Role of C₄ carbon fixation in Ulva prolifera, the macroalga responsible for the world’s largest green tides

Abstract

Most marine algae preferentially assimilate CO₂ via the Calvin-Benson Cycle (C₃) and catalyze HCO₃⁻ dehydration via carbonic anhydrase (CA) as a CO₂-compensatory mechanism, but certain species utilize the Hatch-Slack Cycle (C₄) to enhance photosynthesis. The occurrence and importance of the C₄ pathway remains uncertain, however. Here, we demonstrate that carbon fixation in Ulva prolifera, a species responsible for massive green tides, involves a combination of C₃ and C₄ pathways_, and a CA-supported HCO₃⁻ mechanism. Analysis of CA and key C₃ and C₄ enzymes, and subsequent analysis of δ¹³C photosynthetic products showed that the species assimilates CO₂ predominately via the C₃ pathway, uses HCO₃⁻ via the CA mechanism at low CO₂ levels, and takes advantage of high irradiance using the C₄ pathway. This active and multi-faceted carbon acquisition strategy is advantageous for the formation of massive blooms, as thick floating mats are subject to intense surface irradiance and CO₂ limitation.

Introduction

The Calvin–Benson cycle (C₃) is the dominant pathway of carbon fixation in marine algae¹. Rubisco (ribulose-1, 5-bisphosphate carboxylase), a key C₃ enzyme responsible for carbon fixation, requires inorganic carbon in the form of CO₂². However, the demand for CO₂ in algal photosynthesis is generally higher than CO₂ concentrations in natural seawaters, e.g., the half-saturation constants for CO₂ of Rubisco in diatoms are 30–60 μM³ but CO₂ concentrations in natural seawater are only 5–25 μM⁴. Thus, CO₂ can be an important factor limiting algal proliferation in the ocean.

Since the 1970s there is growing evidence that most species of prokaryotic and eukaryotic algae have developed CO₂-concentrating mechanisms (CCMs) that enable accumulation of CO₂ via bicarbonate (HCO₃⁻) enzymolysis^3,5. A dominant route in the CCMs is that intra- or extracellular dehydration of HCO₃⁻ is catalyzed by carbonic anhydrases (CA) to release CO₂ to increase reactions at the Rubisco site (Fig. 1a). Although traditionally associated with more advanced terrestrial plants, in recent decades a C₄ or C₄-like pathway has been discovered in the green alga Udotea flabellum⁶ and the marine diatom Thalassiosira weissflogii^7,8, in which transmembrane HCO₃⁻ is not only catalyzed via CA to generate CO₂ but also involves C₄ enzymes—phosphoenolpyruvate carboxylase (PEPCase) and PEPCase kinase (PEPCKase). CO₂ incorporated in this manner eventually enters the C₃ cycle to increase reactions at the Rubisco site (Fig. 1b). More recently, a freshwater macrophyte Ottelia alismoides, a constitutive C₄ plant and bicarbonate user, was shown to possess three different CCMs that can operate with the C₄ pathway in the same tissue, even though Kranz anatomy is absent^9,10. Theoretically, the joint operation of CCMs and the C₄ pathway can greatly improve carboxylation efficiency of algal species in the use of HCO₃⁻, and consequently enhance CO₂ accumulation at the Rubisco site (Fig. 1b).

Fig. 1: Schematics of two carbon acquisition strategies in marine algae.

a Transmembrane HCO₃⁻ is catalyzed by carbonic anhydrase (CA). b Transmembrane HCO₃⁻ is catalyzed by CA and the C₄ pathway (RuBP 1,2-ribulose diphosphate, 3-PGA 3-phosphoglyceric acid, pCA periplasmic (extra-cellular) CA, iCA intra-cellular CA, PEPCase phosphoenopyruvate carboxylase, PEPCKase phosphoenolpyruvate carboxylase kinase, PPDKase pyruvate orthophosphate dikinase, OAA oxaloacetic acid, PEP phosphoenolpyruvic acid, PYR pyruvic acid).

Ulva prolifera, the main species involved in the massive “green tides” in the Yellow Sea¹¹, exhibits remarkable capability for biomass accumulation. U. prolifera biomass increases rapidly—more than 60-fold within ~50 days^12,13. Growth rates in the field were generally higher than 28% per day at temperatures greater than 20 °C¹⁴, and aerial cover of floating canopies exceed 30,000 km² across the Yellow Sea. Consistent with this, the involvement of the C₄ pathway in photosynthesis of U. prolifera has been suggested as an important mechanism to achieve such rapid biomass accumulation, based on two lines of evidence: (1) gene and enzyme analysis in U. prolifera revealed the existence and activity of the C₄-related enzyme pyruvate orthophosphate dikinase (PPDKase)¹⁵; and (2) tissue δ¹³C range of U. prolifera (−21.9 to −14.9‰) at 16 stations in the Yellow Sea indicated a mix of C₃ and C₄ pathways in carbon fixation¹⁶.

These two lines of evidence, however, are not sufficient to characterize a full C₄ pathway in U. prolifera. That pathway requires the participation of the key C₄ enzymes, PEPCase and PEPCKase. PEPCase (in the cytoplasm) supports catalysis of carboxylation of phosphoenolpyruvic acid (PEP), which uses HCO₃⁻ as the inorganic carbon substrate leading to C₄ compound synthesis. PEPCKase (in the chloroplast) is a decarboxylase, generating CO₂ and insuring efficient transfer of CO₂ to Rubisco¹⁷. PPDKase is responsible for catalyzing the regeneration of PEP in the cytoplasm, but it is not the only way for the C₄ pathway to acquire PEP¹⁷. Some researchers even believe that PPDKase might not assist with net CO₂ fixation but rather has a role in protection against photoinhibition¹⁸. Therefore, examining the activities of PEPCase and PEPCKase is a necessary step to confirm the existence of C₄ pathway in U. prolifera.

The ¹³C/¹²C distributions in plant tissue records the integrated pattern of photosynthetic carbon acquisition^19,20; for example, high CO₂ uptake leads to low δ¹³C values (e.g., <−30‰²¹), whereas high HCO₃⁻ uptake gives high δ¹³C values (e.g., >−10‰²²). Therefore, tissue δ¹³C is an important index using to distinguish C₃ and C₄ activity. The ¹³C/¹²C values in seaweeds, however, often display a wide range that makes definition of the C₄ contribution uncertain^20,21. The variation in the ratios depends on ambient temperature, light, salinity, nutrients and CO₂ concentrations in seawater^20,22. Growth and respiration in seaweeds^20,23 can also lead to discrimination and fractionation of ¹³C/¹²C. As canopies of U. prolifera drift in the Yellow Sea, environmental conditions and physiological activity change, forcing variations that may mask clear evidence for C₄ activity.

To resolve this uncertainty, controlled experiments are needed to examine the correlation between the activities of key enzymes and photosynthetic products to ascertain the activity of C₄ pathway and/or CA mechanism in U. prolifera. Although several environmental factors (e.g., temperature, light, salinity, HCO₃⁻ and CO₂ supply, and nutrient availability) may affect the functional expression and activity of CA mechanism and C₄ pathway, light intensity and pCO₂ are regarded as the most important two under the condition with sufficient nutrient supply^3,5,24. Massive floating algal mats in nutrient enriched Yellow Sea are not only exposed to strong surface light, but the thick biomass also can reduce the dissolution of CO₂ from the air and lead to CO₂ limitation. Consequently, the HCO₃⁻ systems operated by CA mechanism and/or C₄ pathway would likely become active.

Here, we describe the results of three outdoor culture experiments designed to examine the daily variations of key C₃ (Rubisco), CA (extra- and intra-cellular CA) and C₄-metabolic enzymes (PEPCase, PEPCKase, and PPDKase) in U. prolifera. The relationships between the activities of major enzymes and photosynthetic products were analyzed via the corresponding variations in tissue δ¹³C, aiming to identify the participation of C₃ and C₄ photosynthetic pathways and CA mechanism in U. prolifera. The results exhibited the coexistence of C₃ and C₄ pathways and a CA-supported HCO₃⁻ mechanism in U. prolifera. The correlated variations of light intensity and pCO₂ with enzyme activity indicated that the C₄ pathway was most active under high light but that the CA mechanism became active at low CO₂ levels. The joint operation of the C₄ pathway and a CA-supported HCO₃⁻ mechanism in U. prolifera greatly improved efficiency of inorganic carbon fixation and illustrated why massive biomass accumulation can be formed in a short period, when thick floating mats are subject to intense surface irradiance and CO₂ limitation in the Yellow Sea.

Results

The response of key C₃ and C₄ enzymes to diurnal sunlight variations

The first two experiments showed that the activity of key C₃ and C₄ enzymes were much higher on a sunny day (experiment 1, Fig. 2) than on a cloudy day (experiment 2, Fig. 2). The patterns of C₃ and C₄ enzymes differed in response to variations in diurnal sunlight (Fig. 2): mean Rubisco activity was maximal in the morning (10:00 h) but declined significantly from 274 to 57 nmol · min⁻¹ · g · fresh weight⁻¹ at noon (12:00) under high light intensity (Tukey HSD = 5.327, crit. = 3.541, p = 0.001), and stayed low activity between 12:00 and 14:00 h, but increased significantly again from 42 to 143 nmol · min⁻¹ · g · fresh weight⁻¹ (Tukey HSD = 4.002, crit. = 3.541, p = 0.019) between 14:00 and 16:00 under reduced light intensity (Fig. 2a).

Fig. 2: Diurnal patterns of key C3 and C4 enzymes in U. prolifera, corresponding to variations in light intensity.

a The pattern of C₃ enzyme (Rubisco) on sunny (experiment 1) and cloudy (experiment 2) days. b–d The pattern of C₄ enzymes on sunny (experiment 1) and cloudy (experiment 2) days. Each data bar is the mean of three measurements (black dots in each data bar are individual data points from each culture container) and error bars are ±1 standard deviation from the mean. Results of two-way analyses of variance comparing sunny and cloudy days were as follows: Rubisco comparison (all times excluding 18:00), light condition (cloudy/sunny) F(1,20) = 33.99, p < 0.0001; time F(4,20) = 8.43, p = 0.0003; light × time interaction F(4,20) = 6.25, p = 0.002. PEPCase comparison (all times excluding 18:00), light condition F(1,20) = 32.74, p < 0.0001; time F(4,20) = 18.38, p < 0.0001; light × time F(4,20) = 10.64, p < 0.0001. PEPCKase comparison (all times), light condition F(1,20) = 152.08, p < 0.0001; time F(5,20) = 5.56, p = 0.002; light × time F(5,20) = 2.48, p = 0.067. See “Methods” for explanation of comparisons made and any transformations used.

In contrast, PEPCase and PEPCKase activities reached maxima at noon, the time of peak irradiation (Fig. 2b, c). PEPCKase activity was significantly higher on the sunny day than on the cloudy day across all time periods from 08:00 to 18:00 (ANOVA, F(1,20) = 152.08, p < 0.0001, Fig. 2c). PEPCase activity was significantly higher on the sunny day than on the cloudy day at three of the five time periods compared, 08:00, 10:00, and 16:00 (Tukey HSD = 3.634, 5.291, 4.253, respectively, crit. = 3.541, p = 0.041, 0.001, and 0.011, respectively, Fig. 2b). PPDKase to catalyze the regeneration of PEP in the C₄ pathway was only detected on sunny days (Fig. 2d). Regression analysis of enzyme activity against light (Fig. 3) confirm that high activity of C₄ enzymes (PEPCase [R² = 0.544, p = 0.006] and PEPCKase [χ² transformed, R² = 0.651, p = 0.002]) was induced under high irradiance. Rubisco (R² = 0.244, p = 0.102) did not display a linear relationship with light (Fig. 3). This is consistent with the results of the ANOVA above.

Fig. 3: Relationship between irradiance and enzyme activities for Rubisco, PEPCase, and PEPCKase.

Means of three measurements (one from each culture container) of enzyme activity for each of 6 time periods in both sunny (experiment 1) and cloudy (experiment 2) days. Equations for regression lines shown are based on the plotted raw data (means: big color dots; individual data points: small color dots). R² and p values for PEPCKase are for the χ² transformed data as reported in the text. The R² and p value for the raw data were 0.6730 and 0.001, respectively.

Relationships between enzyme activities and carbon fixation

The third experiment was conducted on a sunny day, aiming to identify the contribution of CO₂ and HCO₃⁻ in carbon fixation. The activities of key C₃ enzyme (Rubisco), C₄ enzymes (PEPCase, PEPCKase, and PPDKase), and CA enzymes (extra- and intra-cellular CA) and their responses to varying light levels were measured over the course of the day (Fig. 4). Similarly, the variations of pCO₂, HCO₃⁻, and tissue δ¹³C were also measured (Fig. 5). The intent of this trial was to examine variations in key enzymes that represent the three photosynthetic routes, in relation to variations in photosynthetic products (tissue δ¹³C).

1. (1)

   Maximal Rubisco activity again occurred in the morning (Fig. 4a), along with rapidly decreased pCO₂ (Fig. 5a), and lowered tissue δ¹³C (Fig. 5b). Photosynthesis during the morning was therefore dominated by a C₃ pathway supported by sufficient pCO₂ source.

2. (2)

   PEPCase and PEPCKase activities peaked at noon (Fig. 4b). From 10:00 to 12:00 as irradiance increased, tissue δ¹³C increased 10‰ (Fig. 5b), suggesting a link between C₄ pathway and carbon fixation using HCO₃⁻. The activity of PEPCase and PEPCKase and tissue δ¹³C declined markedly at 2 p.m. (Fig. 4b), likely a result of decreased light intensity (Fig. 5b), consistent with the results from experiments 1 and 2, indicating the importance of strong light induction for C₄ pathway occurrence, rather than low pCO₂.

3. (3)

   Intra-cellular CA became more active in the afternoon (Fig. 4c) when pCO₂ was below 150 μatm (Fig. 5a). Throughout the experiment, the value of tissue δ¹³C kept increasing after 2 p.m. (Fig. 5b), although the activities of PEPCase and PEPCKase declined markedly (Fig. 4b). Intracellular CA activity was negatively correlated to both pCO₂ (R² = 0.773, p = 0.049) and HCO₃⁻ concentration (R² = 0.717, p = 0.070), a result that indicated a CA-dominant photosynthetic pathway late in the day when pCO₂ decreased. In contrast, extracellular CA was not active and remained unchanged during the experiment (Fig. 5b), indicating the species mainly used the diffusion of HCO₃⁻ in cytosol via intracellular CA (Fig. 1b).

Fig. 4: Diurnal patterns of C3 and C4 enzymes and CA in response to sunlight variations.

a Diurnal pattern of C₃ enzyme (Rubisco). b Diurnal patterns of C₄ enzyme (PEPCase, PEPCKase, and PPDKase). c Diurnal patterns of CA (extracellular and cellular CA). They indicate the activities of C₃ and C₄ pathways and CA mechanism, respectively, in response to diurnal sunlight variations. Each data bar is the mean of three measurements (one from each culture container) and error bars are ±1 standard deviation from the mean; black dots in each data bar are individual data points from each culture container.

Fig. 5: Diurnal variations of pCO2 and HCO3⁻ concentrations and tissue δ¹³C.

a Diurnal variations of pCO₂ and HCO₃⁻ concentrations in container seawater. b Diurnal variations in tissue δ¹³C in U. prolifera. Each data point is the mean of three measurements from experiment 3, and the error bars are ±1 standard deviation from the mean (small black and orange dots in each error bar are individual data points from each culture container). Note that the decline in δ¹³C between 08:00 and 10:00 indicates C₃ dominance, and thereafter, the decrease in δ¹³C is indicative of C₄ dominance as pCO₂ declines below 200 μatm. Similarly, the decline δ¹³C at 14:00 is associated with an increase in Rubisco (see Fig. 2a).

These results suggest that U. prolifera used a HCO₃⁻ source via a combination of C₄ pathways and the CA mechanism in response to changes in irradiation intensity and CO₂ level.

Discussion

The results of this study not only demonstrated the coexistence of C₃ and C₄ pathways and the CA mechanism in U. prolifera but also indicated that the C₄ pathway catalyzed by PEPCase and PEPCKase were most active in U. prolifera photosynthesis under high light. In this regard, the photosynthetic machinery of U. prolifera could be similar to that previously described for the green alga U. flabellum⁶ and the marine diatom T. weissflogii⁸. The CO₂ delivered to the Rubisco site comes from three sources: the available CO₂ from seawater, HCO₃⁻ catalyzed by the CA mechanism, and HCO₃⁻ catalyzed by PEPCase and PEPCKase via the C₄ pathway (Fig. 1b). The joint operation of the C₄ pathway and the CA mechanism greatly improve efficiency of inorganic carbon fixation in U. prolifera, and consequently, accelerate the rate of biomass accumulation (Fig. 1b). This multifaceted photosynthetic mechanism has important implications for the ability of this species to grow rapidly when there is high irradiance, and facilitates the formation of the massive floating green tide mats observed in the Yellow Sea¹³.

Studies of the C₄ pathway in marine algal photosynthesis are very limited, but the results from a few species indicate that the occurrence of a C₄ pathway and its importance in carbon fixation have distinct species-specific expression. For example, inhibition of PEPCase or PEPCKase could reduce more than 90% of photosynthesis in T. weissflogii⁸ and ~50% of photosynthesis in U. flabellum⁶. In this study, the range of tissue δ¹³C (−19.1 to −17.4‰) implied an important contribution of HCO₃⁻ in carbon fixation in U. prolifera. We cannot specifically define the contribution of HCO₃⁻ fixed separately via the CA mechanism versus the C₄ pathway, but we found that the environmental factors inducing the activity of C₄ enzymes are different from the CA mechanism. The diurnal modalities of C₄ enzymes among the three experiments were consistent, although their concentrations were different depending on the ambient environmental conditions at the time of those experiments (Figs. 4 and 5). The repeated modes indicate that the highest PEPCKase activity occurred at maximal light (Figs. 2c and 4b); PEPCKase has a direct correlation with C₄ acid formation⁶. Previous studies on the diatom T. pseudonana also found that light intensity is more important for the C₄ acid accumulation than low pCO₂ concentrations^25,26. In this study, tissue δ¹³C showed a marked increase (10‰) at noon, indicating photosynthesis supported by HCO₃⁻ (Fig. 5) and that the process is operated by C₄ pathway rather than C₃ pathway and CA mechanism (Fig. 4). In contrast, HCO₃⁻ and CO₂ supply play important roles in modulating activity of C₃ pathway and CA mechanism²⁷. High CO₂ generally suppresses expression of a high-affinity CCM state²⁸, a feature reflected in our result that the C₃ pathway was active at high pCO₂ concentrations but that the CA mechanism became dominant when pCO₂ was low (Figs. 4 and 5a).

HCO₃⁻ transport rate and C₄ activity are energetically costly and require high photon flux densities and sufficient nutrient supply^29,30 to support synthesis of specific proteins. Excess light energy under strong irradiation however enables ATP to accumulate in the cells and leads to photoinhibition. An active C₄ pathway at noon indicates that U. prolifera has an efficient capability to dissipate excess light energy and ATP in cells. Photosystems I and II (PSI and PSII) are light-harvesting operators, and the energy flux they capture will be quenched and redistributed between PSII/PSI to achieve a balance and avoid irreversible damage to the photosynthetic systems³¹. An induction experiment with U. prolifera showed that the electron transport rate (ETR) between PSII/PSI was still high when light intensity reached 800 µmol photons m⁻² s^{−1 32}. Xu and Gao³³ found that the ETR and net photosynthetic rate of U. prolifera remain high and stable even as light intensity increased to 2000 µmol photons m⁻² s⁻¹. These results explain the continuous carbon accumulation of U. prolifera exposed to light intensity > 1200 µmol photons m⁻² s⁻¹ for more than 2 h in sunny day experiments, which is about two- or threefold higher than that required to saturate the photosynthetic rate (600 µmol photons m⁻² s⁻¹³³). PPDKase might play an important role in dissipating excess energy and ATP in cells, since it is responsible for catalyzing the regeneration of PEP in the cytoplasm, where ATP is consumed during PEP formation from pyruvate (Fig. 1b). The basis for this speculation is from the experiments of Haimovich-Dayan et al.¹⁸ who used RNA-interference to silence the single gene encoding PPDKase in P. tricornutum and found that the variations of PPDKase activity hardly affected net CO₂ fixation but were distinctly involved in dissipating excess energy and ATP in cells. In this study, we only detected PPDKase under sunny conditions, indicating its link with protection against photoinhibition. Based on our study and previous evidence, we propose that, of the three enzymes of C₄ metabolism, net CO₂ fixation in U. prolifera mainly is determined by PEPCase and PEPCKase, but energy dissipation depends on PPDKase.

Coastal eutrophication and high light supply in the Yellow Sea are important environmental conditions that favor the initiation of C₄ function of U. prolifera. During the summer (June–August) when the U. prolifera bloom is forming, dissolved inorganic nitrogen (DIN) concentrations are 10–80 µM near the coast and 1–15 µM offshore¹⁶, and the average light intensity in surface seawaters is ~1072.2 µmol photons m⁻² s^{−1 34}. In this study, the DIN concentrations in the culture medium were about 30 µM and the daily average light intensity on sunny days in experiments 1 and 3 was 1196 and 1011 µmol photons m⁻² s⁻¹, respectively. These values fit within the range of environmental condition in the Yellow Sea. The pCO₂ supply is limited during the formation of green tide in the Yellow Sea, with a range of 300–450 μatm³⁵, and moreover, it can be affected by phytoplankton consumption. Large floating mats formed by U. prolifera block air–sea exchange, thus, HCO₃⁻ uptake and assimilation could become important for rapid biomass accumulation. This was reflected in the tissue δ¹³C (culture samples: −19.5 to −17.4‰; field samples: −21.9 to −14.9‰)¹⁶.

Ulva prolifera assimilates CO₂ predominately via the C₃ pathway, takes up HCO₃⁻ via the CA mechanism at low CO₂ levels, and takes advantage of high irradiation by deploying the C₄ pathway. This adaptive and multifaceted carbon acquisition strategy in U. prolifera is obviously an advantageous biological approach to support fast biomass accumulation and improve oxygen production in the filaments to sustain respiration for algae while floating in thick mats³⁶. The relative contribution of the C₄ pathway and CA mechanism in utilizing the HCO₃⁻ system and the environmental thresholds that determine which of these pathways dominate at different stages of bloom development, maturity, and decline need to be further elucidated.

Ulva prolifera blooms are initiated from the biomass of thalli dislodged in the intertidal zone where the alga is subject to very high diurnal ranges in temperature and light and can tolerate partial desiccation³⁷. Evolutionarily, the expression of C₄ photosynthesis in U. prolifera maybe an adaptive response that enables the species to take advantage of rapidly changing conditions, and which also leads to formation of unusual massive blooms. The ability to harness the benefit of C₄ photosynthesis might also be a feature of other types of blooming macroalga and warrants investigation.

Methods

Culture experiments

Floating specimens of Ulva prolifera were collected from the Yellow Sea and, after cleaning epiphytes off using sterilized seawater, the sampled thalli were cultured in a laboratory incubator for a week prior to the outdoor experiments. Fifty grams of fresh thalli were placed into each of three replicate transparent plastic containers (53.5 cm × 39 cm × 32.5 cm), with 40 L of filtered seawater. To maintain ambient seawater temperatures in the containers, they were suspended in an outdoor seawater pond (60 × 100 m) at Muping Coastal Station of Chinese Academy of Sciences, China. Each experiment lasted 1 day from 08:00 to 18:00, without stirring. The first two outdoor culture experiments were carried out in July 2018, including a sunny day culture (experiment 1) and a cloudy day culture (experiment 2). The two experiments were to examine the responses of major enzyme activities of the C₃ and C₄ pathways (Rubisco, PEPCase, PEPCKase, and PPDKase) to diurnal variation of light intensity. The details are given below.

Algal sample was collected every 2 h from each of the three culture containers and stored in a liquid nitrogen tank prior to assays of enzyme activities. Light intensity, salinity, and air temperature were monitored during the culture using a light meter (TES-1339R, TES Electrical Electronic Corp., Taiwan), salinometer (S3-Standard kit, Switzerland), and thermometer (PT3003, Anymeter, China), respectively. The initial concentrations of DIN and dissolved inorganic phosphate (DIP) in the culture medium for both the sunny and cloudy day experiments were 34.6 and 0.67 μM, respectively. During experiments 1 and 2, salinity varied from 31.2 to 32.1 and water temperature was not much different on sunny (27.4–32.6 °C) versus cloudy (28.2–31.4 °C) days, but sunlight intensity was much higher on sunny days (57.5–1858 μmol photons m⁻² s⁻¹) than cloudy days (10.2–810 μmol photons m⁻² s⁻¹).

A third outdoor experiment (again with three replicate culture containers as described above) was conducted in August 2019 to define the correlation between major enzyme activities and corresponding photosynthetic products. This experiment was carried out on a sunny day, from 08:00 to 18:00. Samples were collected from each of the three culture containers every 2 h and stored in liquid nitrogen for the assays of enzyme activities and tissue δ¹³C. Meanwhile, the changes of pCO₂ and HCO₃⁻ were measured in the container seawater, and light, salinity, and air temperature were monitored through the day. The initial concentrations of DIN and DIP in the culture medium were 30.9 and 0.16 μM, respectively. During the third experiment, salinity varied from 33.1 to 33.8, water temperature ranged from 26.2 to 29.6 °C, and sunlight intensity from 50.4 to 1738 μmol photons m⁻² s⁻¹.

Measurement of the pCO₂ and HCO₃⁻ concentrations

Twenty-five milliliters of water samples were taken from each of the three culture containers at each 2-h time interval and transferred to a fifty milliliters stoppered polyethylene bottle containing ten milliliters of a hydrochloric acid (HCl) standard solution (0.006 mol L⁻¹). After the pH in the water sample was stabilized, HCl standard solution was added into the sample to adjust the pH between 3.40 and 3.90. The added HCl volumes and pH values were recorded and total alkalinity calculated as

$${\mathrm{A}} = \frac{{V_{\mathrm{HCl}} \times c^{\mathrm{HCl}}}}{{V_{\mathrm{W}}}} \times 1000 - \frac{{a_{{\rm{H}}^{+}} \times \left( {V_{\mathrm{W}} + V_{\mathrm{HCl}}} \right)}}{{V_{\mathrm{W}} \times f_{{\rm{H}}^{+}}}}1000,$$

where A represents the alkalinity of the sample (mmol L⁻¹); _c^HCl represents HCl standard solution (mol L⁻¹); V_W represents water sample volume (mL); V_HCl represents added HCl volume (mL); \(a_{{\rm{H}}^{+}}\) represents the hydrogen ion activity corresponding to the solution pH; and \(f_{{\rm{H}}^{+}}\) represents the hydrogen ion activity corresponding to the pH and actual salinity of the solution. All data, including temperature and salinity, were input into CO2SYS³⁸, which was used to calculate the pCO₂ and HCO₃⁻ concentrations.

Enzyme assays

The frozen algal samples were ground with liquid nitrogen, with ~0.1 g of the ground sample used for enzyme assays. The activities of Rubisco, PEPCase, and PPDKase were assayed using enzyme assay kits provided by Solarbio Life Sciences, China. The activity of PEPCKase was assayed using enzyme assay kits provided by Nanjing Jiancheng Bioengineering Institute, China. One unit of Rubisco, PEPCase, and PEPCKase activity is defined as the amount of enzyme consuming 1 nmol NADH per minute. One unit of PPDKase activity is defined as the amount of enzyme consuming 1 nmol NADPH per minute.

CA activity was assayed according to the method of Wilbur and Anderson³⁹. Prior to storage in liquid nitrogen, ~0.1–0.14 g of fresh algal thallus (algal weight) were weighed and then soaked in 2 mL of barbiturate buffer (20 mmol/L, pH = 8.4). Five milliliters of CO₂-saturated water was injected to initiate the reaction. The reaction mixture was cooled in a 4 °C-water bath. The extracellular CA activity was assayed by measuring the time of catalyzed reaction required for the pH to change from 8.3 to 7.3 (T_c). The same procedure was repeated using 2 mL of barbiturate buffer without algal thallus and the uncatalyzed time required for background pH change from 8.3 to 7.3 was recorded (T₀). The extracellular CA activity was calculated according to the following formula: Enzyme activity (U/g) = ((T₀/T_c − 1) × 10)/algal weight.

Then, ~0.03–0.04 g of algal thallus was carefully ground in liquid nitrogen and soaked with 2 mL of barbiturate buffer (20 mmol/L, pH = 8.4) for the assay of total CA activity. The total CA activity was measured and calculated using the same method and formula as for extracellular CA activity. The intracellular CA activity was calculated by total CA activity minus extracellular CA activity.

Tissue δ¹³C measurement

After rinsing with 0.1 M HCl and washing with Milli-Q water, algal samples were freeze-dried and ground. Approximately 0.5–1 mg ground sample was placed into a 4 × 6 mm tin capsule for tissue δ¹³C analysis. The samples were analyzed using an isotope-ratio mass spectrometer (MAT 253, Thermo Scientific, USA) at the Yantai Institute of Coastal Zone Research, Chinese Academy of Sciences. Reference gases were calibrated against International Reference Materials (IAEA-CH6, IAEA-600 and EMA-P1). Results are expressed relative to Vienna PeeDee Belemnite. Replicate measurements of a laboratory standard (acetanilide, Thermo Scientific) analyzed with the samples indicated that analytical errors were <0.1‰ for δ¹³C.

Statistics and reproducibility

Linear regression analysis was carried out to test the dependence of enzyme activity on irradiance levels using data from both the sunny and cloudy day experiments (experiments 1 and 2). Pearsonʼs R² was used to determine the significance of the results. PEPCKase activity was transformed (χ²) to ensure normality of residuals for the linear regression (Shapiro–Wilk test). Other variables did not require transformation. Two-way analyses of variance (ANOVA, factors = time of day and light condition) was carried out on data from experiments 1 and 2. These analyses compared the level of enzyme activity under sunny and cloudy conditions and between different time periods (three replicates at each time period). Comparisons for PEPCKase were made across all time periods from 08:00 to 18:00, and for Rubisco and PEPCase for time periods from 08:00 to 16:00. Bartletts test was used to check for homogeneity of variances. A square root transformation was required to correct the variance structure for Rubisco and PEPCase. The 18:00 time period was excluded for Rubisco and PEPCase as variance structure could not be corrected if it was included. Tukey’s HSD was used for the pairwise comparisons. Correlation analyses were conducted on parameters measured in the third experiment for the time period from 08:00 to 14:00 (also three replicates) in order to examine the relationships between the activities of key enzymes and photosynthetic products to ascertain the activity of C₄ and/or CA pathways in U. prolifera. All analyses were undertaken using Addinsoft’s statistical software XLSTAT.

Reporting summary

Further information on research design is available in the Nature Research Reporting Summary linked to this article.