Limited acclimation of early life stages of the coral Seriatopora hystrix from mesophotic depth to shallow reefs

Mesophotic coral ecosystems (MCEs, reefs between 30 and 150 m depth) have been hypothesized to contribute to shallow reef recovery through the recruitment of larvae. However, few studies have directly examined this. Here we used mesophotic colonies of Seriatopora hystrix, a depth generalist coral, to investigate the effect of light intensity on larval behavior and settlement through ex situ experiments. We also investigated juvenile survival, growth, and physiological acclimation in situ. Bleached larvae and a significant reduction in settlement rates were found when the mesophotic larvae were exposed to light conditions corresponding to shallow depths (5 and 10 m) ex situ. The in situ experiments showed that mesophotic juveniles survived well at 20 and 40 m, with juveniles in shaded areas surviving longer than three months at 3–5 m during a year of mass bleaching in 2016. Juvenile transplants at 20 m showed a sign of physiological acclimation, which was reflected by a significant decline in maximum quantum yield. These results suggest that light is a significant factor for successful recolonization of depth-generalist corals to shallow reefs. Further, recolonization of shallow reefs may only occur in shaded habitats or potentially through multigenerational recruitments with intermediate depths acting as stepping stones.

www.nature.com/scientificreports/ symbionts after exposure to an excessive amount of absorbed light energy 18,19 . However, larvae and juveniles may be more flexible to environmental changes. For instance, coral larvae 20 and juveniles 21 have the flexibility to associate with multiple algal symbiont types that shape their survival and growth. Hence, their physiological responses to depth transplantation should be tested. Seriatopora hystrix Dana 1846, is a widespread scleractinian coral in the Indo-Pacific region. This coral is an ideal species model since it is abundant at an MCE in Okinawa 22,23 while it disappeared locally in a nearby shallow reef following bleaching events in 1998 24 and 2001 with no recovery in the shallow reef observed until 2010 25 and later 26 . Here we examined the effect of light on mesophotic coral larval behavior and settlement in a laboratory experiment as well as on the survival, growth, and physiological acclimation of juveniles in a field experiment. These experiments clarify whether coral larvae from mesophotic depth (from ca. 40 m depth) can settle in shallower reefs and whether the settled juveniles can survive and grow in this environment.
The planulae were actively crawling and settled rapidly within hours after release under control (i.e., 40 m depth) light conditions (Fig. 2). Percent of settled larvae differed significantly between light conditions both in 2015 (Mann-Whitney U, P = 0.004, pairwise comparison: 40 m > 10 m) and 2016 (One-Way ANOVA, F = 9.008, df = 3, P = 0.001; Fig. 2). The percentage of settled larvae reduced significantly in 5 and 10 m light conditions compared to control, while the percentage of settled larvae in 20 m light condition was similar (40 m = 20 m ≥ 10 m = 5 m lights; Bonferroni, P = 0.001). All larvae survived in 40 and 20 m conditions, while in 10 and 5 m conditions, survival rates of both crawling/swimming and settled larvae reduced by 1.1 and 7.8%, respectively (Fig. 2). In addition, 16.9 and 100% of the surviving pre-and post-settled larvae became pale or bleached when exposed to 10 and 5 m light conditions, respectively ( Supplementary Fig. 2).
Survival and growth rate of juvenile (field experiment). Most juveniles in exposed orientation at 3-5 m (in 2015, 2016) and 20 m (in 2016) did not survive the first month (Fig. 3). In 2015, the survival of juveniles at 3-5 m depth (0%) was significantly lower than other depths (i.e., 20 and 40 m) (Mantel-cox log-rank test, P < 0.001; Fig. 3; Supplementary Table 1). Depth also influenced juvenile survival at the deeper sites in an exposed orientation in 2015, where the 20 m juveniles had significantly lower survival (9.5%) than the 40 m control juveniles (11.1%) after six months (Mantel-cox log-rank test, P = 0.005; Fig. 3; Supplementary Table 1). In 2016, juveniles at 20 m in a shaded orientation (12.1%) and the control juveniles (40 m depth, exposed ori- Table 1. Mean daily maximum irradiance (PAR, Photosynthetically Active Radiation) between June 2015 and February 2017 and mean seawater temperature during the crucial acclimation period (i.e., the first month) of coral juvenile transplant experiments in August-September 2015 and 2016 at the depths of 3-5, 20, and 40 m in exposed and shaded orientations. www.nature.com/scientificreports/ entation; 6.3%) survived after six months, while the juveniles at 3-5 m shaded orientation only survived three months (3.6%) (Fig. 3). Importantly, orientation influenced juvenile survival, where the survival at 3-5 m and 20 m in a shaded orientation was similar to survival at 40 m in an exposed orientation (Mantel-cox log-rank test; P > 0.05; Supplementary Table 1). In 2015, the number of polyps in juveniles in an exposed orientation at 20 and 40 m increased (Fig. 4), and the mean geometric diameter also increased ( Supplementary Fig. 3), although differences were not significant. An average (± SE) of 5.7 ± 0.33 and 5.5 ± 0.78 polyps per juvenile was observed after two months at 20 m and 40 m, respectively (Student's t-test, t = -0.209, df = 53, P = 0.835). Mean geometric diameter (± SE) of juveniles at 20 and 40 m frames was 1.52 ± 0.04 and 1.44 ± 0.06 mm, respectively, with no significant difference observed (Student's t-test, t = -0.911, df = 53, P = 0.366, Supplementary Fig. 3).
Similarly, in 2016, the number of polyps in juveniles increased in both exposed and shaded orientations at all depths (Figs. 4,5). After two months, the shaded juveniles at 20 m (mean ± SE of 4.7 ± 0.46 polyps per juvenile) and the exposed juveniles at 40 m (mean ± SE of 4.6 ± 0.40 polyps per juvenile) had a significantly greater number of polyps per juvenile than the juveniles at 40 m in a shaded orientation (mean ± SE of 2.2 ± 0.20 polyps per juvenile) (Kruskal-Wallis followed by Dunn tests, Chi-squared = 17.92, df = 2, P < 0.001). The shaded juveniles at 20 m had a significantly larger mean geometric diameter (1.40 mm) compared to the 40 m juveniles in exposed (1.24 mm) and shaded orientations (1.23 mm) (Kruskal-Wallis followed by Dunn tests, Chi-squared = 7.43, df = 2, P = 0.020).
Algal density, chlorophyll a and c 2 per cell and surface area, and chlorophyll ratio (a:c 2 ) were similar for juveniles at 20 and 40 m in 2015 ( Fig. 6c-f, Supplementary Table 2). In 2016, symbiont density in the shaded juveniles at 20 m and exposed juveniles at 40 m was 1.4 and 2.6 × 10 5 cells cm −2 , respectively. Concentrations of chlorophyll a and c 2 per cell were 31.0 and 12.5 pg cell −1 , respectively, for those shaded at 20 m, while those www.nature.com/scientificreports/ exposed at 40 m had 24.7 and 8.4 pg cell −1 , respectively (Fig. 6d). An insufficient number of surviving replicates in 2016 prevented statistical comparisons.

Discussion
Our results provide several insights into the potential recovery of S. hystrix in shallow reefs by means of larvae released from colonies living at mesophotic depths. In our laboratory-based experiments, we observed most larvae rapidly crawling at the bottom of the acrylic columns used, settling within 24 h; suggesting most S. hystrix larvae from mesophotic colonies settle close to their parent colonies at mesophotic depths. This behavior is consistent with previous observations on this species 9,27 . However, our results also suggest some larvae could disperse far from their natal reefs since up to 16% of the larvae remained in the water column or at the surface (Supplementary Fig. 1), and up to 9.7% of the larvae kept swimming four days after release (Fig. 2). This suggests that a non-negligible portion of S. hystrix larvae from mesophotic depth may swim vertically or are passively transported by currents in the water column to find a suitable place to settle further away. The upward swimming behavior of mesophotic coral larvae and their position in the water column could partly contribute to vertical larval dispersal to shallow reefs. In the present study, since the upward swimming speed of S. hystrix larvae from mesophotic depth was 0.6 mm s −1 , in theory, larvae could reach the surface from 40 m depth after 18 h. This lies within the timeframe of larval settlement competency periods. However, the swimming speed of coral larvae is much slower than horizontal currents in the reefs 28 . Larval dispersal distance is primarily determined by the larval competency period, their position in the water column and the coincident water currents [29][30][31] . The longer larvae stay in the water column, the more likely they will disperse. In the case of mesophotic larvae, water movement will also affect their vertical migration. For example, off North Carolina's coast, upwelling influenced the shoreward migration of larval invertebrates and fish 32 . No information is www.nature.com/scientificreports/  www.nature.com/scientificreports/ available on upwelling around Okinawa during the coral reproductive season. However, at the time of larval release, typhoons could create enough vertical water movement to potentially transport S. hystrix larvae from mesophotic depths to shallow reefs, although the frequency and paths of strong storms vary across years 9,33 . This stochastic connectivity may explain the absence of genetic partitioning within the water column for S. hystrix in Okinawa 26 . Future studies on current patterns during spawning/larval release are necessary to understand larval dispersal processes from mesophotic reefs. Mesophotic larvae that are dispersed to shallower areas of the reef face several challenges to their survival. The laboratory experiments showed that settlement rates of S. hystrix larvae from mesophotic colonies were reduced when exposed to light conditions corresponding to depths shallower than 20 m (i.e., 10 and 5 m) (Fig. 2). This supports previous findings where the larvae of shallow corals preferred to settle in similar light conditions as parental colonies 34,35 . In addition, most of the pre-and post-settled larvae partially or completely bleached under light conditions representing depths shallower than 20 m ( Supplementary Fig. 2). The vertical transmission of algal symbionts into larvae from mesophotic corals like S. hystrix might be unfavorable for larvae dispersed to shallower water since the higher light conditions increased DNA damage in the symbiont algae 36 . Likewise, excess algal symbionts increases the susceptibility of adult corals to bleaching 37 . Therefore, in shallow reefs, settlement of larvae from mesophotic corals may be limited to shaded microhabitats such as steep spurs or overhangs. However, it is essential to note that light conditions cannot be solely interpreted as light intensity alone due to differences in the light spectrum used in our experiments; hence, further investigation into the independent effect of light quantity and quality is required.
In addition to high light stress, S. hystrix larvae from mesophotic depth will likely be exposed to thermal stress when dispersing to shallow reefs. In 2016, many corals bleached between 0 to 20 m depth in Okinawa 38,39 (pers. Obs.), where high (> 3 °C) temperature differences between shallow and mesophotic depths occurred for the majority of the planula release period. Elevated temperatures (> 3 °C above average seasonal temperature) can lower larval survival and reduce dispersal 40 . In the case of S. hystrix from mesophotic depths in Okinawa, high temperature discrepancy between shallow and mesophotic depths during thermal stress events will likely reduce settlement success in shallow reefs.
While laboratory experiments on larvae focused on light stress, field experiments on juveniles combined light and thermal stresses. The overall survival of juveniles significantly increased with depth, and those in a shaded orientation showed higher survival than juveniles in exposed orientations (Supplementary Table 1). As observed for the larvae in laboratory experiments, the high light intensity may cause stress on juveniles at 3-5 and 20 m depths in exposed orientation (light intensity was ~ 12 and ~ 2 fold higher than 40 m depth, respectively). Similarly, for adult corals, most of the low light-adapted corals transplanted to high light environments showed bleaching 41 and high mortality 42,43 (but see cases for the S. pistillata 15 and F. paradivisa 16 for contrasting responses). www.nature.com/scientificreports/ The survival of juveniles from mesophotic depth in shallower reefs was also affected by substrate orientation. In the 2016 field experiments, in shallower reefs (i.e., 3-5 and 20 m depths), most juveniles survived when in a shaded orientation (Fig. 3), i.e. in low light environments created by crevices and overhangs. These observations support previous studies showing the frequent occurrence of juveniles on shaded or vertical surfaces in shallow reefs 44,45 . Such surfaces also provide protection from sediment accumulation 46 and fish grazing 47 . Conversely, almost all juveniles at 3-5 m and those at 20 m in an exposed orientation died within the first month of transplantation (Fig. 3). This mortality corresponds with exceptional thermal stress. Indeed, around Sesoko Island, sea surface temperature in 2016 was the second-highest in the last three decades after the 1998 bleaching event 39 . Since mortality in adult corals has been attributed to thermal and high light stresses 48  Surprisingly, the coral juveniles that survived at 20 m depth showed significantly increased growth rate at 20 m, or remained relatively similar, to those at 40 m, both at the exposed and shaded orientation ( Fig. 4; Supplementary Fig. 3). A similar result has been reported previously, where juveniles of Stylophora kuehlmanni Sheer and Pillai 1983 were almost twice as large at 5 m as those at their natural depth of 45 m 49 . Likewise, adult colonies of S. hystrix (Pers. Obs.), S. pistillata 15 , and Orbicella franksi (Gregory 1895) 50 grew significantly faster at shallow reefs (< 20 m) than those at MCEs. In these cases, higher light intensity in the shallower reefs may have enhanced calcification in corals by light activation 51 . However, this is unlikely to have occurred in our study since a significant increase in growth rate was only found at the 20 m shaded orientation with extremely low light intensity (~ 18 fold lower than 40 m exposed orientation). A possible explanation is that warmer seawater temperature (~ 0.5 °C warmer at 20 m than at 40 m) during the first two months of juvenile transplant experiments enhanced juvenile growth 52,53 . The juvenile growth rates observed in our study indicate that the intermediate depth of 20 m is adequate for the successful recruitment of S. hystrix from mesophotic depth.
Photoacclimation responses are also likely to play an essential role in juvenile survival in shallow reef environments. Here, the response of the algal symbiont to the higher light conditions can be seen through the decrease in maximum quantum yield, Fv/Fm (Fig. 6a). It should be noted that measurements of Fv/Fm were performed in the laboratory and, as such, changes in seawater temperature during the transfer from the field sites could have affected the results. To minimize this, samples were carefully transferred under dark conditions and immediately www.nature.com/scientificreports/ measured upon arrival to the laboratory. Minor variations were observed between samples (Fig. 6a), likely due to slight differences in light intensity between 20 and 40 m depth at the time of measurement (the light intensity differences between 20 and 40 m was ~ 37 µmol photon m −2 s −1 ), however the seawater temperature was similar at both depths. The differences in light intensity between 20 and 40 m depths may also be responsible for similar variations in the other indicators measured (algal density and chlorophyll concentrations). Other studies have also reported a decrease in Fv/Fm as one of the photoacclimatory processes of MCEs adult colonies of S. pistillata (from ~ 0.67 at 30 m to ~ 0.64 at 3 m) and F. paradivisa (from 0.66 at 50 m to 0.49 at 5 m) when transplanted to shallower depths 15,17 . A decrease in maximum quantum yield under high light conditions reflects potential damage to photosystem II or adaptation to reduce photo-oxidative damage to the photosynthetic apparatus in the symbiotic algae within corals 54 . Thus, adjustment of maximum quantum yield, Fv/Fm, in the symbiont can be considered a strategy for coral juveniles from mesophotic depth to acclimate to different light environments. Green fluorescent proteins (GFPs) in corals have been suggested to play a role in photoprotective mechanism 55 , avoidance from predators 56 , and prey attraction 57 . While no study on corals from mesophotic depths has investigated fluorescent proteins in juveniles, a few studies focused on adults [58][59][60][61] . However, no specific conclusion could be drawn regarding the potential role of fluorescent proteins in mesophotic corals even though ~ 70% of corals fluoresced over the entire part of the corals observed 60 . In the Red Sea, mesophotic Galaxea fascicularis (Linnaeus 1767) from mesophotic depth increased its GFPs when exposed to light representing 3 and 20 m depth, suggesting a photoprotective function of GFPs 59 . In the present study, the juveniles at both 40 and 20 m (exposed and shaded orientation) had GFP with similar fluorescent characteristics (see ESM). Therefore, GFP for juveniles in a low light environment is likely to have other roles than photoprotection. Further studies are needed to quantify the intensity of coral fluorescence at mesophotic depth, investigating the role of fluorescent proteins as the coral's defense mechanism at high light intensity during acclimation to shallow reefs.
In terms of recolonization of shallow reefs, our results showed that a small portion (up to 16%) of S. hystrix larvae from mesophotic colonies might disperse to shallower reef habitats. A shorter reproductive season and smaller planula size compared to their shallow counterparts 9 also supports limited dispersal. Moreover, as light conditions at shallower depths impede direct recolonization of coral larvae from mesophotic depth, rugosity or tridimensional complexity of the shallow reef will play an essential role for mesophotic larvae by providing suitable shaded habitats. Around our study site at intermediate depth (~ 20 m), in 2015 and 2016 a few small colonies of S. hystrix were observed, and more recently, the occurrence of Seriatopora colonies at 20 m and 10 m appears to be increasing (pers. obs.). In 2021, a single, well-developed colony at 4.8 m was observed within the field experiment area (pers. obs.). No evidence yet whether those new colonies at a shallower depth originated from settlement of larvae from mesophotic colonies. Our results, and the absence of genetic structure related to depth between shallow and mesophotic Seriatopora in the region 26 , suggest that 20 m depth may act as a stepping stone to connect mesophotic corals to shallow reefs. We suggest that recolonization from mesophotic depths to shallow reefs occurs through multigenerational recruitment over a long-term period. However, anthropogenic stressors exacerbating coral reefs' degradation 62 will limit the potential of mesophotic corals to reseed shallow reefs. Indeed, S. hystrix juveniles from mesophotic depth transplanted to shallower depths during the thermal stress event of 2016 suffered high mortality, even at 20 m. If such events occur more frequently in the future 63 , they may reduce the stepping stone capacity of 20 m reef habitats. Given the ecological importance of mesophotic corals, the origin of shallow water colonies and the process for recolonization of these habitats deserves further investigation. To fully understand the contribution of MCEs to shallow reef recovery, future studies should include a range of corals with differing spawning mechanisms and agal transmission modes.

Methods
Study sites, coral collection, and environmental measurements. Six to ten mature colonies  Table 3). Each colony was maintained in indoor seawater systems at the Sesoko Station of the University of the Ryukyus (described in 9 ). Seriatopora hystrix is a brooder whose larvae contain symbiotic algae when released (vertical transmission) 27 and, in Okinawan mesophotic reefs, S. hystrix release larvae monthly from May to August 9 . The larvae released during the peak planula release period 9 were used for larval behavior and settlement experiments ex situ and juvenile acclimation experiments in situ. They were kept in filtered seawater (0.2 µm) until the experiments to avoid the presence of larvae and symbiotic algae from other species coming through the seawater supply and keep better water quality. In situ juvenile acclimation experiments were conducted at three sites: at the MCE site (40 m; where the original adult parent colonies originated) and at two shallower sites (3-5 m and 20 m, within 750 m from the MCE site; Supplementary Fig. 4). Seawater temperatures and light intensity were measured hourly at each site using loggers (HOBO Pendant/Light Data Logger, Onset Computer Corporation, USA).

Effect of different light conditions on larval behavior and settlement (laboratory experiment).
Fifty to a hundred larvae colony −1 day −1 were released on 18-20 July 2016 (5 colonies). They were all pooled in a 10 L tank filled with filtered seawater daily. Larvae were used in the following two experiments within 6 h of release. To examine the larval position in the water column, ten larvae were exposed to light conditions representing environments at 40 m, 20 m, 10 m, and 5 m depths (i.e., 50-60, 250, 450 and 600 µmol quanta m −2 s −1 , respectively) in 80-cm-tall acrylic columns using LED lights (Hydra 52, C2 Development Inc., USA) (Supplementary Table 4 www.nature.com/scientificreports/ 2 min in each light condition (n = 3, 7, 7, and 8 larvae in total in 5, 10, 20, and 40 m light conditions, respectively). The tracks were traced to transparent plastic sheets on the side of the acrylic column using a marker. To examine larval settlement and survival, 30 newly released planulae were transferred to 700 ml plastic containers. Plastic settlement plates (circular shape, diameter: 6 cm, circle polyethylene V-type container V-1, AS ONE, Japan) were placed in each container since S. hystrix larvae prefer to settle on plastic 9 . The containers were exposed to 13 h:11 h (light:dark) photoperiods under the light environment at 40 m, 20 m, 10 m, and 5 m depths, see above). Six replicates were performed in each light condition. The larvae were counted over four days and classified as (i) settled, (ii) crawling/swimming, or (iii) dead. Pre-and post-settled larval conditions were monitored as healthy or bleached (Supplementary Fig. 2). Seawater temperature was kept at 27 ± 1 °C (i.e., the temperature at 40 m) and was replaced twice a day (i.e., 8:00-10:00 and 18:00-20:00) with 50-60% FSW.
Juvenile acclimation to different depths (field experiment). Hundreds of larvae per colony released on 27 July-6 August 2015 (8 colonies) and 18-28 July 2016 (9 colonies) were pooled and kept in a 10 L filtered seawater tank. The plastic settlement plates (same as above) were then placed in the 10 L tank to facilitate settlement. A total of 477 and 181 planulae settled on 29 and 46 settlement plates in 2015 and 2016, respectively (ranging between 1 and 50 planulae per plate). The location of juveniles on the plates was mapped under a dissecting microscope. In both years, plates with 1-week-old juveniles were fixed horizontally to the top of rectangular PVC frames and deployed in August at three depths (3)(4)(5)20, and 40 m sites). In 2015, n = 146, 163, and 168 juveniles on the plates were distributed at 3-5, 20, and 40 m sites, respectively, and all plates were placed upward on the frames exposed to direct sunlight (hereafter, this position is referred to as exposed orientation). In 2016, the plates were placed upward and downward (hereafter referred to as shaded orientation) on the frames (Supplementary Fig. 5). The plates hosted between 28 and 32 juveniles at each depth and orientation.

Survival and growth of juveniles.
Monthly observations were performed to examine juvenile survival and growth in 2015 and 2016. The juveniles were carefully transported to Sesoko Station (in the dark, covered by shade cloth) and maintained under their respective depths' light conditions. Juvenile survival was examined as either alive or dead based on their color and the presence of coral tissue under a dissecting microscope. The number of polyps and geometric diameter were measured under a dissecting microscope to examine juvenile growth. In 2015, 291 out of 477 juveniles were selected for growth measurements. In 2016, all the juveniles were measured. After the observations (within two days), the juveniles were returned to the originally transplanted depths.
Maximum quantum yield, algal density, chlorophyll pigments of juveniles. At the end of the experiment in both years (February 2015 and 2016), the juveniles were transferred under dark conditions to the laboratory to measure the maximum quantum yield of the symbiotic algae using a pulse-amplitude modulated chlorophyll fluorometer (Diving-PAM, Walz, Germany). A total of ten juveniles (5 each for 20 m and 40 m exposed orientation; 2015) and six juveniles (4 for 20 m shaded orientation; 2 for 40 m exposed orientation; 2016) were dark-adapted for 30 min before maximum quantum yield (Fv/Fm) and maximum relative electron transport rate (rETRmax) measurements (Supplementary Materials and Methods). Soft tissues of each juvenile were then removed using an airbrush. The tissues were then extracted for algal density, chlorophyll pigments (described in 58  Statistical analyses. Before analyses, the statistical assumptions were verified with Shapiro-Wilk (normality) and Levene's (homogeneity) tests and transformed if necessary (log, inverse sine, and square root transformation). All statistical analyses were conducted using SPSS (version 11.5).
For laboratory experiments, one-way ANOVA tests were performed to examine differences in larval swimming speeds across light conditions (40, 20, 10, and 5 m) for each downward (n = 9, 9, 12, and 4 measurements, respectively) and upward direction (n = 3, 3, 3, and 2 measurements, respectively). A one-way ANOVA, followed by Bonferroni post hoc tests, was performed to test for significant differences in larval settlement rate after 96 h under different light conditions (40, 20, 10, and 5 m light conditions); the container was the experimental unit (n = 6), the light condition was considered as a fixed factor.
For the field experiments, survival rates of juveniles were estimated using Kaplan-Meier (K-M) survival analysis. Each juvenile was assumed to be independent of the other. Mantel-cox log-rank tests were compared the estimated K-M survival curves among depths in 2015 and depths and orientations in 2016. Pairwise comparisons of Mantel-cox log-rank tests were used to quantify differences in survival curves for a given year. Student's t-tests were used to detect the significance of the number of polyps and geometric diameter between depths (20 m, n = 44; 40 m, n = 11) at two months in 2015. In 2016, a Kruskal-Wallis test, followed by Dunn post hoc tests, was used to detect significant differences between depths and orientation (20 m shaded orientation, n = 17; 40 m exposed, n = 10; and 40 m shaded, n = 14). Statistical analyses for growth in both years were only performed during the first two months of transplantation due to an insufficient number of surviving juveniles beyond these periods. Welch's t-tests were used to examine significance between depths (20 and 40 m; both n = 5) in 2015 on maximum quantum yield (Fv/Fm and rETRmax) and chlorophyll (a and c 2 ) per surface area and per cell. A Mann-Whitney U test examined the significance of chlorophyll (a:c 2 ) ratio between depths (20 and 40 m; both n = 5).

Data availability
All data needed to evaluate the conclusions are present in the paper and/or the Supplementary Materials. The raw data analyzed in this study are available from the corresponding author on request.