the same area which was partially explained by variation in shape as a function of size.
Changes in colony shape with size
While there were no significant correlations between any shape variable and size (represented as colony volume) across all the observed values together except for packing (Fig. 2), the shape of a colony did change as a function of size within some growth form and shape variable combinations (Fig. 3). Because each shape variable is size independent (i.e. consistent for the same shape across any range of sizes), the observed changes in shape with size shown here are likely to be genuine differences in shape as size increases. Sphericity decreased with size in the digitate and laminar growth forms. All other growth forms maintained constant sphericity across their observed size range except the tabular and arborescent group which appeared to decrease marginally as volume increased despite their slope estimate confidence intervals overlapping with zero (Fig. 3). Packing increased with size fastest in the arborescent group, followed by the corymbose, laminar, digitate and tabular growth forms, with the massive and sub-massive colonies remaining constant. The massive group decreased in fractal dimension with size and the corymbose colonies increased with size. All the other variables remained constant as a function of volume based on the 95% confidence intervals. However, there was some evidence to suggest that both VVOL and VAREA may scale with size in some growth forms (Fig. 3).
Capturing qualitative growth forms using quantitative variables
Growth form was correctly predicted by four shape variables in conjunction with volume (Fig. 4). The model included convexity, packing, VVOL and fractal dimension, with interaction terms between volume and both packing and fractal dimension. The final model explained 74% of the deviance (McFadden’s pseudo R2 of 0.62, d.f = 42). Overall, the model predicted growth forms with a high degree of accuracy (kappa = 0.66). The growth forms in order of highest to lowest balanced accuracy were: massive (95.1%, n = 22), arborescent (92.6%, n = 16), sub-massive (91.3%, n = 6), digitate (81%, n = 30), corymbose (80.7%, n = 41), tabular (77.2%, n = 17) and laminar (70.2%, n = 20). Fractal dimension was added to the model as the three shape variables alone were unable to distinguish between tabular and laminar growth forms, despite the balanced accuracy of all other groups being above 79%. The probability of the correct class in the final model was the highest for all growth forms and was distinct from all other potential classes (Fig. 4). The massive group had the highest mean probability (0.95 ± 0.04), with the laminar and tabular having the lowest (0.48 ± 0.07 and 0.50 ± 0.1, respectively).
Discussion
We developed six quantitative shape variables and showed that variation in volume compactness, surface complexity and top-heaviness explained much of the variation in coral shape. The observed changes in some variables with colony size resulted in colonies that straddled traditional growth form classifications (Fig. 3). We found that four morphological variables can predict traditional growth form classifications with accuracies ranging from 70 to 95%, demonstrating that these variables captured most of the variation encoded in traditional growth form classifications (Fig. 4). Our approach was able to place coral colony morphology along continuous axes of functional variation without relying on homologous structures or landmarks, providing a set of morphological traits to explore general links between shape and biological and ecological processes across multiple growth forms and colonies simultaneously.
Coral morphology was partitioned into three main axes of variation (Figs. 1, 2). Variation in volume compactness captured a gradient from non-branching to highly branching colonies. However, compactness constrained surface complexity and top-heaviness, where colonies with higher levels of compactness tended to be smooth and bottom heavy. Furthermore, each of the three axes can provide causal explanations for biological processes. For example, volume compactness may be a suitable trait for explaining why more massive morphologies have less variable and slower overall growth because it captures a gradient from massive to more complex forms and relates to surface area-to-volume ratios (Dornelas et al. 2017). Similarly, variation in top-heaviness, capturing a gradient from lower lying to tabular colonies, may be a trait that can test ideas related to benthic competition strategies (e.g. lateral benthic expansion vs indirect shading and competitive escape) (Jackson 1979). Variation in surface complexity is related to competition and resource use, where colonies with their surfaces distributed in a complex way have less resources (e.g. light, nutrients) per unit surface area but can have more polyps packed within a given space (Wangpraseurt et al. 2012). For example, if light levels are low, uniformly spreading out surface area maximises incoming light per surface area, which is reflected by increasing abundance of plating colonies as depth increases (Chappell 1980). These hypotheses are based on organism performance, but others can be formulated across a range of scales. Examples include low compactness colonies providing habitat for juvenile fishes (Alvarez-Filip et al. 2011), high compactness colonies increasing reef framework building (Rasser and Riegl 2002), high surface complexity increasing larval recruitment (Hata et al. 2017) and niche diversification being increased by top-heavy, tabular colonies (Kerry and Bellwood 2015). The ability to formulate and test these types of causal hypotheses offers a direct approach for linking form to function not possible using growth forms, and not clouded by metrics that conflate shape and size.
Growth forms typically occupied specific areas of continuous shape space, but the large amount of overlap between them suggests that growth forms are less distinct than their discrete nature implies (Figs. 1, 3). Growth forms were also not distributed along a single trajectory of morphological variation which highlights that morphological variation between growth forms occurs along multiple axes. Therefore, a single ordinal classification of categories, for example from most to least “complex”, would be misguided. Overall, the semi-distinct, semi-overlaying distribution and variation in growth forms at once confirms that growth forms work as morphologically distinct classifications to some degree but at the same time suggests that they are less definite and defined than implied by the nature of assigning a single category. This potentially unsatisfactory statement is made more palatable once morphological plasticity and the observed changes in shape as a function of size within growth form (Fig. 3) are considered: not every corymbose colony looks alike in the same way that each member of a wildebeest herd does, and a tabular colony only looks truly tabular after an initial period of growth up and out from the benthos. As such, the size distribution of colonies may have implications for the shape distributions of colonies within a growth form. Within growth form changes in life history traits with size have been highlighted previously (Madin et al. 2014; Álvarez-Noriega et al. 2016; Dornelas et al. 2017), which may be partially explained by ontogenetic changes in morphology and morphology-related processes. While variation in processes between growth forms acts as an indicator that morphology plays an important role, the incomplete and overtly definite nature of growth form categories are unsuitable for establishing causal links. The shape variables proposed here, however, offer an approach for establishing such links due to their quantitative, non-discrete nature.
While this study included a wide range of growth forms and sizes, there are unobserved sources of variation that may fill in or stretch the boundaries of the observed shape space if added. Encrusting colonies, which extend laterally over the surrounding substrate, were not included due to the difficult nature of obtaining whole colony specimens and the fact that the three-dimensional shape of an encrusting colony is contingent on the local substrate it encrusts, although in situ measurements of encrusting forms should be possible via photogrammetry techniques. Columnar colonies are also absent due to a lack of intact specimens in the museum collections. The less populated area of the observed morphospace between the massive and sub-massive growth forms and the remaining growth forms would likely be occupied by columnar colonies given their semi-sturdy, semi-branching shape. While the range in colony size in the study varied over three orders of magnitude, including both smaller and larger colonies in the dataset may also further fill in and expand the observed shape space. Further, there are likely to be microstructural differences between live colonies and skeletons; however, the focus of this study was on broader differences at the colony scale which are likely to be larger than differences between live and dead colony scans.
Both the approach and results of our study have applications for relating morphology to process in other taxa. Because the variables used in this study require no taxon-specific information to calculate (e.g. landmarks) they can be used to measure and compare morphological variation across any organism where a suitable 3D representation is available. Other colonial organisms such as sponges, soft corals, gorgonians and macroalgae are similar in their range of geometric complexity and are exposed to similar conditions, which suggest that similar trade-off axes should exist in these taxa. Measuring complex colony shapes across taxonomic groups would allow for empirical testing of the theoretical work on morphological strategies laid out by Jackson (1979). In the terrestrial realm, there is a large body of work on the functional ecology of plants which partially overlaps with corals given that both groups are sessile, able to experience partial mortality, and have a photosynthetic component. Going a step further, it should also be possible to compare morphology across a range of organisms, from bacteria to blue whales, to potentially uncover universal drivers of morphological adaptations via the variables outlined in this study.
This study provides a comprehensive set of traits that partition shared and unique variation between growth forms and highlight size-dependent changes in shape within growth forms. These traits have strong theoretical links to many processes important for both corals and their roles as ecosystem engineers and allow for causal explanations of phenomena to be established across a broad range of morphological variation. This study provides an empirical toolkit and theoretical backbone for future reef research that is timely given the ongoing work on three-dimensional metrics and methods, and the need to establish a broader understanding of how morphology maps to function across scales.
Data availability
Morphological traits data available from figshare. https://figshare.com/articles/CoralColonyMorphologyData_WholeColonies_MediumToHighQuality_LaserScanned/8115674. Scripts and functions available from https://github.com/Kylezx1/QuantifyingCoralMorphology.
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Acknowledgements
We would like to acknowledge Francois Leclerc and CREAFORM Inc. for providing equipment and technical support for the data collection. Luc Bidaut and Jenny House for CT scan data for calibration. Miranda Lowe and the Natural History Museum of London, Tom Bridge and the Museum of Tropical Queensland, and the Bell Pettigrew museum for facilitating specimen access and data collection. Kristin Precoda, Rachael Woods and Damaris Torrez-Pulliza for proofreading and feedback throughout. MD was supported by the John Templeton Foundation (60501) and a Leverhulme Fellowship, while JM was supported by the Australian Research Council (FT110100609) during the period this research was undertaken.
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Zawada, K.J.A., Dornelas, M. & Madin, J.S. Quantifying coral morphology. Coral Reefs 38, 1281–1292 (2019). https://doi.org/10.1007/s00338-019-01842-4
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DOI: https://doi.org/10.1007/s00338-019-01842-4