Impact of dissolved inorganic carbon concentrations and pH on growth of the chemolithoautotrophic epsilonproteobacterium Sulfurimonas gotlandica GD1T

Epsilonproteobacteria have been found globally distributed in marine anoxic/sulfidic areas mediating relevant transformations within the sulfur and nitrogen cycles. In the Baltic Sea redox zones, chemoautotrophic epsilonproteobacteria mainly belong to the Sulfurimonas gotlandica GD17 cluster for which recently a representative strain, S. gotlandica GD1T, could be established as a model organism. In this study, the potential effects of changes in dissolved inorganic carbon (DIC) and pH on S. gotlandica GD1T were examined. Bacterial cell abundance within a broad range of DIC concentrations and pH values were monitored and substrate utilization was determined. The results showed that the DIC saturation concentration for achieving maximal cell numbers was already reached at 800 μmol L−1, which is well below in situ DIC levels. The pH optimum was between 6.6 and 8.0. Within a pH range of 6.6–7.1 there was no significant difference in substrate utilization; however, at lower pH values maximum cell abundance decreased sharply and cell-specific substrate consumption increased.


Introduction
The hypoxic areas of the oceans, that is where the oxygen concentration is less than 2 mL L À1 , are currently increasing on a global scale (Stramma et al. 2008). The most severe form of anoxia, with fatal consequences for higher life, constitutes the development of hydrogen sulfide-containing bottom waters. These so called "dead zones" have expanded due to eutrophication in coastal ecosystem (D ıaz and Rosenberg 2008) but exist also in semi-enclosed basins with reduced water circulation such as the Black Sea, Cariaco Basin, and the Baltic Sea. The Baltic Sea is one of the largest hypoxic marine systems and it is intensely influenced by anthropogenic activities (Conley et al. 2011).
At the interface between hydrogen sulfide and oxygen and/or nitrate, different groups of sulfur oxidizing bacteria play an important role in the detoxification of hydrogen sulfide (Lavik et al. 2009). Bacterial chemolithoautotrophic denitrification occurs when there is an interface between sulfide and nitrate and has been shown to be an important process for removal of both nitrogen and hydrogen sulfide (Jensen et al. 2009;Lavik et al. 2009;Grote et al. 2012;Bruckner et al. 2013). Chemoautotrophic denitrification is a widely distributed metabolic route, inter alia, carried out by members of the b-, cand e-proteobacteria, as well as Aquificales and some other bacterial and archeal groups, which occur across a wide range of habitats (Mat ej u et al. 1992;Reysenbach et al. 2009;Shao et al. 2010). However, there is evidence that e-proteobacteria seem to dominate this process in marine pelagic redox zones (Brettar et al. 2006;Lin et al. 2006;Grote et al. 2007), but are also widespread in hydrothermal vents (Campbell et al. 2006). In fact, these species are responsible for the majority of chemoautotrophy in the redox zones, as they carry out 70-100% of the CO 2 fixation in the pelagic redox gradients of the Baltic and Black Seas (Grote et al. 2008;Glaubitz et al. 2009). Different groups of e-proteobacteria have been found globally distributed in marine anoxic/sulfidic areas (Grote et al. 2012;Rodriguez-Mora et al. 2013) and probably are also widespread in coastal anoxic zones with a sulfide-nitrate interface. In the Baltic Sea redox zones, e-proteobacteria mainly belong to the Sulfurimonas gotlandica GD17 cluster (Grote et al. 2007). Grote et al. (2012) recently studied a representative of this Sulfurimonas cluster, named S. gotlandica GD1 T , and used genomic and physiological investigations to demonstrate high-metabolic versatility and adaptations to pelagic redox zones of this strain. The bacterium is known to reduce nitrate to dinitrogen and to oxidize thiosulfate to sulfate.
Thus, this group of e-proteobacteria fulfills an important ecological role in the oxic-anoxic interface of the Baltic Sea, being primarily responsible for hydrogen sulfide detoxification and nitrate removal.
Using S. gotlandica GD1 T as a model organism for this group , we were investigating abiotic and biotic factors which regulate the growth and distribution of these bacteria in the environment. Although in previous studies the utilization of different electron donors and acceptors (Grote et al. 2012;Labrenz et al. 2013) and the impact on the distribution of this group in the redox zone (Bruckner et al. 2013) was studied, we examined here the effects of dissolved inorganic carbon (DIC) concentration and pH on growth of S. gotlandica GD1 T .
The important role of chemolithoautotrophic e-proteobacteria in the sulfur and nitrogen cycle led us to ask whether and how these bacteria are able to cope with changes in DIC concentrations and pH which are predicted due to ocean acidification in marine environments. According to the report of the Intergovernmental Panel on Climate Change (IPCC), a decrease of 0.3 pH units is predicted by the year 2100 and a decrease of 0.77 pH units by the year 2300 (Caldeira and Wickett 2003). However, in the deeper anoxic zones of the central Baltic basins the DIC concentration is already around 2 mmol L À1 and the pH is 7.1 (Beldowski et al. 2010;Schneider 2011) and acidification impacts are therefore assumed to be relatively small in the environment. Only few studies have examined the impact of DIC and pH on growth of chemolithoautotrophic bacteria, mostly with focus on carbon concentrating mechanisms, and using isolates derived from hydrothermal vent habitats (e.g., Dobrinski et al. 2005;Scott and Cavanaugh 2007). Therefore, in this study we first investigated whether different DIC concentrations and pH values have an influence on growth of S. gotlandica GD1 T . Second, in order to deduce single regulating factors, we examined the influence of different pH values not only for growth but also for substrate utilization.

Material and Methods
Cultivation Sulfurimonas gotlandica GD1 T was grown in anoxic artificial brackish water with the following components: 95 mmol L À1 NaCl, 11.23 mmol L À1 MgCl, 2.28 mmol L À1 CaCl 2 , 2.03 mmol L À1 KCl, 10 mmol L À1 HEPES, 192 lmol L À1 KBr, 91 lmol L À1 H 3 BO 3 , 34 lmol L À1 SrCl 2 , 91 lmol L À1 NH 4 Cl, 9 lmol L À1 KH 2 PO 4 , and 16 lmol L À1 NaF. Resazurin served as the redox indicator. To remove oxygen from the medium, the deionized water used in medium preparation was boiled for at least 10 min and then purged with N 2 for at least 45 min. After autoclaving the medium, vitamins (Balch et al. 1979), trace elements SL10 (Widdel et al. 1983), selenite, and tungstate (Widdel and Bak 1992) were added as supplements. Nitrate (1 mmol L À1 ) was added as electron acceptor and thiosulfate (1 mmol L À1 ) as electron donor. Both were prepared anaerobically and afterward autoclaved. Although hydrogen sulfide is an important substrate in situ and was shown to be utilized by this strain (Grote et al. 2012), thiosulfate provides high cell numbers as well and is better suitable for controlled experimental investigations (Grote et al. 2012;Bruckner et al. 2013). The substrate concentrations were added in saturation for S. gotlandica GD1 T , allowing exponential growth for several days. As carbon source sodium bicarbonate (filter-sterilized), was provided at a concentration of 2 mmol L À1 . Because there is an equilibrium of hydrogen carbonate, carbonate, and carbon dioxide (DIC speciation), the carbon source will be named as DIC concentration. The distribution of the DIC speciation at pH 6.5 is 70.96% hydrogen carbonate, 28.96% carbon dioxide, and 0.07% carbonate, whereas at pH 8.0 the distribution of the DIC speciation is 95.59% hydrogen carbonate, 1.23% carbon dioxide, and 3.17% carbonate.
The bacterium was grown in batch culture at 15°C in the dark and at a pressure of 2.5 bar (N 2 -atmosphere) in all experiments. To determine the DIC saturation as well as optimum pH range 250 mL bottles were used including 50 mL headspace. In the experiments to examine substrate utilization during chemolithoautotrophic growth, 600-mL bottles were used with 100-mL headspace. Bacterial cell numbers were quantified by counting DAPI (4′,6diamidino-2-phenylindol)-stained cells by epifluorescence microscopy. The maximal cell numbers, which were reached at the end of the exponential growth phase, represent both the yield of the culture (with respect to the substrate concentrations) and the carrying capacity under the given conditions, reflecting the efficiency of using the available substrates and converting them into bacterial biomass.

Chemical analysis
The pH was measured with a WTW microprocessor pH meter pH 3000 and a WTW SenTix 61 pH electrode and calibrated with standard buffer solutions (pH 4.01 and 6.87). All pH measurements are reported on the National Bureau of Standards (NBS) scale. The pH was measured at the beginning (marked as pH s ) and end (marked as pH e ) of the incubation time. After preparing the medium (including autoclaving and cooling) and adding the substrates and the desired DIC concentration, a 20-mL subsample was taken from the anoxic medium and its pH adjusted to the desired value by addition of 0.1 mol L À1 hydrochloric acid at room temperature. The corresponding amount of 1mol L À1 HCl was then calculated and added to the medium, which was then inoculated with the bacteria. Changes in pH caused by different temperatures between the measurement and incubation temperature were calculated with the carbonate equilibration model, CO2SYS (Lewis and Wallace 1998). Nitrate was quantified colorimetrically at a wavelength of 540 nm according to the spongy cadmium method, as described by Jones (1984). Sulfate was determined turbidimetrically by Ba precipitation in a procedure modified from that of Tabatabai (1974). Here, to avoid the formation and precipitation of thiosulfate-derived zero-valent sulfur, the samples were not acidified by citric acid. Thiosulfate was analyzed with a modified method according to Zopfi et al. (2004). The samples were derivatized with 3-(bromomethyl)-2,5,6-trimethyl-1H,7H-pyrazolo[1,2-a]pyrazole-1,7-dione (also known as (mono)bromobimane) and then measured by HPLC (Merck), consisting of a LiChrosphere 60RP select B column (125 9 4 mm, 5 lm). The eluents were 0.25% acetic acid (v/v) and HPLC-grade methanol. The methanol gradient was established as follows: 0 min: 0%, 1 min: 8%, 4.5 min: 10%, 7 min: 32%, 11 min: 32%, 18 min: 50%, 22 min: 100%, 24 min: 100%, 25 min: 0%, and 30 min: 0%. Thiosulfate was detected by a fluorescence detector (excitation: 380 nm, emission: 480 nm). Standards and reagent blanks were prepared in N 2 -purged deionized water and analyzed as described for the samples.

Estimation of DIC saturation for growth
Sulfurimonas gotlandica GD1 T was grown in batch culture at DIC concentrations ranging from 20 lmol L À1 to 2000 lmol L À1 and at a pH s between 7.0 and 7.5. DIC concentration was not measured directly but instead sodium bicarbonate was dissolved and then added to the medium to obtain the desired final concentration. From the theoretical equilibrium between CO 2 compounds in the medium and in the headspace it was calculated that a maximum of 1.8% of the DIC was converted into CO 2 gas in the headspace. Previous experiments had shown that during growth in batch culture and under the conditions applied, S. gotlandica GD1 T reaches stationary phase after 10-14 days (Grote et al. 2012;Bruckner et al. 2013). Thus, final cell concentrations at this time represent the carrying capacity for this strain under the given conditions. Therefore, we took samples after 14 days and quantified cell numbers by DAPI staining. Cell number at the beginning of the incubation time was 2.0 9 10 5 cells mL À1 .

Effects of different pH values on chemolithoautotrophic growth
To identify the pH range allowing the chemolithoautotrophic growth of S. gotlandica GD1 T , the bacteria were cultivated within a pH s range of 6-9. Accordingly, a pH s range AE0.05 of the target pH s was established. HEPES (10 mmol L À1 ) was used as the buffer based on its optimum buffering capacity between pH 6.8 and 8.0. The pH of the bacterial preculture medium was between 7.0 and 7.5. Bacteria were grown in batch culture for 14 days, with the final cell number determined as described above. At the end of the incubation, the pH e was controlled using the same methods described above. Cell number at the beginning of the incubation time was 2.5 9 10 5 cells mL À1 .

Substrate utilization during chemolithoautotrophic growth
After the pH range had been determined, which is suitable for chemolithoautotrophic growth of S. gotlandica GD1 T , substrate utilization was investigated at selected pH values within this range. S. gotlandica GD1 T was grown under the same conditions as above, and the pH was measured at the beginning (pH s ) and end (pH e ) of the experiments. The experiments were conducted at pH s of 7.1 (the pH of the Baltic Sea redox zones), and at pH s 6.6 (the critical point at which the influence of pH on maximal cell numbers became visible before). Cell number at the beginning of the incubation time was 2.7 9 10 5 cells mL À1 .
Cell numbers, nitrate and thiosulfate consumption, and sulfate production were quantified daily for 14 days, although substrate utilization per bacterium was calculated only during late exponential growth (day 6-9). Nitrate was analyzed in 1 mL samples diluted 1:100, and sulfate in undiluted 1 mL samples. Thiosulfate was measured in 25-lL samples centrifuged and diluted 1:10 prior to derivatization with 50 lL of Monobromobimane-HE-PES-EDTA-buffer. The derivative was diluted again 1:10 to obtain a thiosulfate concentration below 20 lmol L À1 , that is within the concentration range yielding the best linear relationship. Sulfate was measured immediately, whereas nitrate and thiosulfate samples were stored at À20°C until analysis. All vials used for the analyses were flushed with N 2 to remove oxygen and to maintain the samples as oxygen-free as possible. Negative controls without bacteria had been previously performed and revealed that purely chemical reactions can be ruled out for changes in substrate concentrations at different pH values (Bruckner et al. 2013).
Statistical tests were performed using an analysis of variance (ANOVA) and an error probability of 5% followed by a post hoc test (Tukey).

Estimation of DIC saturation for growth
Sulfurimonas gotlandica GD1 T grew at the whole DIC concentrations but final cell numbers increased with increasing DIC concentration up to a saturation level at around 800 lmol L À1 DIC. At this concentration maximal cell number of 2.8 9 10 7 AE 3.4 9 10 6 cells mL À1 was reached (Fig. 1). According to the calculated dynamic fitting procedure by SigmaPlot, half-saturation concentration in DIC for achieving maximal cell numbers was 132.6 lmol L À1 , with a threshold concentration of 87.5 lmol L À1 DIC.

Effects of different pH values on chemolithoautotrophic growth
The optimum pH s range for S. gotlandica GD1 T , as judged from the final cell concentration, was between 6.7 and 8.0, with no significant differences in the maximal cell numbers of 1.7 9 10 7 AE 2.9 9 10 6 cells mL À1 (ANOVA, P > 0.05) (Fig. 2). At pH s values above 8.0 and below 6.5, cell numbers did not differ from the initial levels, indicating that no growth occurred. At pH s 6.5, bacterial cell numbers increased only slightly, resulting in a maximal cell number of 3.3 9 10 6 AE 1.5 9 10 6 cellsmL À1 . The pH measurements at the end of the experiment showed that the pH in the range of 6.5 and 8.4 remained constant (AE0.02) during the experimental time whereas above and below these points the pH e decreased by about 0.18-0.25.

Substrate utilization during chemolithoautotrophic growth
The aim of this study was to examine the substrate utilization of S. gotlandica GD1 in dependence of pH. The chosen pH s values were pH s 7.1 (present pH in Baltic Sea redox zones), and pH s 6.6 (the critical point, at which an influence of pH on maximal cell numbers was visible). Maximal cell numbers, and substrate utilization showed no significant differences between the pH s 7.1 and 6.6 values (ANOVA, P > 0.05) (Fig. 3). Thus, the results of pH s 7.1 and 6.6 were summarized together. In all trials within these 2 pH s values, a cell abundance of 1.4 9 10 7 AE 2.7 9 10 6 cells mL À1 was reached in 9 days (Fig. 3). However, at a pH s directly below 6.6 cell numbers were sharply reduced (see Figs. 2, 3), for example at pH s 6.55 only a maximal cell number of 3.8 9 10 6 AE 4.1 9 10 5 cells mL À1 at day 9 was achieved ( Fig. 3C).
At pH 7.1 and 6.6 S. gotlandica GD1 T completely consumed the 1000 lmol L À1 thiosulfate, metabolizing most of it to sulfate within the 9 days (1322.9 AE 201 lmol L À1 ). Nitrate was only partially consumed and at the end of the experiment still 236 AE 129 lmol L À1 of nitrate could be measured. In contrast, at pH s 6.55 the bacteria used 742.5 AE 391.8 lmol L À1 of nitrate and 824.3 AE 144.0 lmol L À1 of thiosulfate and produced 903.8 AE 373.0 lmol L À1 sulfate. According to Figure 3 the exponential growth occurred between days 3 and 9. During the late exponential phase (day 5-9) differences in the substrate concentrations were the most significant, thus reducing methodological biases (which are larger when only small concentration changes occur). Hence, in the late exponential phase S. gotlandica GD1 T used 68.1 AE 12.3 fmol nitrate cell À1 and 43.7 AE 5.9 fmol thiosulfate cell À1 and produced 77.9 AE 17.9 fmol sulfate cell À1 at pH s 7.1 and 6.6. The cellular growth rate was at both pH s values around 0.4 AE 0.01 h À1 . In contrast, at pH s 6.5, the growth rate was 0.3 AE 0.02 h À1 , but with strongly enhanced substrate turnover. In fact, the cells used 414 AE 151 fmol nitrate cell À1 , 247 AE 209 fmol thiosulfate cell À1 , and produced 944 AE 563 fmol sulfate cell À1 than cultures maintained at a higher pH.
The negative controls for all chemical analysis remained constant during the incubation time and were always in the same range as the standards samples of 0 lmol thiosulfate, nitrate or sulfate, respectively, used for calibration. Hence, there was no evidence that other chemical compounds influenced the measurements. The discrepancy between thiosulfate utilization and sulfate production at 6.55 was probably caused by methodical errors. The measurements of nitrate and thiosulfate at the beginning and after 24 h confirmed the added concentrations of 1 mmol L À1 for each of these substrates. The pH could be kept relatively constant with a decrease of pH e of 0.092 AE 0.046 units.

Discussion
The primary aim of this study was to examine the response of the e-proteobacterium S. gotlandica GD1 T toward changes in DIC and pH. This could be achieved Figure 3. Anaerobic chemoautotrophic growth of Sulfurimonas gotlandica GD1 T in a batch culture at pH 7.1 (A), pH 6.6 (B), and pH 6.55 (C). Cell abundance and nitrate (electron acceptor), thiosulfate (electron donor), and sulfate (formed by thiosulfate oxidation) concentrations were quantified daily. (A-C) are the means of three, two, and two replicates, respectively. Error bars are standard deviations.
by assessing the impact of changes in DIC concentration and pH on growth and maximal cell numbers of S. gotlandica GD1 T in batch culture growth experiments.
Hydrogen sulfide is the major substrate in anoxic waters and S. gotlandica GD1 T seems to be primarily responsible for hydrogen sulfide oxidation in the Baltic Sea (Grote et al. 2012). However, at the oxic-anoxic interface and the upper sulfidic zone thiosulfate concentrations are in a similar range as hydrogen sulfide concentrations (Bruckner et al. 2013) and thiosulfate serves as an alternative substrate for S. gotlandica GD1 T . We used thiosulfate as electron donor in the experiments as substrate concentrations can be much better controlled compared to hydrogen sulfide. Although thiosulfate seemed to be entirely consumed at the end of the experiment (see Fig. 3), earlier experiments with this strain did not produce higher cell numbers with higher thiosulfate concentrations (Bruckner et al. 2013;Labrenz et al. 2013). Therefore, other potentially limiting factors, related to cell concentration, have to be considered, such as the accumulation of inhibitory metabolic products.

Estimation of DIC saturation for growth
The growth-stimulating effects of increasing DIC concentrations for phytoplankton are well documented (e.g., Iglesias-Rodriguez et al. 2008) whereas only few studies were performed with chemolithoautotrophic bacteria. According to the current DIC concentrations of about 2 mmol L À1 and 3.5 mmol L À1 (Frey et al. 1991;Beldowski et al. 2010) in the redox zones of the Baltic and the Black Sea, our results show that these DIC concentrations are well within the range supporting maximal growth of S. gotlandica GD1 T and related epsilonproteobacteria. The results suggest that a further increase in DIC concentration in the redox zones should have no additional direct effect on these bacteria.
A higher DIC concentration in the ocean causes a shift in the DIC speciation toward carbon dioxide, resulting in a decrease of pH, that is at pH 7.1 90% of the DIC speciation is hydrogen carbonate while at pH 6.3 the balance shifts to 50% hydrogen carbonate and 50% carbon dioxide (Deffeyes 1965). However, this shift in speciation should not have an influence on growth of S. gotlandica GD1 T as a DIC concentration of 800 lmol L À1 was already sufficient to promote maximal cell numbers (Fig. 1). Comparable saturation curves for increasing DIC concentrations had been determined for other bacterial and phytoplankton species. Clark and Flynn (2000) described the relationship between the carbon-specific growth and the DIC concentration of several marine phytoplanktons. Most of these species reached a saturation between 500 and 1000 lmol L À1 DIC. Furthermore, Dobrinski et al. (2005) showed that for the chemolithoautotrophic c-proteobacterium Thiomicrospira crunogena, isolated from a hydrothermal vent, the half-saturation DIC concentration was 220 lmol L À1 and saturation was reached at 1000 lmol L À1 DIC, which is in the same range as the values determined for S. gotlandica GD1 T . In contrast, Scott and Cavanaugh (2007) showed that the chemoautotrophic Solemya velum symbionts reach saturation at a CO 2 concentration of 100 lmol L À1 . However, this saturation is also well within the range of the CO 2 concentration in the environment, where S. velum was collected. In addition, they could prove that these symbionts rely on CO 2 and not on bicarbonate.
Genomic data indicate that S. gotlandica GD1 T is capable of using both CO 2 and bicarbonate by converting intracellular bicarbonate to CO 2 with the carbonic anhydrase (Grote et al. 2012). In addition, Dobrinski et al. (2005) could prove that the chemolithoautotrophic c-proteobacterium Thiomicrospira crunogena has the ability to use both external CO 2 and bicarbonate. Therefore, it seems probable that S. gotlandica GD1 T has also the ability to use both external CO 2 and bicarbonate as inorganic carbon source.

Effects of different pH values on chemolithoautotrophic growth
The pH range at which S. gotlandica GD1 T grew well (pH 6.6-8.0) was relatively narrow compared to that of other chemolithoautotrophic proteobacteria. For example several c-proteobacterial Thiomicrospira species from hydrothermal vents grew at a wide pH range of 5.3-8.5 or 4.0-7.5 (Brinkhoff et al. 1999). Also for other chemoautrophic e-proteobacteria a relatively wide tolerable pH range was found, for example for Sulfurimonas paralvinellae and Sulfurimonas autotrophica, the pH range was 5.4-8.6 (optimum 6.1) and 5.0-9.0 (optimum 6.5), respectively (Inagaki et al. 2003;Takai et al. 2006). Sulfurimonas denitrificans, the closest cultivated relative of S. gotlandica GD1 T (Grote et al. 2012), has a pH optimum of 7.0 (Timmer-ten Hoor 1975). Most of these investigated bacteria with a more extended pH range compared to S. gotlandica GD1 exist in habitats such as hydrothermal vents, where pH changes are frequent and rapid. Thus, the extended pH range suggests that it is an adaptation to the extremely variable conditions, whereas S. gotlandica str. GD1 was isolated from a relatively stable habitat. Scott and Cavanaugh (2007) confirm this conclusion with their studies about chemoautotrophic c-proteobacteria, living as endosymbionts in sulfidic/oxic interfaces. These Solemya velum symbionts have also a relatively narrow range of pH optimum (between pH 7.4 and 8.5), showing the same sharp decline in growth directly below and above these levels.
The substrate utilization did not differ significantly between pH s 7.1 and 6.6. However, at a pH s below 6.6 the situation changed drastically and growth of S. gotlandica GD1 was obviously impaired, and consumption of nitrate and thiosulfate was strongly reduced. Thus, the important functional role of S. gotlandica GD1 T in the redoxcline nitrogen and sulfur cycles would probably be impacted.
While intracellular pH was not measured in this study, it is supposed that the intracellular pH varies by around 0.1 units per unit change in the external pH (Hackstadt 1983). According to Booth (1985) changes in pH outside the pH optimum leads to an inhibition of both enzyme activity and cell growth (Booth 1985). However, thus far the exact mechanism of intracellular pH regulation is not completely understood. Earlier studies have shown that the regulation is energy dependent and requires a high respiratory rate (Booth 1985). Hence, the high substrate utilization per bacterium at pH s 6.55 could be at least partially explained by regulation of the intracellular pH outside the optimum pH.
As substrate utilization in the batch culture experiments was significantly higher than under environmental conditions, the results rather reflect the carrying capacity of S. gotlandica GD1 T at the given conditions. Future studies should aim to more accurately simulate in situ conditions (e.g., with chemostat cultures). Due to global warming and higher CO 2 concentrations in the atmosphere an increase in the DIC concentration and a decrease of pH by about 0.3 units in the ocean, known as ocean acidification, is predicted (Houghton et al. 2001). Our results suggest that a direct impact of acidification on S. gotlandica GD1 T and related organisms should not be very strong, as the optimum pH range for this model organism is still within the range of the predicted changes in pH. On the other hand, indirect effects on S. gotlandica GD1 T might be more important than direct ones. For example there is evidence that nitrification, the process which delivers nitrate for denitrifying bacteria, is negatively influenced by a decrease in pH and an increase in pCO 2 (Huesemann et al. 2002;Denecke and Liebig 2003;Hutchins et al. 2009).