Porites astreoides was considered one of the least susceptible coral species to bleaching after exposure to heat waves recorded in the U.S. Virgin Islands in 2005 (Smith et al., 2013) and in the Cayman Islands, in 2009 (van Hooidonk et al., 2012). However, the ability of P. astreoides and their endosymbionts to recover from stress depended on the frequency of the exposure. When exposed to a single bleaching event, P. astreoides recovered endosymbiont abundance after 1.5 months (Grottoli et al., 2014; Levas et al., 2018) or within a year (Schoepf et al., 2015) at reef ambient temperatures. In contrast, colonies that were exposed to a recurrent bleaching treatment lost half of their endosymbionts and were not able to recover after six weeks in ambient temperatures (Grottoli et al., 2014). Porites divaricata was resilient to repeated bleaching via heterotrophic compensation, whereas the mounding corals P. lobata and O. faveolata used a combination of heterotrophy and thermally tolerant Symbiodiniaceae in their response to mild bleaching events (Levas et al., 2018).

Symbiodiniaceae associated with P. astreoides were sensitive to heat (Grottoli et al., 2014; Schoepf et al., 2015; Soto-Santiago et al., 2017b; Levas et al., 2018) and cold (Kemp et al., 2011) stress. Colonies exposed to 32°C lost ~ half of endosymbionts (Grottoli et al., 2014; Soto-Santiago et al., 2017b; Levas et al., 2018) and 40% to 75% of chlorophyll concentrations (Schoepf et al., 2015; Soto-Santiago et al., 2017b). Seawater temperatures lower than 16°C caused a significant reduction in gross photosynthesis and in the maximum photochemical efficiency of photosystem II (Fv/Fm) (Kemp et al., 2011). Also, P. astreoides showed low resilience to sedimentation, as Fv/Fm rates kept decreasing after 5 days of being removed from the treatments (Rushmore et al., 2021).

Synergistic effects of warmer temperatures and other environmental factors were threatening to the P. astreoides coral-algal physiology (Camp et al., 2016; Smith et al., 2019). Elevated temperature combined with OA decreased productivity of colonies collected from both high and low-variance habitats off the Cayman Islands, indicating that acclimatization to natural pH–temperature disturbances did not increase physiological performance of P. astreoides under future climate scenarios (Camp et al., 2016). During a 4-year field experiment in the Florida Keys, the presence of fleshy macroalgae (Dictyota spp. within 10 cm) was the environmental factor that best explained the increase in bleaching of P. asteroides corals in thermal stress (Smith et al., 2019). Bleaching was predominant in P. astreoides, observed in 69.0% of transplants, while only 7.1% of Siderastrea siderea bleached (Smith et al., 2019).

When tested individually, exposure to macroalgae and low pH alone did not negatively affect the algal endosymbionts in P. astreoides. Adult colonies were resistant to allelopathy from macroalgae as Fv/Fm rates were unaffected by crude extracts from Dictyota (Paul et al., 2011). After a two-year transplantation to a low aragonite saturation submarine spring, chlorophyll-a and endosymbiont densities increased, indicating a higher capacity for the photosynthetic activity that could provide additional energy to corals under suboptimum conditions (Martinez et al., 2019).

Growth of P. astreoides was reported in the literature to be equally sensitive and resistant/resilient to thermal stress. While P. astreoides showed negative calcification in response to elevated temperature (30.3°C) for two months (Okazaki et al., 2017); projected end-of-century annual mean temperature (31°C) for Caribbean reefs had no significant effect on calcification rates after ~ 3 months at this temperature (Bove et al., 2019). Heat-stress lowered calcification by 69% in experiments where P. astreoides colonies were exposed to 31°C for 7 days in a tank (Schoepf et al., 2015), but P. astreoides was able to recover pre-treatment growth after the heat-treated colonies were transplanted back on the reef for a year (Grottoli et al., 2014; Schoepf et al., 2015; Levas et al., 2018). However, repeated annual bleaching impaired the ability of P. astreoides to recover calcification rates (Grottoli et al., 2014). Calcification of P. astreoides colonies transplanted in situ were negatively correlated with heat stress  (Manzello et al., 2015).

The effects of OA on the growth of P. astreoides depended on the pCO₂ levels and exposure to heat stress. Calcification was stable at end-of-century pCO₂ (701/673 µatm) (Bove et al., 2019), but experienced major declines under higher pCO₂ (900, 1300, 3309/3285 µatm) (Okazaki et al., 2017; Bove et al., 2019). Reduced pH had a greater impact on calcification compared to temperature, although these factors had an additive decrease in calcification when combined (Camp et al., 2016). In contrast, the interaction between OA and heat did not significantly lower calcification of P. astreoides after a 30-day acclimation period (Bove et al., 2019).

Acclimatization to low pH did not seem to increase resilience in P. astreoides (Crook et al., 2013; Camp et al., 2016; Wall et al., 2019). The deleterious effects of OA were not significantly different between colonies acclimatized to high and low variance in pH (Camp et al., 2016). Corals collected in proximity to a low-pH groundwater plume showed significant decrease in calcification under OA in experimental conditions; comparable to the lower calcification rates in colonies that had not been previously acclimatized (Crook et al., 2013; Wall et al., 2019). After a two-year transplantation to a low-pH spring, linear extension and calcification were maintained but skeletal density of the coral decreased (Martinez et al., 2019). Similarly, sedimentation did not decrease linear extension rates but affected skeleton density and calcification (Elizalde-Rendón et al., 2010).

In contrast, the linear extension, density, or calcification of the skeleton of P. astreoides were not affected by a wide depth variability from 6 – 47 m, indicating the species growth was unaffected by depth (Groves et al., 2018). In mesophotic reefs (30 – 40 m depth), growth rates were also not significantly impacted by increased temperatures (Groves et al., 2018).

Macroalgal competition was a less understood factor that was very deleterious to P. astreoides. Growth was reduced by 40% on average when colonies were exposed to five different species of benthic macroalgae (Vega Thurber et al., 2012).

Recruitment of P. astreoides was unaffected, or even increased, by depth (Holstein et al., 2016b; Goodbody-Gringley et al., 2018). Planulae production increased with depth and was correlated to peak P. astreoides cover at 10 m and at 35 m off the U.S. Virgin Islands (Holstein et al., 2016b). Fecundity was maintained across 2 m to 33 m in Bermuda, and recruits collected from the upper-mesophotic zone showed higher settlement, growth, and survival rates (Goodbody-Gringley et al., 2018). In addition, a reciprocal transplantation experiment between shallow and mesophotic reefs showed that P. astreoides larvae survived and settled independently from the parental origin and that mesophotic light conditions increased survivorship (Goodbody-Gringley et al., 2021). Thus, mesophotic reefs may provide a refuge for P. astreoides enabling recruitment to shallower reefs (Holstein et al., 2016a).

OA decreased P. astreoides larval survivorship (Olsen et al., 2015), metabolism, settlement, post-settlement growth (Albright and Langdon, 2011), and recruit calcification (de Putron et al., 2011), but mild pH reductions (from 8.05 to 7.85) had no effects on settlement and survival of recruits (Campbell et al., 2017).

Larval physiology, survival, settlement, and metamorphosis were resistant to heat stress (Olsen et al., 2013; Ross et al., 2013; Ritson-Williams et al., 2016), although it caused inhibition of larval photochemical efficiency (Olsen et al., 2015), oxidative damage in the larval tissues (Olsen et al., 2013; Ritson-Williams et al., 2016), and post-settlement mortality (Ross et al., 2013). P. astreoides recruitment was reduced by half at sites that were highly exposed to an anomalous cold-water plume in the Florida Keys in 2010, and the effect was apparent three years after the event (Kemp et al., 2016).

Survival of P. astreoides recruits was lower under heat (30°C) when compared to ambient temperatures (26°C) and sedimentation was a key factor in either ameliorating or aggravating the effects of thermal stress (Fourney and Figueiredo, 2017). When the levels of sedimentation were low (30 mg.cm⁻², 6.55 NTU), coral recruits survived at rates closer to those under ambient temperatures. In contrast, high amounts of fine, anthropogenic sediment (≥ 60 mg.cm⁻², ≥ 14.2 NTU) significantly increased mortality of coral recruits under high temperatures (Fourney and Figueiredo, 2017). In a different study system, the relationship between sediment grain size and P. astreoides recruitment was reversed; fine sediment did not affect recruit survivorship or health, but coarse sediment did (Rushmore et al., 2021).

Exposure to fleshy macroalgae was harmful to P. astreoides recruitment (Paul et al., 2011), particularly when abiotic stressors were added (Olsen et al., 2015; Campbell et al., 2017). Dictyota significantly reduced larval survival and recruitment (Paul et al., 2011; Olsen et al., 2015). In synergy with OA and heat, Dictyota caused a four-fold increase in lipid peroxidation in P. astreoides larvae, which indicated cellular oxidative damage compared to control treatments (Olsen et al., 2015). When in contact with Stypopodium zonale, the survival of larvae was lower after 96 hours, but settlement was not affected (Campbell et al., 2017). In contrast, OA in combination with S. zonale significantly reduced settlement (Campbell et al., 2017).

The coral tissue properties of P. astreoides were sensitive to sedimentation (Rushmore et al., 2021), strongly shaped by temperature fluctuations (Kenkel et al., 2015a; Schoepf et al., 2015; Solomon et al., 2019), but sometimes resilient to thermal stress (Haslun et al., 2018; Levas et al., 2018), and OA (Martinez et al., 2019). Porites astreoides colonies showed increased levels of oxidative stress biomarkers in the tissue (carbonyl content, hydroperoxide) after exposure to moderate to high levels of sedimentation and did not show signs of recovery after 5 days of sediment removal (Rushmore et al., 2021). However, innate immune system-related genes maintained low levels of expression under a 32°C treatment, indicating resistance to thermal stress (Haslun et al., 2018). Porites astreoides was able to maintain lipids, proteins, and carbohydrates reserves during and after one year of exposure to a mild bleaching event (Levas et al., 2018), however, the species did not seem to rely on a long-term recovery capacity of their tissue condition following recurrent bleaching events (Schoepf et al., 2015). The most negative effects of thermal stress on P. astreoides tissue condition were a decrease of protein and carbohydrate concentrations and a higher amount of heterotrophic C versus photoautotrophic C (δ ¹³C_h−e) in the coral tissue, suggesting that colonies invested more in heterotrophy to compensate for the lack of energy reserves (Schoepf et al., 2015). Lipid class composition changed dramatically after recurrent bleaching events, with a 50% decline in wax esters (i.e., storage lipids) (Solomon et al., 2019).

Reciprocally transplanted colonies between inner and outer reefs in the Florida Keys experienced a decrease in mass gain and total lipid, protein, and carbohydrate content after one year. Reef-scale specialization to temperature, especially the frequency of thermal fluctuations, was considered the primary driver (Kenkel et al., 2015a). In contrast, high protein concentration was maintained after a two-year transplantation to a low aragonite saturation submarine spring, indicating acclimatization of the tissue properties to the suboptimum conditions (Martinez et al., 2019).

The literature search identified only three papers that described the microbiomes associated with P. astreoides in response to stress and the stress in each case was associated with macroalgae. The microbiome associated with P. astreoides was altered in the presence of macroalgae (Vega Thurber et al., 2012; Morrow et al., 2013), but the response depended on the macroalgae species (Morrow et al., 2012). Lobophora variegate aqueous extracts caused dysbiosis, while Dictyota (organic) extracts had a significant effect on bacterial assemblages (Morrow et al., 2012). Microbial taxa composition in the surface mucous layer of P. astreoides was disrupted by exposure to macroalgae, where each macroalgal species induced a different response compared with control treatments (Vega Thurber et al., 2012). The presence of macroalgae increased variability in the coral microbiome among colonies within the same treatment, which could be a sign of the loss of beneficial microbes and microbiome dysbiosis (Vega Thurber et al., 2012). In situ interactions between P. astreoides colonies and macroalgae Dictyota menstrualis and Halimeda opuntia in the U.S. Virgin Islands, the Florida Keys, and Belize, shifted the coral-associated microbial communities (Morrow et al., 2013). In the coral-algal competition zone, the coral P. astreoides maintained a relatively more stable microbiome compared to the coral Montastrea cavernosa and provided a competitive edge for P. astreoides against macroalgae (Morrow et al., 2013).