Ecological sampling

Water was sampled at the South (Lat: 40°43′N Long: 112°13′W) and North (Lat: 41°26′N Long: 112°40′W) Arms of the Great Salt Lake (GSL; UT, USA) with autoclaved bottles and transported to the laboratory on ice. These studies do not involve protected species and no specific permits were required for the described field studies in the public areas of the GSL. Dunaliella spp. and haloarchaeal cells were isolated by enrichment in Minimal Media (MM1) liquid media (Dunaliella) at salinities ranging from 36, 75, 100, 150, 200, and 250 PSU. MM2-agar containing plates at the same salinities as for Dunaliella were used for haloarchaeal cells (see Supplement below).

Species identification by DNA Sequencing

To survey the diversity of organisms that naturally co-exist in hypersaline environments we enriched photoautotrophs from the South-Arm of the GSL by inoculating water samples into MM1 media containing only salts at different concentrations (75, 100, 150, 200, 250 PSU) (Fig. S1 A). Exponentially growing Dunaliella spp. cells were harvested by centrifugation (2300 rcf×4 min); DNA extraction and purification were done using DNeasy Plant Mini Kit (Qiagen), and quantified spectrophotometrically. Species-specific internal transcribed spacers (ITS-1, and ITS-2) of the RNA genes, were amplified using the primers described in [46]. Secondly, to identify co-existing microbial species, aliquots of GSL water were plated onto nutrient rich solid agar medium over a similar salinity range as for the autotrophs. Bright pink, red and orange colonies grew (Fig. S1 B) that have characteristic colony morphologies of haloarchaea due to their high cellular content of bacterioruberins, carotenoids, and rhodopsins. Isolated colonies of haloarchaeal cells (Fig. S1 B) were then grown to exponential phase and harvested by centrifugation. 16 s rRNA sequences were amplified from genomic DNA extracts according to the PCR protocol described by [47]. All amplicons were sequenced using an ABI 3730xl DNA Analyzer.

Culture conditions

For single and co-culture experiments, axenic batch cultures of Dunaliella salina (Culture Collection of Algae and Protozoa, UK, CCAP 19/18) were grown in artificial sea water (ASW [48] containing salts reaching a total of 200 PSU and enriched with nutrients as in f/2 media [49] called MM1. Cultures were grown under a 13 h∶11 h light∶dark photoperiod and at 150 µmol photons m⁻² s⁻¹ (verified by a Li-Cor 191SA (Li-Cor Inc.) at 30°C and 100 rpm shaking. Cells were entrained to this light regimen for 3 tandem culture transfers until the growth rate did not change (3 weeks) prior to the experiments. Growth rates were determined by the change in cell number and/or change in red autofluorescence (680 nm) over time. H. salinarum NRC-1 was maintained in CM media [50] at a salinity of 200 PSU and for co-culture experiments cells were grown in MM1 enriched with nutrients akin to DOM, including a mixture of amino acids (see supplement Table S1, for details) and acclimated to the same light∶dark photoperiod as D. salina. The inoculation density of co-cultures was 10⁵ ml⁻¹ D. salina cells, and 10⁸ ml⁻¹ H. salinarum cells. All experiments were run in triplicate. D. salina cells were counted by flow cytometry, H. salinarum was measured as optical density at 600 nm (OD₆₀₀ of 1.0 = 8×10⁸ cells/ml).

Duirnally synchronized syntrophic interaction between D. salina and H. salinarum

To investigate the physiological exchange and interplay between D. salina and H. salinarum, supernatant from a light/dark adapted D. salina culture was collected and seeded with H. salinarum. Culture growth was monitored at 37°C for 7 days using a BioscreenC high throughput microbial growth analysis instrument. Sterile MM1, MM1 with 400 mM glycerol and MM1 supplemented with amino acids (60 µM; see supplement Table S1 for a list of amino acids) commonly found in hypersaline ecosystems were used as controls.

Single cell analysis and fluorescent cell stains

An Influx flow cytometer (Cytopeia) using a Coherent Innova 305C argon ion laser excitation source tuned at 488 nm and 200 mW was used to quantify cell abundance. Cell count was based on forward angle light scatter (FALS) and red fluorescence collected with a 610 nm long pass and a 700/50 nm band pass filter. Sampling was done every two hours with a calibrated robot. The cells were fixed in paraformaldehyde (0.1%) and kept at 4°C until counting. Yellow/green fluorescent 1μm microspheres (Polysciences, Warrington, PA, USA) were used to calibrate gain and object detection threshold settings and as an internal fluorescence standard for normalization and counting.

Intracellular glycerol-containing vesicles in D. salina cells were observed according to standard protocols by staining with the highly specific aminoacridine dye 1 µM Quinacrine [16], [51], [52] for 15 minutes and washed twice in 200 PSU saline. Cells were analyzed for green fluorescence of quinacrine (ex: 488 nm, em: 504–523 nm, 1 µM) using a 500 nm long pass (LP) and a 530/30 nn band pass (BP) filter and red autofluorescence of chlorophyll using a 610 nm LP and a 715/50 nm BP filters. Loss of quinacrine fluorescence from pre-labeled cells indicates vesicle secretion.

DNA in live cells was detected by staining with SYBR I (λex = 497 nm/λ_em = 520 nm, 3 µM Invitrogen) [53] or DAPI (4',6-diamidino-2-phenylindole, dihydrochloride) (ex: 350 nm em: 450 nm, 3 µM) and analyzed with a BD FACS ARIAII flow sorter and a Delta Vision confocal microscope. SYTOX® blue (ex: 440 nm, em: 525 nm, 3 µM), an impermeable probe, was used to detect dead cells with compromised plasma membranes. It was used in combination with the Annexin V stain for PCD detection (see below). Dunaliella sub-populations were defined by a combination of their forward scattering characteristics and their red autofluorescence of chlorophyll a. Populations were also identified by their red autofluorescence of chlorophyll a in combination with the fluorescence of the labeled probes used (FITC-Annexin, SYTOX® blue) and subsequently sorted. After sorting with the BD FACS ARIAII, the cell's membrane and nucleus integrity were evaluated and photographed with a Delta Vision confocal microscope. Data analysis was done using FlowJo analytical software (Tree Star).

Programmed cell death (PCD) analyses

Three independent markers of PCD in chlorophytes were used [54], [55]: phosphatidylserine (PS) externalization, caspase activity and observation of the typical morphological changes associated with PCD in algae. Caspase activation and morphology are qualitative assessments; PS externalization allows qualitative and quantitative (cell enumeration) evaluation. The TUNEL assay (detection of DNA fragmentation flow cytometrically) was avoided for cell quantitation as it may detect non-specific double stranded DNA breaks, which occur during necrosis [56] and its specificity has been questioned by [45].

1. PS externalization was detected by fluorescein isothiocyanate (FITC)-labeled Annexin V adapted to the manufacturer's suggested protocol for Dunaliella (BD Pharmingen). Annexin is a a Ca²⁺-dependent phospholipid-binding protein that binds with high affinity for PS. PS is located on the cytoplasmic surface of the cell membrane, except in PCD when PS migrates to the outer surface of the plasma membrane. FITC-Annexin was used in combination with SYTOX® blue (SB), an impermeable probe that only detects dead cells when the plasma membrane is disrupted. Experiments were done in triplicate. Cells were photographed in a Delta Vision microscope.
2. Cysteine protease activity of caspase-3, which is specifically associated with PCD in Dunalliela spp [54], [55], was measured using a Caspase-3 Fluorometric Assay Kit (Assay Designs Catalog No 907-014) according to the manufacturer's instructions. Caspase-3 exists as a proenzyme, becoming activated during the PCD pathway. This assay measures the conversion of a non-fluorogenic peptide Ac-DEVD-AMC substrate for caspase-3 to a fluorogenic product that emits light at 400 nm when excited at 360 nm. Caspase-3 activity was calibrated with a solution of 7-Amino-4-methyl coumarin at 5 µM in reaction buffer at 30°C and expressed as units of fluorescence relative to the equivalent fluorescence obtained from 5.56 units of fully active Caspase-3 when reacting with the Caspase-3 substrate according to the assay kit.
3. Cellular morphological changes associated with PCD including cell shrinkage, vacuolization, plasma membrane blebbing, nuclear condensation and ejection of the nucleus were examined using a Delta Vision confocal microscope. Microscopic detection of PS externalization was also performed.

Radioisotope tracing

C-flux was determined with radioisotope tracing by addition of NaH¹⁴CO₃ to an activity of 1µCi¹⁴C ml⁻¹ to light∶dark acclimated pure and co-cultures of D. salina and H. salinarum at an inoculating ratio of 10⁵ D. salina cells: 10⁸ H. salinarum cells. Total activity was determined using phenylethylamine that stabilizes radioactive counts [57]. D. salina and H. salinarum cells were collected by 2 µm and 0.22 µm filtration, respectively, and washed in 200 g/L saline. ¹⁴C uptake was halted with 250 µL 6 M HCl, incubated at room temperature (RT) for 30 min and prepared for counting with the addition of Ecosint (National Diagnostics). Samples were counted (disintegrations per minute, DPM) using a Tri Carb 2810 TR (Perkin Elmer) scintillation counter and carbon incorporation calculated according to [58] with modifications.

D. salina glycerol production and release

Glycerol, an important constituent of DOM in hypersaline environments [26], was measured as follows. For bulk glycerol release experiments, 2 ml samples from pure D. salina and D. salina plus H. salinarum co-cultures were collected in 14 mL falcon tubes at each time point. A 500 µL aliquot was removed and fixed in paraformaldehyde to a final concentration of 0.1% for cell counting via a hemocytometer and flow cytometry. One-mL of the remaining sample was centrifuged (3500 rcf) for 15 min and the supernatant removed for extracellular glycerol measurements. The D. salina cell pellet was resuspended in 500 µL ddH₂O to lyze cells and release intracellular glycerol. Glycerol measurements were done using a free glycerol detection kit (Sigma F6428) as per the manufacturer's instructions.

Transcriptional response of H. salinarum to D. salina dissolved organic matter (DOM)

Microarrays were generated at the Institute for Systems Biology Microarray Facility and processed according to standard protocols [59]; [60]. Each microarray slide contained 70mer oligonucleotides for each of the 2400 genes of Halobacterium salinarum [61] spotted in quadruplicate at two spatially distinct locations. Labeling, hybridization and washing were performed as described previously [31]. Statistical significance of differential gene expression was determined using the maximum likelihood method [62]. Data reported in this paper has been deposited in the Gene Expression Omnibus (GEO) database record GSE45752 (http://www.ncbi.nlm.nih.gov/geo/query/acc.cgi?acc=GSE45752).

Growth model

A growth model for both pure and co-cultures of D. salina and D. salina + H. salinarum was developed using the technical computing environment MATLAB (Mathworks, Inc.). The model was defined as a single birth-death ODE for the change in total cell density,(1)with light irradiance,(2)a “memory” variable,(3)and parameters γ, δ, and κ representing the maximum cell growth rate, cell death rate, and a saturation scaling factor, respectively.

Cellular growth, defined by the first term of Eq. (1), only allows N to increase during the light phase (I = 1) with a saturation level defined by κM (a Droop growth model) [65]. Importantly, Eq. (3) is such that for light phases, providing a constant saturation threshold therein. Conversely, M resets to the value of N during dark phases. Thus, M allows the saturation level to increase with each diurnal cycle, a characteristic observed in experimental data. Cell death, defined by the second term of Eq. (1), only occurs during the dark phase (I = 0), and is modeled as simple exponential decay based on the assumption that the cells have little to no tolerance to darkness.

Light irradiance (I, Eqn. (2)) was simulated as a square wave over a range of 0 (dark) and 1 (light) with a duty cycle equivalent to the nominal experimental photocycle of 13 hr∶11 hr light∶dark (45.8%).

The model was fit to experimental data by iteratively adjusting the values of γ, δ and κ until the sum of squared errors between the predicted trajectory for N (numerical solution of Eqns. (1)–(3)) and experimental data was minimized. Model fits were done individually on each experimental replicate within each culture set to generate statistics for each parameter.

Microbial organisms (chlorophytes and bacteria) in the Great Salt Lake

The enriched algal population (Fig. S1A)was identified as predominantly belonging to Dunaliella spp, single-celled wall-less photosynthetic chlorophytes, specifically D. salina, D. pseudosalina, D. viridis, D. parva, and a few other species (Fig. 1B; Fig. S2, A & B). The microbial populations were all confirmed as halobacteria, with several direct matches to H. salinarum (Fig. S2 C), a halophilic photoheterotrophic archaeon that thrives over a wide range of salinity (135–300 PSU). These results confirm that Dunaliella spp co-exist with diverse halobacteria in the South Arm of the GSL [24]. Dunaliella spp density fluctuated over several months between 10³–10⁸/L and the density of haloarchaea fluctuated between 10⁶ and 10⁹/ml. Thus we choose D. salina and H. salinarum as a model system to study their interaction in laboratory experiments.

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Figure 1. Cell death upon exposure to darkness or H.salinarum cells triggers the release of glycerol by D. salina.

(A) D. salina accumulates and utilizes glycerol as an osmoprotectant in hypersaline growth conditions. Accumulation of glycerol in D. salina cultures is correlated to increasing salinity in the growth medium peaking at 150 PSU (inset). (B) D. salina releases glycerol by cell death. Illustrated and merged phase contrast/fluorescence photomicrographs of a D. salina cell undergoing cell death. D. salina stores glycerol and other byproducts of photosynthesis inside secretory vesicles that are localized to the apical flagellar pole (top). The green color of the vesicles is due to quinacrine staining of glycerol and the red fluorescence corresponds to chloroplasts. The image show dramatic disruption of the cell membrane and complete loss of internal glycerol in a cell that has undergone cell death (bottom). (C) A shift of live light acclimated cultures (100–150 µmol-photon m⁻²sec⁻¹) to complete darkness (0 µmol-photon m⁻² sec⁻¹) results in release of glycerol by D. salina. The intracellular glycerol is measured by flow cytometry analysis of quinacrine stained vesicles D. salina cells. (D) Representative confocal laser micrograph of D. salina cells stained with FITC-Annexin V to highlight the externalization of PS (green fluorescence), and red corresponds to red chlorophyll autofluorescence. (E) Representative confocal laser micrographs of dead D. salina stained with FITC-Annexin V and SYTOX® blue highlighting PS completely externalized and the ejection of the nucleus indicating cell death.

https://doi.org/10.1371/journal.pone.0062595.g001

Mechanism of DOM production by D. salina

The mechanism for release of photosynthetically sequestered C by D. salina, the predominant primary producer in halophilic environments [24], [26], was investigated. In response to routine increases in salinity, D. salina enhances CO₂ assimilation to produce and store glycerol for use as an osmoprotectant [66]. This was corroborated here and glycerol production by D. salina peaked at its preferred salinity range between 150–200 PSU (Fig. 1A). Microscopy and quinicrine fluorescence revealed that glycerol stores are localized in vesicles (Fig. 1B) in D. salina. It is known that moieties for export are stored in vesicles [16], [67] and in natural settings, up to 17% of this glycerol reserve is released along with other uncharacterized metabolites into the environment [26].

To characterize the timing of glycerol release as a proxy of DOM release with respect to the diurnal cycle, intracellular glycerol was measured during the transition from day to night. There was a precipitous drop in intracellular glycerol upon transfer of light acclimated(≥150 µmol photon m⁻² s⁻¹) culture to complete darkness (0 µmol photon m⁻² s⁻¹) [40] (Fig. 1 B & C and Video S1). A high percentage of cells releasing glycerol and other uncharacterized C and N metabolites died during this process and exhibited membrane damage. The percentage of FITC-annexin V in combination with SYTOX® blue labeled cells (Fig. 1 D & E) detected the externalization of PS, confirming that 65+/−15% of cells were undergoing PCD. The proportion of apoptotic cells increased after the onset of darkness with a mean value of 59%. Previous observations also revealed that D. salina cells undergo PCD when placed in complete darkness and that this process is blocked by inhibitors of caspases, which are the effectors of apoptosis [40]. The cells stained with FITC-Annexin V showed the range of PCD-related morphological changes, from membrane blebbing to ejection of the cell nucleus followed by complete dissolution of the cells into the media (Fig. 1 E & F, and Video S1). In addition, a one-to-one correlation between numbers of cells undergoing PCD and amount of extracellular glycerol was observed (see below). These findings indicate that glycerol and other uncharacterized PCD materials are released by active cell death in D. salina in hypersaline environments. The stimulus for PCD and subsequent glycerol and DOM release was the onset of darkness.

Duirnally synchronized syntrophic interaction between D. salina and H. salinarum

Neither the MM1 media nor glycerol supplementation alone supported H. salinarum growth. The PCD supernatant from the D. salina culture containing DOM (glycerol, plus unknown C and N containing nutrients not measured), on the other hand, was nearly as supportive of haloarchael growth as MM1 supplemented with amino acids (Fig. 2). Thus, DOM released by diurnally synchronized cultures of D. salina fully complements nutritional requirements of H. salinarum.

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Figure 2. Dissolved organic material (DOM or photosynthate) released by D.salina fully complements nutritional requirements of H. salinarum.

Supernatant of D. salina culture in artificial seawater (MM1) supported H. salinarum growth at a level that was comparable to its growth in MM1 supplemented with amino acids at naturally occurring concentrations.

https://doi.org/10.1371/journal.pone.0062595.g002

Next, the hypothesis that D. salina benefits from its association with H. salinarum was explored. The intracellular glycerol concentration in both pure and co-cultures cultures, showed a slight drop in concentration during the night, and ranged between 5–2 M over the three day experiment (Fig. 3A). While the extracellular glycerol and possibly other nutrients in the DOM accumulated in both cultures over time, the rate of accumulation was significantly slower in co-cultures with H. salinarum relative to pure cultures of D. salina (Fig. 3B). This slower accumulation of glycerol and nutrients in co-cultures was partly explained by radioisotope incorporation and tracing, which revealed that a) D. salina incorporated its own released DOC (dissolved organic carbon) at night when in pure culture (Fig. 3C) and that b) H. salinarum incorporated ¹⁴C-labeled nutrients from the algal DOM and released metabolized products. However, H. salinarum did not incorporate NaH¹⁴CO₃ by itself (Fig. 3D). Subsequently at night D. salina re-assimilated DOM, specifically dissolved carbon, in the presence of haloarchaea as shown by at least two-fold higher productivity (C/cell/h) relative to pure culture (Fig. 3C). This is consistent with the heterotrophic capabilities of Dunaliella spp. [68] and known abilities of other marine microalgae to nocturnally assimilate organic compounds suggesting that this might be a general behavior and not unique to hypersaline algae [69].

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Figure 3. Diurnally synchronized syntrophic interaction with H.salinarum increases productivity of D. salina.

(A) Intra- and (B) extra-cellular glycerol concentrations in D. salina culture individually (blue) or with H. salinarum (red) over several day: night cycles, dash lines represent +/− standard deviation. (C) Radiolabel incorporation and tracing shows daytime uptake and nighttime release of ¹⁴C by D. salina. Uptake of ¹⁴C by D. salina at night is enhanced two-fold in co-cultures relative to pure cultures indicating nighttime assimilation of ¹⁴C in presence of H. salinarum. (D) Simultaneous tracing of C within H. salinarum cells demonstrates uptake and processing of ¹⁴C in sync with the diurnal cycle.

https://doi.org/10.1371/journal.pone.0062595.g003

To understand the implications of darkness induced cell death on algal population dynamics we constructed a growth model from experimental measurements of total cell counts (see methods) (Fig. 4A). The fitted parameters are shown in Table 1. The R-squared values (adjusted for degrees of freedom) for model fits to experimental data were 0.794+/−0.04 (s.e.m.) for pure and 0.702+/−0.09 (s.e.m.) for co-cultures. Our previous experimental data shows cell death during nighttime (Fig. 4A & C). Our model predicts that this occurs exponentially, and that the rate of decay is significantly faster (p<0.05) in co-culture (t_1/2 = 5.9+/−1.4 hrs) than in pure culture (t_1/2 = 10.1+/−2.8 hrs). Furthermore, the addition of increasing amounts of H. salinarum to D. salina cultures showed that H. salinarum independently induces algal cell death (Fig. 4B and Video S2). When daylight returns, surviving cells resume growth, saturating after a few divisions. Notably, the light induced burst growth rate is similar for both pure (t_doub = 1.1+/−0.6 hrs) and co-cultures (t_doub = 1.3+/−0.6 hrs). This process iterates over sequential day/night cycle resulting in daytime regeneration and nighttime drops in the algal population. Overall, both pure and co-cultures maintain a net positive growth rate, with the algal population doubling approximately every 13 hrs and 20 hrs in pure and co-culture, respectively, consistent with previously reported growth rates for D. salina [70].

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Figure 4. Cell death is triggered at nighttime as part of the diurnal synchronized program of D.salina.

(A) Cell numbers for D. salina in pure and co-cultures with H. salinarum over several diurnal cycles. Live cell concentration measured using flow cytometry are indicated with blue (pure culture) and red (co-culture) points while lines are fitted model simulations. Green boxed region indicates time frame reported in Fig. 3D over which caspase-3 activity was assayed. (B) H. salinarum induces cell death in D. salina under continuous light regime. Intracellular glycerol within D. salina was stained with quinacrine and quantified with flow cytometry. Decrease of intracellular glycerol proportionally with higher cell density of H. salinarum. Unstimulated (pure D. salina culture and dark shifted samples are shown as controls. (L/L>L, cultures grown on a 24 h constant light regime maintained in the light during the measurements, LL>D, cultures grown in constant light shifted to dark conditions (0 µmoles m²s⁻¹). (C) The decrease in D. salina cell number in the model (Fig. 4A (blue line) due to cell death is supported by the time course of annexin V labeled cells (blue line) indicating percentage of cells exhibiting externalization of PS and SYTOX® blue stained cells indicating the percent dead cells (red line). (D) The decrease in cell number in the model (blue dotted line) due to cell death is also supported by higher levels of caspase-3 during nighttime. Red line is Savitsky-Golay smoothed (span of 5) average of two replicate measurements for each time point.

https://doi.org/10.1371/journal.pone.0062595.g004

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Table 1. Initial and fitted parameter values for model of growth for pure D. salina and D. salina + H. salinarum co-cultures.

https://doi.org/10.1371/journal.pone.0062595.t001

Furthermore, the D. salina cells externalized PS (a marker of PCD) a few hours before the actual death, the cells start dying just before the night period starts, with a peak immediately after the lights change into the dark period. These data indicate that death occurs at night, while cell numbers double during the day (Fig. 4C). This was also confirmed by measurements of caspase-3 activity, which were higher during times of cell death and low during the growth phase (Fig. 4D), and the morphological changes (Fig. 1D & E). Importantly, the intracellularly measured glycerol (∼4 M, assuming a volume of a secretory granule = 1 µm [71]) content in D. salina combined with the number of cells observed to undergo nocturnal cell death (∼3×10⁵ mL⁻¹) accounted for the majority of the extracellularly measured glycerol (∼70 µM).

We also analyzed the transcriptional response of H. salinarum when challenged with the DOM released by D. salina (Fig. 5). At least 50 genes were differentially expressed and upregulated, of which nearly half are not annotated and are of unknown function [72], [73]. Those that had some putative functional assignment were mostly up regulated and included genes for siderophore biosynthesis, proteases, transport, metabolism, and cell division. Differential expression of a subset of these functional categories is consistent with known mechanisms for stimulation of algal productivity, nutrient uptake, and growth [74]. Similarly, up regulation of DMSO fermentation enzymes [75] and cytochrome oxidase suggests putative energy production mechanisms in haloarchaea engaged in this interaction, although DMSO production by D. salina is yet to be demonstrated. The upregulation of hemolysin a pore forming enzyme damaging to chlorophyte membranes may have accelerated D. salina's cell death. Furthermore the induction of a putative protein transporter, hydrolases and several proteases might be important for the hydrolysis of macromolecular components in the algal photosynthate. Notably, proteases and other hydrolytic enzymes are known to be abundant in the marine and freshwater DOM [2], 76 In terms of the physical architecture of this interaction, we also observed that haloarchaeal cells were often physically associated with the algal cells both in co-cultures of laboratory strains and in the natural environment (Fig. S3 A and B), analogous to cellular interactions observed in the phycosphere [77], [78].

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Figure 5. Mechanisms of communication and interactions in the syntrophic interaction.

Transcriptional response of H. salinarum NRC-1 to D. salina conditioned artificial seawater amended with nutrients (MM1).

https://doi.org/10.1371/journal.pone.0062595.g005