In situ photorespirometry

All experiments were done in assemblages with a dense canopy of the fucoid Hormosira banksii (Turner) Descaisne, which commonly dominates shores in southern New Zealand and southeastern Australia. Field experiments were done at Wairepo Reef, Kaikoura [35]. Assemblages were dominated by three main components: 1) the fucoid canopy species H. banksii (average percent cover, 88.25 ±7.6%; average dry weight, 70.6 ±20.4 g); 2) sub-canopy algae, including juveniles of the fucoids Cystophora torulosa (average percent cover, 16.5 ±5.4%; average dry weight, 15.1 ±4.4g) and Carpophyllum maschalocarpum (average percent cover, 4.75 ±4.3%; average dry weight, 15.8 ±6.2g), ephemeral algae such as Champia novouzealandia (average percent cover, 8.7 ±4.9%; average dry weight, 9.1 ±4.6g); and 3) the basal assemblage dominated by Corallina officinalis (average percent cover, 38.25 ±5.3%; average dry weight, 33.1 ±13.3g).

To record natural conditions to be used in conjunction with photorespirometry experiments at the field site, irradiance and temperature were logged in the mid-shore of Wairepo Reef using HOBO (Onset^©) loggers; irradiance was cross-calibrated with a LiCor meter (LI-192 quantum sensor) to convert light measured by HOBO loggers into PAR irradiance in µmol m^-2 s^-1. Irradiance and temperature were recorded at 5 minute intervals between February 2008 and March 2010. Loggers were set facing upwards on the reef and fixed securely so that sensors could not change orientation. These were checked routinely to prevent fouling. Irradiance was also measured simultaneously above and below the canopy of H. banksii to determine the light reaching the sub-canopy. Irradiance above the canopy (ambient) was approximately 40 times higher than in the sub-canopy. Sub-canopy irradiance (i.e., on top of Corallina but below the canopy and sub-canopy layers) averaged just 18 µmol m^-2 s^-1 at an ambient irradiance of 500 µmol m^-2 s^-1, 28 µmol m^-2 s^-1 at an ambient irradiance of 1000 µmol m^-2 s^-1, and 50 µmol m^-2 s^-1 an at ambient irradiance of 2000 µmol m^-2 s^-1.

NPP of natural macroalgal assemblages was examined in situ using custom-built incubation chambers fixed to the substratum of the reef [23]. Chambers were designed to be secured around established assemblages of benthic intertidal algae without displacing them. They were made of a clear Perspex tube of height/volume 25 cm/12.3 l with a clear Perspex attachment plate and lid [23]. They were attached to the reef using a separate base plate to which the main chambers were bolted. The base plate was secured to the reef using four stainless steel bolts fixed into rawl plugs in the substratum. The Perspex tubing had an internal diameter of 25 cm (8mm thick) and covered a reef surface area of approximately 491 cm². A submerged bilge pump was used to mix the chambers (as in the laboratory-based experiments) and stop the formation of boundary layers.

Incubations were done while the tide covered the chambers to ensure that the internal temperature remained stable and there was no formation of oxygen bubbles, and also to ensure that the light regime was as natural as possible. Temperature within the chambers was measured throughout experiments using HOBO (Onset Corporation ™) data loggers and irradiance was measured with a LiCor meter (LI-192 quantum sensor). The temperature loggers were placed on the inside of the chamber and irradiance was measured outside of the canopy, but beneath the 1cm thick lid.

Oxygen exchange was measured by removing water samples using 50 mL syringes. A Hach LDO probe (Model HQ40d) was used to test the dissolved oxygen (DO) concentration of the seawater within the syringe. Respiration measurements were taken by covering chambers to omit light or during night incubations. No significant differences in respiration were found between night incubations and those done in covered chambers during daytime. Invertebrates were removed from assemblages by hand, and by using a low pressure water pump to flush remaining invertebrates and sediments from the coralline turf. Natural variation in temperature was used to determine the effects of temperature on NPP and respiration across irradiance levels. Photosynthesis-irradiance (P-E) curves were generated from incubations at three temperature ranges: 8-12°C (winter), 13-17°C (autumn) and 18-22°C (summer). NPP was standardized by dry weight of algae (mg O₂ gDW^-1h^-1) for analysis, but was presented by area (g O₂ m^-2h^-1) for comparison with laboratory assemblages.

In situ NPP measurements were done during austral summer (December 2009), autumn (March 2010), and winter (June 2010). To test potentially variable responses of the sub-canopy parts of the assemblage in different light regimes, three canopy treatments were initiated. In a series of replicate plots, the canopy was removed, leaving the sub-canopy intact, and in others the sub-canopy was removed (including mid- and basal components), leaving the canopy intact. The three canopy treatments were intact assemblages (control), the canopy minus sub-canopy, and the sub-canopy minus the canopy (hereafter referred to as intact, canopy and sub-canopy). NPP was analyzed at irradiances of approximately 1000 μmol m^–2 s^-1 and 1900 μmol m^–2 s^-1 for three replicates of each treatment. Because irradiance data were based on natural variation of light (i.e., there was no shading of chambers to reach desired light intensities), data at around 1000 μmol m^–2 s^-1 and 1900 μmol m^–2 s^-1 were binned using data between 900-1100 μmol m^-2 s^-1 and 1800-2000 μmol m^–2 s^-1, respectively.

Algal collection and acclimatization

Intact macroalgal assemblages were removed from the mid-intertidal zone of Wairepo Reef, for laboratory incubations during austral autumn (April-May) 2009. These assemblages were chiseled from the reef with the substratum attached (approximately 15 × 15 cm of substratum), then taken back to the laboratory where incubations were done. Algal collections were done under the collecting permit of the School of Biological Sciences, Canterbury University from New Zealand’s Ministry of Primary Industries.

Algae were kept in a re-circulating seawater system, at 10°C ±0.3 and a 12-hour light/dark cycle. Before experimentation all assemblages were given at least 48 hours (and not more than 56 hours) to acclimatize before experiments were initiated. The temperature range of the coastal water of southeastern New Zealand varies considerably throughout year, with the Kaikoura coast receiving annual sea-surface temperatures ranging from 9-18°C [36], but intertidal platforms regularly reach temperatures above 20°C during the summer months and below 7°C in the winter. Therefore, the experimental range tested was 10, 15, 20 and 25°C.

Laboratory photorespirometry- Single thalli and assemblages

To clarify the impacts of temperature stress on the photophysiology of the fucoid assemblages we manipulated temperature in a series of complementary laboratory experiments. In situ tests of temperature variation necessarily confounded seasonal acclimation and daily light variation with temperature and light differences. Laboratory incubations were used to identify the acute effects of rising temperature on single thalli of H. banksii and assemblages dominated by a canopy of H. banksii, a sub-canopy of Cystophora torulosa and a basal turf of Corallina officinalis (hereafter referred to as ‘assemblages’). Due to the larger biomass of full assemblages, larger incubation chambers were required to accommodate them. However, the chambers were built of the same materials, including the same thickness of the lid. The same incubation protocol was used for single thalli and assemblages.

Single thalli of H. banksii were incubated in tubular Perspex chambers of internal 15 cm diameter (8 mm thick) and 15 cm height with flat 10 mm Perspex lids. These were kept at a constant temperature using a water jacket, consisting of a second Perspex tube surrounding the incubation chamber. The light source was above the incubation chambers and directed through the lid and not the sides of the chambers. Water was pumped from a temperature-controlled water bath to the cooling jacket of each chamber using a submerged magnetic pump. The internal temperature of incubation chambers was verified using internal temperature loggers. To prevent boundary layers forming on the algal surface, which could potentially limit photosynthesis, chambers were constantly mixed using a 3 cm magnetic stirrer (at 500 rpm). Water samples were extracted with a 1 mL syringe inserted through a tap in the lid and oxygen concentrations were measured in a Clark-type oxygen electrode (Strath Kelvin Microcell MC100) and cross-referenced with a Hach LDO probe (Model HQ40d).

The full algal assemblages were incubated in large chambers. These were 8 mm thick clear Perspex tube (30 cm high, 25 cm diameter), with a 10 mm thick clear Perspex base plate and lid [23]. Temperature was controlled by placing chambers in a constant temperature water bath, which was altered to experimental temperatures (verified using internal temperature loggers). The water within the incubation chambers was mixed using a submerged magnetic water pump that circulated the seawater in a turbulent vortex motion. Because of the size of the assemblages, the water in the chambers was exchanged after incubations at two irradiance levels to ensure that saturation did not occur and no nutrients became limiting. To prevent distortion of algal NPP due to respiration of invertebrates, all visible invertebrates were removed before incubations by freshwater dipping and physical removal.

Algae were incubated under various light intensities using a Phillips Discharge metal halide lamp limited to photosynthetically active radiation (PAR) wavelengths, with irradiance adjusted using neutral density filters to give five levels of irradiance (150, 300, 600, 1500, and 2000 μmol m^–2 s^-1). NPP was measured as changes in oxygen concentration using a Hach LDO meter (Model HQ40d). Dark respiration was obtained by covering the chamber to omit light. Measurements of dark respiration were performed at least 30 minutes after algae had been exposed to light. In total, six replicate assemblages were incubated under each light intensity and temperature combination. Following incubations, algae were dried for 24 h in a conventional oven at 50 °C and dry weights were recorded. NPP, GPP and respiration were standardized by dry weight of algae and/or area of the substratum.

Analysis of photosynthetic parameters

Several photosynthetic characteristics were calculated in the laboratory and field incubations using photosynthesis vs. irradiance curves (P-E) across temperatures. These were: α, the light-use efficiency of the P-E curve; R, the respiration rate of the assemblage; E_c, the compensation point of the assemblage; and P_m, the NPP at saturating irradiance. Photosynthesis curves of single assemblage components were fitted against irradiance (i.e., P-E curves) using the exponential relationship described by Walsby [37]:

Where P_m is the maximum photosynthetic rate at light saturating irradiances, E is irradiance level, R is the rate of respiratory oxygen consumption (g O₂ gDW^-1 h^-1), α is the light-use efficiency at light-limiting irradiances. The light-use efficiency (α) was calculated as the slope of a linear regression between 0-150 μmol m^-2 s^-1 for each replicate assemblage. Differences in photosynthetic parameters were tested using ANOVA. Also, differences in respiration rate (R), compensating irradiance (E_c) and the light-use efficiency (α) were compared between single thalli and assemblages using ANCOVA.

Q₁₀ values were calculated as the change in rate (GPP and respiration) over a 10°C temperature change. For laboratory assemblages the Q₁₀ was calculated between 10-20°C and 15-25°C, and for field assemblages it was calculated between approximately 10-20°C. Q₁₀ values were calculated for each replicate assemblage and averaged.

Impacts of in situ temperature variation on assemblages and components

In situ H. banksii-dominated assemblages had elevated respiration rates with increasing temperature (Table 1), but there was almost no difference in P_m or α, most likely caused by seasonal temperature and irradiance acclimation processes (Figure 1). However, there was a trend of increasing irradiance required to reach compensation with increasing temperature (E_c; F_2,9 = 13.0, P = 0.0066).

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Figure 1. Effects of temperature on NPP of intact in situ macroalgal assemblages dominated by a canopy of H. banksii, the sub-canopy only and the canopy only (mean ±SE).

NPP is shown at moderate irradiance, binned between 900-1100 μmol m^-2 s^-1 (A) and high irradiance, binned between 1800-2000 μmol m^-2 s^-1 (B).

https://doi.org/10.1371/journal.pone.0074413.g001

NPP of in situ assemblages and the isolated community components (canopy only and sub-canopy only) had varied responses to temperature at moderate light intensities (1000 µmol m^-2 s^-1; Figure 1A). The canopy alone showed declining NPP with rising temperature, whereas the sub-canopy had its greatest average NPP at 15°C. Intact assemblages had lower NPP at 20°C than either the canopy alone or the sub-canopy alone. At 1000 µmol m^-2 s^-1, there was a significant interaction between temperature and canopy treatments, driven by the large decline in NPP of the full assemblage at 20°C (canopy treatment x temperature, F_4,18 = 3.0, p = 0.048). At high light intensities (1900 µmol m^-2 s^-1) NPP of the sub-canopy alone declined with rising temperature, whereas full assemblages and the canopy alone had no overall trend with rising temperature (Figure 1B). The canopy treatment had an effect on NPP at 1900 µmol m^-2 s^-1 (canopy treatment, F_2,18 = 27.8, p < 0.0001), but there was no significant effect of temperature and no interaction. Increasing respiration rates and compensating irradiance could have drastic consequences for the balance of primary productivity and respiration, but due to the seasonal variation in temperature, these effects cannot be corroborated without controlled laboratory experiments.

Species composition varied across seasons, but the dominant canopy and sub-canopy components remained somewhat constant, with H. banksii, C. torulsa and C. officinalis present in all plots during all seasons (Figure S1). The canopy of H. banksii had an average cover over 85% across all seasons, with the basal layer of C. officinalis contributing over 30% and the sub-canopy fucoid C. torulosa contributing over 15% during each season. A range of ephemeral macroalgae was found in the sub-canopy throughout the year, but the total number of species changed little (mean 7.8 ± 0.4 SE). Ephemeral species such as Colpomenia sinuosa, Champia novae-zealandiae and Lophothamnion hirtum were present at different times during the year, but rarely contributed more than 5% to overall cover.

Effects of rising temperature — assemblages and single thalli

Community composition of macroalgal assemblages differed slightly among replicates in terms of species richness (average species richness of 8 ±SE 0.3) and percent cover of macroalgae (Table 2). However, Hormosira banksii, Cystophora torulosa, Carpophyllum maschalocarpum and Corallina officinalis were always present and although species richness of the sub-canopy varied among replicates, all replicate assemblages had between 7 and 9 species in total and between 5 and 7 sub-canopy species (average sub-canopy species richness 6 ±SE 0.2). The canopy of Hormosira banksii made up, on average, 45.3% (±SE 6.3) of the total biomass and the basal layer of Corallina officinalis made up 21.2% (±SE 3.8) of total biomass, while all of the combined sub-canopy species contributed 33.5% (±SE 2.7) of the total biomass.

Laboratory-based experiments showed that increasing temperature caused a shift in several photosynthetic parameters of assemblages dominated by a canopy of Hormosira banksii. Temperatures rising between 10-25°C resulted in an increase in light-use efficiency (α; Figure 2 A; r² = 0.75, F_1,14 = 42.4, p < 0.0001) and irradiance at the compensation point (E_c; Figure 2 B; r² = 0.64, F_1,15 = 24.4, p = 0.0002). Respiration changed linearly with temperature (Figure 2 C; assemblage r² = 0.87, F_1,14 = 102.2, p < 0.0001), with Q₁₀ values of 2.5 and 3.2 between 10-20 °C and 15-25 °C respectively (Table 3). Q₁₀ of GPP was lower in the higher temperature range at all light intensities, and in the highest light treatment Q₁₀ was below 1, which indicated a decline in GPP with rising temperatures. Although in situ assemblages showed no change in α or P_m, controlling for acclamatory processes using acute laboratory experiments showed that some of the laboratory vs. in situ differences may be related to seasonal acclimation to light and temperature.

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Figure 2. Effects of temperature on four photosynthetic parameters of H. banksii alone (single thalli) and H. banksii dominated assemblages (mean ±SE) in laboratory experiments.

Parameters are the light-use efficiency or α (A), compensation point or Ec (B), respiration or R (C) and maximum NPP or P_m (D) of P-E models.

https://doi.org/10.1371/journal.pone.0074413.g002

A comparison of photosynthetic parameters of single thalli and assemblages showed that assemblages responded more negatively to rising temperatures than did single H. banksii thalli. Light-use efficiency (α) increased with rising temperatures (temperature: F_1,23 = 42.4, p < 0.0001), but to a similar degree in both treatments (Figure 2A; treatment x temperature interaction: F_1,45 = 1.47, p = 0.29). However, light-use efficiency values were much higher for single thalli than they were for assemblages (treatment: F_1,45 = 36.1, P < 0.001). Both the increasing respiration rates with increasing temperature (temperature x treatment interaction; F_1,45 = 47.2, p < 0.001) and the increase in the compensation irradiance (E_c) with increasing temperature (temperature x treatment interaction; F_1,45 = 36.1, P < 0.001) were more pronounced for assemblages than for single thalli (Figure 2B, C). Maximum NPP (P_m) increased between 10 and 15°C both for assemblages and single thalli, but declined with increasing temperature. Although there was a greater decline in average NPP in the assemblages, there was no significant interaction of treatment x temperature (F_1,45 = 0. 0008, p = 0.97), but NPP was lower for assemblages than for single thalli (treatment: F_1,45 = 4.6, p = 0.037).

The P-E curves generated for assemblages dominated by a H. banksii canopy in laboratory experiments had a marked response to rising temperatures (Figure 3 A and B). A change of 5°C (10-15°C) caused a rise in NPP across the light gradient, but increasing thermal stress (20°C and above) caused a decline in NPP, particularly at high light intensities. Although both methods of standardization (area or biomass) had similar responses to irradiance and temperature, variation was greater when standardized by area. P_m was significantly different between P-E curves at each temperature (F_3,131 = 11.6, p < 0.0001) as was light use efficiency (α; F_3,131 = 4.6, p = 0.0043). In the two curves centered on 10 and 15°C there was no sign of saturation of photosynthesis, whereas temperatures centered on 20 and 25°C caused saturation of photosynthesis, and possibly photoinhibition at high irradiance.

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Figure 3. Response of NPP (±SE) in the laboratory to rising temperatures in macroalgal assemblages dominated by H. banksii at four treatment temperatures 10, 15, 20 and 25°C.

Curves for each temperature are fitted with rectangular hyperbole. Data are standardized by (A) dry weight of algal material (mg O₂ gDW^-1 h^-1) and (B) area of substrate (g O₂ m^-2 h^-1).

https://doi.org/10.1371/journal.pone.0074413.g003