Skip to main content

Thank you for visiting You are using a browser version with limited support for CSS. To obtain the best experience, we recommend you use a more up to date browser (or turn off compatibility mode in Internet Explorer). In the meantime, to ensure continued support, we are displaying the site without styles and JavaScript.

Molecular chaperone accumulation as a function of stress evidences adaptation to high hydrostatic pressure in the piezophilic archaeon Thermococcus barophilus


The accumulation of mannosyl-glycerate (MG), the salinity stress response osmolyte of Thermococcales, was investigated as a function of hydrostatic pressure in Thermococcus barophilus strain MP, a hyperthermophilic, piezophilic archaeon isolated from the Snake Pit site (MAR), which grows optimally at 40 MPa. Strain MP accumulated MG primarily in response to salinity stress, but in contrast to other Thermococcales, MG was also accumulated in response to thermal stress. MG accumulation peaked for combined stresses. The accumulation of MG was drastically increased under sub-optimal hydrostatic pressure conditions, demonstrating that low pressure is perceived as a stress in this piezophile, and that the proteome of T. barophilus is low-pressure sensitive. MG accumulation was strongly reduced under supra-optimal pressure conditions clearly demonstrating the structural adaptation of this proteome to high hydrostatic pressure. The lack of MG synthesis only slightly altered the growth characteristics of two different MG synthesis deletion mutants. No shift to other osmolytes was observed. Altogether our observations suggest that the salinity stress response in T. barophilus is not essential and may be under negative selective pressure, similarly to what has been observed for its thermal stress response.


It is now well established that the majority of life on Earth dwells in the depth, in the so-called “Deep-Biosphere”, although due to the difficulties accessing those there is only scarce information on how the ecosystems function. Amongst deep-biosphere ecosystems, hydrothermal vents are one of the most intriguing. Hydrothermal vent fluids form when seawater enters cracks in the substratum near spreading ridges. During its interaction with the warm basalt, the water gets saturated with minerals, which composition will vary with the substratum1. Hydrothermal fluids are eventually forced out from the seafloor. Upon release in the ocean, the warm fluid gets into contact with the cold, oxidized ocean waters, creating a very sharp gradient in temperature, salinity, and redox potential over a few centimeters2,3,4. Despite these extremely variable environmental conditions, microbial life is thriving in the hydrothermal fluids. Thus, it is expected that microorganisms from hydrothermal vents express a strong stress adaptation in order to live in these steep gradients.

The effects of salinity and thermal stresses on cells and biological macromolecules are essentially negative, e.g. destabilization of the function and structure of cellular components or inward/outward fluxes of cellular salts. Two strategies of osmoadaptation to salinity have been demonstrated in prokaryotes5. Extremely halophilic Archaea and a few halophilic Bacteria accumulate K+, Na+ and Cl in response to changes in extracellular salinity6,7,8, while a common strategy among microorganisms to cope with osmotic stress will involve the accumulation of low-molecular-mass organic compounds, also named compatible solutes because they do not interfere with cellular metabolism9,10,11. Compatible solutes can be sugars, amino acids, polyols and are shared between thermophiles and mesophiles. Hyperthermophiles and thermophiles also accumulate very specific solutes little or never encountered in mesophiles: mannosylglycerate (MG), which is accumulated by hyperthermophilic Archaea and thermophilic Bacteria12; di-myo-1,3′-inositol phosphate (DIP)13, which is restricted to the domain Archaea with the exception of two hyperthermophilic bacterial genera, i.e. Thermotogales and Aquificales14,15,16,17; diglycerol phosphate and derivatives of these compounds5,18. MG is accumulated in response to high salinity. Cellular concentrations exceed 0.6 μmol/mg of proteins in Thermococcales12,19,20,21. MG is synthesized in four steps from mannose-6P by proteins encoded by a four-gene cluster which is strongly conserved in the Thermococcales, to the exception of the T. kodakarensis species which genome lacks the entire locus (Fig. 1). DIP accumulates in response to high temperature stress to cellular concentrations in excess of 1 μmol/mg of proteins12,21. Thus, MG and DIP have been proposed to be key players in osmo- and thermo-protection in hyperthermophiles respectively12,22.

Figure 1

MG synthesis pathway (A, adapted from ref. 20) and genetic organization (B).

In the deepest parts of the oceans, hydrothermal vent ecosystems are also submitted to extremely high hydrostatic pressures (HHP)23,24. Several microbial species adapted to extreme pressures (piezophiles) have been isolated from various deep-sea hydrothermal vents over the last decades2,25,26,27,28. The first piezophilic hyperthermophilic isolate was Thermococcus barophilus strain MP, isolated from the Snake Pit hydrothermal vent system (3,550 m depth) on the Mid-Atlantic Ridge, which grows optimally at 40 MPa, 85 °C and 3% salinity26. More recently, Pyrococcus yayanosii strain CH1, an obligate piezophilic hyperthermophile was isolated from the Ashadze hydrothermal vent site, also on the Mid-Atlantic Ridge27,29. To date, the genetic bases of the adaptation to HHP in these piezophiles remain unknown30,31.

The impact of pressure bears resemblance to both a lowering of temperature and an increase in temperature, since it will reinforce the structure of some molecules, such as membrane lipids, but will as well destabilize other structures, such as proteins30,32,33. In some ways, it also bears resemblance to salinity stress. Since HHP will antagonize or emphasize the impact of thermal and salinity stresses on cells, it has been proposed that HHP may influence the cellular response to stress in piezophiles34,35,36. The presence of DIP and MG synthesis genes in the genomes of the two known hyperthermophilic piezophiles, T. barophilus and P. yayanosii37,38, suggests that the stress response in these organisms could rely on the same bases as in other Thermococcales. However, recent investigations of the thermal stress response in T. barophilus showed that this strain is unable to synthesize DIP, due to a four-gene insertion between the IPS and IMPCT/PIPS genes36. These genes code for an Inositol-1-phosphate synthase and a bifunctional CTP:Inositol-1- phosphate cytidylyltransferase/Phospho-di-inositol-1-phosphate synthase, respectively responsible for the first two steps of DIP synthesis. The MG synthesis cluster in T. barophilus is also interrupted by a 17kb insertion between the MPGS and MPGP encoding genes (Fig. 1), which might also significantly affect the expression of MG synthesis genes, and consequently the salinity stress response of T. barophilus. These two genes encode the proteins responsible for the last two steps of MG synthesis20. Thus, whether MG is accumulated in T. barophilus in response to salinity stress, thermal stress, or both stresses as has been observed in P. ferrophilus, remained to be determined.

To address this question, we have investigated the effect of HHP on the salinity and thermal stress response of Thermococcus barophilus strain MP26. We show here that MG is accumulated primarily in response to salinity stress in T. barophilus. Stress response and the accumulation of MG peaked at low pressure, which clearly demonstrates the protective effect of HHP against salt and thermal stresses and a physiological adaptation to HHP of the T. barophilus proteome.


Characterization of the response to salt and heat stress in T. barophilus

Salinity, and combined thermal/salinity/pressure stress conditions for T. barophilus were optimized in order to achieve comparable growth parameters under both sub-optimal and supra-optimal conditions. The detailed procedure and results are described in the Supplementary Material (Table S1). Our results show that the high hydrostatic pressure had no impact on the optimal temperature or salinity for T. barophilus. Sub-optimal and supra-optimal salinity stresses were 1% and 4% salinity. These conditions resulted in a 12 h growth lag in cultures but had little impact on the final growth yields. Organic solutes were extracted from T. barophilus cells grown under sub-optimal, optimal and supra-optimal conditions in temperature (80 °C, 85 °C, 90 °C respectively), salinity (1%, 3%, 4% NaCl) and hydrostatic pressure (0.1 MPa, 40 MPa, 70 MPa), representing a total of 27 different growth conditions. The ethanol extracts were examined by natural abundance 1H- and 13C-NMR for the presence of MG. The 1H- and 13C-NMR spectra showed peaks corresponding to α-mannosyl-glycerate, easily identified by comparison with those of the literature39. The specific assignments of MG are reported on the 1H-13C HMQC spectra (Figure S1). 2D-NMR (HMBC and HMQC) spectra were acquired to confirm the structure of the putative MG present in T. barophilus extracts. The 1H-13C HMQC and HMBC spectra revealed the shift of the anomeric carbon (1H resonance at 4.92 ppm and 13C resonance at 100.1 ppm) which confirms the identification of this compound as MG. As expected from previous studies36, DIP was detected under none of the conditions tested in this study.

Quantification of MG accumulation at optimal pressure under salinity and thermal stresses

Under optimal pressure and temperature growth conditions, i.e. 40 MPa and 85 °C respectively, MG was detected only for supra optimal salinities, e.g. 4 and 5% NaCl (Fig. 2, green rectangle). The absolute concentration of MG in cells reached 0.12 μmol/mg proteins for both conditions. At optimal pressure and salinity (Fig. 2, red rectangle), MG was not detected under standard thermal stress conditions (90 °C36). Under thermal stress conditions corresponding to the upper growth temperature limit for that species, e.g. 98 °C, MG accumulation was detected at very low levels (0.06 μmol/mg proteins). When grown under both thermal and salinity stresses, MG was detected only under high salinity stress whatever the temperature tested. Its production peaked at 0.33 μmol/mg of proteins for a NaCl concentration of 4% and a temperature of 90 °C. Temperature higher than 90 °C could not be tested at or above 4% salinity for lack of growth of strain MP.

Figure 2: MG accumulation in T. barophilus as a function of pressure, in response to salt and temperature stress.

Thermal stress conditions under optimal salinity (3% NaCl) and pressure (40 MPa) conditions for growth are highlighted by a red rectangle. Salinity stress conditions under optimal temperature (85 °C) and pressure (40 MPa) are highlighted by a green rectangle. NG (No growth) P/T/salinity combination incompatible with growth of T. barophilus, e.g. 98 °C at atmospheric pressure. NA: Not analyzed.

Effect of hydrostatic pressure on the salinity and thermal stress response in T. barophilus

Under sub-optimal pressure conditions and under optimal salinity and temperature conditions (85 °C, 3%NaCl, 0.1 MPa, Fig. 2), MG is accumulated at 0.30 μmol/mg of proteins, a level comparable to the highest MG accumulation observed under optimal growth pressure. The salt stress response in T. barophilus at low pressure is similar whatever the temperature tested. No MG was detected at low salinity; while the MG accumulated at 4% NaCl was almost two folds that accumulated at “optimal” salinity. MG accumulation peaked for the combined high salinity and high temperature stress to reach 0.6 μmol/mg of proteins.

Under supra-optimal pressure conditions, MG was almost never detected in the cells. In fact, MG was accumulated to levels close to the detection limit between 0.024 and 0.03 μmol/mg of proteins, only under high salt stress. Due to the very limited amount of MG accumulated at supra-optimal pressure, it is difficult to ascertain whether its accumulation in the cells of T. barophilus followed the same trend at supra-optimal pressure as is observed for the other two pressure conditions, although the detection of MG only under the conditions yielding the highest accumulation at sub-optimal and optimal pressures would be consistent with such a scenario. Noticeably however, there is a marked negative correlation between pressure and MG accumulation in response to salt and heat stresses in T. barophilus.

Salinity and thermal stress response of MG-deficient mutants of T. barophilus

Regardless of the accumulation pattern of MG, which exhibits a typical stress response, the absolute levels of MG accumulated in the cells remained low in comparison to other Thermococcales, raising questions about the role of MG and other organic solutes in the stress response of T. barophilus. To understand the contribution of MG in salt or thermal adaptation, two mutants lacking MG synthesis were constructed in the ∆pyrF derivative of T. barophilus40. In Tb∆MGPS, MGPS, the isolated gene of the pathway, which encodes the third enzyme of the MG pathway catalyzing the conversion of GDP-mannose to mannosyl-3-phosphoglycerate, was deleted (Fig. 1); while in Tb∆MPGP the first gene of the operon, which encodes the last enzyme of the MG synthesis pathway catalyzing the conversion of mannosyl-3-phosphoglycerate to mannosylglycerate, was deleted. Both mutants showed lower growth rates under combined salinity and thermal stress conditions (90 °C and 4% NaCl) at 0.1 MPa, while the Tb∆MPGP mutant also showed reduced growth under optimal growth conditions (Table 1). Growth yields were essentially unaffected at 24 or 48 h (Table S2), although some small but reproducible differences could be observed when the cells were subcultured from sub-optimal salinity to supra-optimal salinity stress conditions (Table S3). As expected, no MG synthesis could be detected in the two mutants under any of the pressure, temperature and salinity combinations tested, while MG synthesis could be detected at wild-type levels in the ∆pyrF parent strain. In this later strain, MG accumulation peaked at similar concentration for combined temperature and salinity stress (0.59 and 0.62 μmol/mg of proteins, respectively). Interestingly, the accumulation of the last intermediate in MG synthesis, e.g. mannosyl-3-phosphoglycerate, was detected at a very low level (0.0011 μmol/mg of proteins) in the Tb∆MPGP mutant for combined temperature and salinity stress.

Table 1 Growth rate of wild-type T. barophilus (WT), Tb∆MPGP and Tb∆MPGS mutants at atmospheric pressure under optimal temperature and salinity conditions (85 °C and 3% NaCl), and temperature and salinity stress conditions (90 °C and 4% NaCl).

Accumulation of compatible solutes in wild-type and MG-deficient mutants of T. barophilus

Aspartate and glutamate have been previously shown to accumulate in Thermococcales to compensate for the absence of DIP synthesis41,42. To evaluate the possibility of cross compensation of the lack of MG accumulation by other organic solutes, we quantified the accumulation of aspartate and glutamate in T. barophilus cells. In the wild-type T. barophilus cells grown under optimal conditions, aspartate, glutamate and total organic solutes were present at 0.07, 0.14 and 0.31 μmol/mg of proteins respectively (Table 2). Variations of solutes concentrations under stress conditions are quite small. The total solute pool increases almost two times between optimal and combined salinity and thermal stresses. This increase is essentially due to the accumulation of MG, although aspartate accumulation is decreased slightly under thermal stress. In the Tb∆MPGP mutant, aspartate and glutamate concentration variations are also small. Aspartate concentrations decrease by a factor close to 2 under salinity stress, while glutamate concentrations tend to increase. As a consequence, the total pool of organic solutes remains stable under stress. In contrast, aspartate, glutamate and total solute concentrations decreased under stress in the Tb∆MGPS mutant (Table 2). Intracellular K+ content was determined for all pressure, temperature and salinity conditions of growth in T. barophilus MP, yielding no evidence of inorganic solute accumulation as a function of stress in T. barophilus (Table S4).

Table 2 Quantitation of compatible solutes in T. barophilus MP and the Tb∆MPGP and Tb∆MGPS mutants.


We have monitored the accumulation of organic solutes in the piezophilic hyperthermophilic Thermococcus barophilus strain MP to characterize the impact of hydrostatic pressure and piezophilic adaptation on the salinity and thermal stress response in deep hydrothermal vent organisms. MG was the only osmolyte detected that responded to environmental stresses in T. barophilus. This solute is accumulated preferentially in response to salinity stress and its peak concentration is observed under combined salt, low-pressure and temperatures stresses. MG was shown to accumulate also under the extreme thermal stress conditions under optimal temperature and salinity. Interestingly, MG accumulation was twice higher under low hydrostatic pressure conditions in comparison to optimal pressure, while its accumulation was barely detected under supra optimal conditions. Osmolytes, such as MG or DIP, accumulate during stress to protect the proteome from the deleterious effect of the reduced activity of water inside or in the vicinity of the cells. The exact molecular mechanisms for osmolyte is still a subject of debate, but it has been proposed that osmolytes accumulated during stress create a protective shell surrounding the proteins, which helps maintain proper folding and protein function43. An increase of MG accumulation under low pressure conditions clearly indicates that low pressure are perceived as stressful conditions by the cell proteins and that the stability of its proteome is compromised, e.g. that the T. barophilus proteome is low-pressure sensitive. These results confirm and extend previous observations which have shown the pressure-dependent induction of a heat shock protein in strain MP44.

In a simplistic scheme, the impact of hydrostatic pressure may be resumed to the Le Chatelier general law of chemical equilibrium, which implies that an increase in pressure will favor the smallest state in a chemical system45. Thus, if the volume of a protein is smaller in its native form than in its unfolded form, this protein will be stabilized by pressure, and destabilized if its native volume is larger. Protein tightening under pressure is often reported46. Bartlett and colleagues have shown that enhanced pressure tolerance in the SSB protein in the piezophilic strain SS9 of Photobacterium profundum is linked to amino acid substitutions leading to increased rigidity of the protein structure47. This adaptation mechanism is essentially similar to the increased rigidification of proteins observed in the presence of the osmolyte MG48. Thus, the accumulation of MG under low pressure conditions will tend to increase protein rigidity, suggesting that the proteome of T. barophilus is too flexible at atmospheric pressure. In contrast, the lower accumulation of osmolytes under optimal and supra-optimal pressure conditions in T. barophilus suggests that high-hydrostatic pressure enhances protein stability in this organism. These observations are consistent with recent measurements of the molecular dynamics of T. barophilus cells by Neutron Scattering which have evidenced the extreme flexibility of the proteome of T. barophilus at atmospheric pressure and the stabilizing effect of hydrostatic pressure on the proteome49. These experiments clearly identified two dynamic regimes for the proteome of T. barophilus. In the first one, at atmospheric pressure the proteome flexibility is extremely high. Increased protein flexibility is an important part of the adaptation to low temperature in psychrophiles since it will counteract the temperature-dependent reduction of the dynamics. However, this increased flexibility is usually restricted to the active sites of the protein50,51,52 since an increase of the flexibility is linked to lower stability of the proteins. Indeed, an increase of the overall flexibility can have a deleterious impact on protein activity53,54,55,56. Molecular dynamics study in T. barophilus demonstrate an increase of the whole protein flexibility, not only of the actives sites, and suggests that it might impact significantly the proteome functions49. Consistent with this hypothesis, T. barophilus cells were shown to express a stress protein at ambient pressure44. The accumulation of MG, which has been shown to increase protein rigidity, at atmospheric pressure would also be consistent with the need for the cell to reduce this flexibility to restore the activity of the proteome57. In the second regime, which happens above 20 MPa, the flexibility of the proteome is greatly reduced and remains almost unaffected by pressure up to 120 MPa. This clearly shows the stabilizing impact of hydrostatic pressure on the proteome of T. barophilus, as well as the stability of this proteome under high hydrostatic pressures. This is congruent with the observation that MG is accumulated at lower levels, and that no stress protein are produced under pressure. Together, the physiological and molecular dynamics data concur to demonstrate that the proteome of T. barophilus is adapted to high hydrostatic pressure, e.g. piezophilic.

MG accumulation in T. barophilus at peak concentration under combined salt, low-pressure and temperature stresses remains in the low range (0.6 μmol/mg proteins) when compared to values reported for other Thermococcales under the sole salinity stress, e.g. from ca. 0.25 to more than 1 μmol/mg of proteins in T. celer and P. furiosus respectively12,21. Indeed, under similar stress conditions, MG accumulation is only 0.21 μmol/mg protein. Other solutes such as aspartate and glutamate may also play a role in the stress response of Thermococcales. Aspartate and glutamate levels were ca. 3-fold higher under osmotic stress in T. litoralis21, while in T. kodakarensis, glutamate accumulated 9.8-fold, concomitantly with a 20-fold DIP level increase, in response to heat stress, and aspartate concentrations increased 4.3 fold under osmotic stress41. In contrast to these Thermococcales species, the intra-cellular concentrations of aspartate and glutamate varied only marginally under thermal or salinity stress conditions in T. barophilus (Table 2). We could not detect significant organic solute concentration variations in the NMR spectra acquired in any stress conditions, suggesting that no other compatible organic solute was accumulated in this species in response to stress. Furthermore, we could not detect any organic osmolyte accumulation in two MG-deficient mutant derivatives of strain MP, and inorganic compatible solutes, such as K+ ions, which are accumulated in halophilic and slightly halophilic strains to counterbalance the negative charges in the cells6 are not accumulated in response to stress in T. barophilus. Thus, these results suggest that the salinity stress response is not essential in the T. barophilus species. Together with the loss of the thermal stress response which has been already reported in this species36, these results suggest that the T. barophilus species might have developed a novel strategy to respond to stress. However, these observations could also show that this species is losing its ability to respond to salinity and thermal stresses.

To this date, the DIP and MG loci and DIP and MG accumulation patterns were extremely conserved in all Thermococcales. Previous exceptions to this trend were T. kodakarensis, which lacks the MG synthesis locus; Pyrolobus fumarii which only accumulates DIP as a response to both stresses but which genome is yet uncharacterized58 and Palaeococcus ferrophilus which lacks the DIP synthesis genes and accumulates only MG as a response to both stresses. In contrast to these three exceptions, T. barophilus harbors a complete set of DIP and MG genes, but each is interrupted by a large insertion, e.g. ca 5 and 17kb for DIP and MG synthesis respectively (Fig. 1)36. These insertions are a reasonable explanation for the lack of DIP synthesis in T. barophilus36 but may also explain the low levels of MG accumulation. In contrast to other Thermococcus species, T. barophilus is piezophile, a phenotype shared with P. ferrophilus the other strain known not to accumulate DIP19,59. The lack of DIP accumulation in these two species was proposed to result from their adaptation to high hydrostatic pressures36. The rationale for this proposition relies on the overlaps existing between the impact of both stresses on proteins and on their antagonizing effects on biomolecules. Interestingly, the piezophilic Thermotogales species, Marinitoga piezophila, also lacks the DIP synthesis genes60 and accumulates only amino acids under tress conditions17. Thus, it is very tempting to try to link the low accumulation of organic solutes in T. barophilus and the piezophily of its proteome. The marginal impact of the disruption of MG synthesis in the MPGP and MGPS mutants is consistent with this view. Furthermore, and in contrast to other Thermococcales41, we observed no shift of the accumulation to other organic or inorganic solutes under stress, suggesting that stress response was not required for growth in T. barophilus. The observed accumulation of MG as a response to stress in wild-type T. barophilus may be a reminiscence of the salinity stress response of Thermococcales and an indication that MG has become non-essential only recently during the evolution of this species. Further experiments with DIP and MG synthesis knock-out mutants of other piezophilic hyperthermophiles, especially on the newly isolated obligate piezophile Pyrococcus yayanosii strain CH1, which cannot grow at atmospheric pressure27, would be required to confirm these hypotheses.


Microorganism and growth conditions

Thermococcus barophilus strain MP was grown in Thermococcales Rich Medium (TRM)27. The salinity of the medium was adjusted from 0 to 6% for salt-stress experiments. All cultures were performed under strict anaerobic conditions obtained by headspace substitution to N2 and by addition of Na2S.9H2O, pH = 7.2, to a final concentration of 0.1%. Cultivation at low pressure was performed in sealed serum vials while cultures under HHP were performed in sterile syringes as previously described26. Cultures were inoculated with 0.5% (v,v) of a glycerol stock, stored anaerobically at −80 °C at a starting cell concentration of 5.105 cells per milliliter. To increase experimental reproducibility, the same inoculum was used for all cultures. Cultures were grown under 3 pressure conditions (0.1, 40 and 70 MPa), temperatures ranging from 75 to 98 °C and salinities ranging from 0 to 6% NaCl. Cell growth was monitored by direct cell counts in a Thoma chamber (depth, 0.01 mm) using a light microscope (BX41, Olympus) at regular intervals: 0, 12, 24, 48 and 72 h. Experiments were performed in triplicate unless specified otherwise.

Extraction of intracellular solutes

1010 cells of T. barophilus were harvested during mid-exponential phase of growth by centrifugation (5,000 g, 15 min, 4 °C) and washed once with an isotonic NaCl solution. The washed cell pellets were extracted by the method of Reed61 except that the extraction was performed for 30 min in boiling 80% ethanol. Cells were removed by centrifugation 10 min at 12,000 g at 4 °C. Supernatants were transferred to a clean tube and dried in a rotary evaporator (IKA RV 10, Fisher Scientific, France) or lyophilized (Alpha 1–2 LDplus, Martin Christ, Germany). The dried residue was dissolved in D2O for further NMR analysis.

NMR spectroscopy

All spectra were acquired on a Bruker DRX 500 spectrometer at room temperature and 30° pulse. 1H-NMR spectra were acquired using a 5 mm TBI 1H/{BB}/13C probe. Organic solutes were quantified by adding Trimethylsilyl-2,2,3,3-tetradeutero-propionic acid (TSP) as an internal standard. For quantification, spectra were acquired with water presaturation and a delay of 10s for T1 relaxation time. 31P-NMR spectra were acquired at 202.5 MHz on the same probehead. 13C-NMR spectra were acquired at 125.8 Mhz on a AVANCE 500 Bruker spectrometer equipped with a TCI 1H/13C/15N 5mm probehead. Two-dimensional spectra (COSY, HMQC and HMBC) were acquired with the same spectrometer. The values were normalized to the total protein content of cells quantified by the Bradford assay62 after cell lysis with 1 M NaOH (100 °C, 10 min) and neutralization with 1 M HCl12. Osmolyte concentrations are expressed as μmol solute/mg of total proteins.

Extraction and determination of intracellular K+ content by ICP-AES

Cells of T. barophilus in mid-exponential phase were harvested by centrifugation (5,000 g, 15 min, 4 °C) and washed once in isotonic NaCl solution. Cell lysis was performed by boiling 30 min in distilled water. The supernatant was adjusted to 0.5 N HNO3 for inductively coupled plasma atomic emission spectrometry (ICP-AES) analysis. Calibration range was performed from 0 to 2 ppm. Scandium (1 ppm) was used as an internal standard.

Construction of MG synthesis deletion mutants

Deletion mutants of the MGPS and were obtained as described40. The complete ORF of each gene was removed, to avoid polar effects on the downstream genes. The selection of mutants was performed under pressure, temperature and salinity conditions under which MG was not accumulated in the parental strain, e.g. low pressure, 85 °C and 1% NaCl. Proper deletion was confirmed by sequencing using primers located next to the deletion (Table S5).

Additional Information

How to cite this article: Cario, A et al. Molecular chaperone accumulation as a function of stress evidences adaptation to high hydrostatic pressure in the piezophilic archaeon Thermococcus barophilus. Sci. Rep. 6, 29483; doi: 10.1038/srep29483 (2016).


  1. 1

    Herzig, P. M. & Hannington, M. D. Input from the Deep: Hot Vents and Cold Seeps In Marine Geochemistry (eds Horst D. Schulz & Matthias Zabel ) pp. 457–479 (Springer: Berlin Heidelberg,, 2006).

  2. 2

    Jannasch, H. W. & Mottl, M. J. Geomicrobiology of deep-sea hydrothermal vents. Science 229, 717–725 (1985).

    CAS  ADS  Article  Google Scholar 

  3. 3

    Vondamm, K. L. & Bischoff, J. L. Chemistry of hydrothermal solutions from the southern Juan-de-Fuca ridge. J. Geophys. Res.-Solid Earth Planets 92, 11334–11346 (1987).

    CAS  Article  Google Scholar 

  4. 4

    Prieur, D. Microbiology of deep-sea hydrothermal vents. Trends Biotechnol. 15, 242–244 (1997).

    CAS  Article  Google Scholar 

  5. 5

    da Costa, M. S., Santos, H. & Galinski, E. A. An overview of the role and diversity of compatible solutes in Bacteria and Archaea. Adv. Biochem. Engin. Biotechnol. 61, 117–153 (1998).

    CAS  Google Scholar 

  6. 6

    Csonka, L. N. & Hanson, A. D. Prokaryotic osmoregulation - Genetics and physiology. Ann. Rev. Microbiol. 45, 569–606 (1991).

    CAS  Article  Google Scholar 

  7. 7

    Galinski, E. A. & Truper, H. G. Microbial behavior in salt-stressed ecosystems. FEMS Microbiol. Rev. 15, 95–108 (1994).

    CAS  Article  Google Scholar 

  8. 8

    Vreeland, R. H. Mechanisms of halotolerance in microorganisms. CRC Crit. Rev. Microbiol. 14, 311–356 (1987).

    CAS  Article  Google Scholar 

  9. 9

    Brown, A. D. Microbial water stress. Bacteriol. Rev. 40, 803–846 (1976).

    CAS  PubMed  PubMed Central  Google Scholar 

  10. 10

    Galinski, E. A. Osmoadaptation in bacteria. Adv. Microb. Physiol. 37, 272–328 (1995).

    CAS  PubMed  Google Scholar 

  11. 11

    Ventosa, A., Nieto, J. J. & Oren, A. Biology of moderately halophilic aerobic bacteria. Microbiol. Mol. Biol. Rev. 62, 504–522 (1998).

    CAS  PubMed  PubMed Central  Google Scholar 

  12. 12

    Martins, L. O. & Santos, H. Accumulation of mannosylglycerate and di-myo-inosytol-phosphate by Pyrococcus furiosus in response to salinity and temperature. Appl. Environ. Microbiol. 61, 3299–3303 (1995).

    CAS  PubMed  PubMed Central  Google Scholar 

  13. 13

    Rodrigues, M. V. et al. Bifunctional CTP: Inositol-1-phosphate cytidylyltransferase/CDP-inositol: Inositol-1-phosphate transferase, the key enzyme for di-myo-inositol-phosphate synthesis in several (hyper)thermophiles. J. Bacteriol. 189, 5405–5412 (2007).

    CAS  Article  Google Scholar 

  14. 14

    Martins, L. O., Carreto, L. S., DaCosta, M. S. & Santos, H. New compatible solutes related to di-myo-inositol-phosphate in members of the order Thermotogales. J. Bacteriol. 178, 5644–5651 (1996).

    CAS  Article  Google Scholar 

  15. 15

    Rodrigues, M. V., Borges, N., Almeida, C. P., Lamosa, P. & Santos, H. A unique beta-1,2-mannosyltransferase of Thermotoga maritima that uses di-myo-inositol phosphate as the mannosyl acceptor. J. Bacteriol. 191, 6105–6115 (2009).

    CAS  Article  Google Scholar 

  16. 16

    Lamosa, P. et al. Occurrence of 1-glyceryl-1-myo-inosityl phosphate in hyperthermophiles. Appl. Environ. Microbiol. 72, 6169–6173 (2006).

    CAS  Article  Google Scholar 

  17. 17

    Lamosa, P. et al. Organic solutes in the deepest phylogenetic branches of the Bacteria: identification of alpha(1-6)glucosyl-alpha(1-2)glucosylglycerate in Persephonella marina. Extremophiles 17, 137–146 (2013).

    CAS  Article  Google Scholar 

  18. 18

    Santos, H. & da Costa, M. S. Organic solutes from thermophiles and hyperthermophiles. Hyperthermophilic Enzymes, Pt C 334, 302–315 (2001).

    CAS  Article  Google Scholar 

  19. 19

    Neves, C., da Costa, M. S. & Santos, H. Compatible solutes of the hyperthermophile Palaeococcus ferrophilus: Osmoadaptation and thermoadaptation in the order Thermococcales. Appl. Environ. Microbiol. 71, 8091–8098 (2005).

    CAS  Article  Google Scholar 

  20. 20

    Empadinhas, N., Marugg, J. D., Borges, N., Santos, H. & da Costa, M. S. Pathway for the synthesis of mannosylglycerate in the hyperthermophilic archaeon Pyrococcus horikoshii - Biochemical and genetic characterization of key enzymes. J. Biol. Chem. 276, 43580–43588 (2001).

    CAS  Article  Google Scholar 

  21. 21

    Lamosa, P., Martins, L. O., Da Costa, M. S. & Santos, H. Effects of temperature, salinity, and medium composition on compatible solute accumulation by Thermococcus spp . Appl. Environ. Microbiol. 64, 3591–3598 (1998).

    CAS  PubMed  PubMed Central  Google Scholar 

  22. 22

    Ramos, A. et al. Stabilization of enzymes against thermal stress and freeze-drying by mannosylglycerate. Appl. Environ. Microbiol. 63, 4020–4025 (1997).

    CAS  ADS  PubMed  PubMed Central  Google Scholar 

  23. 23

    Yayanos, A. A. Microbiology to 10,500 metters in the deep-sea. Annu. Rev. Microbiol. 49, 777–805 (1995).

    CAS  Article  Google Scholar 

  24. 24

    Zobell, C. E. Bacterial life at the bottom of the Philippine trench. Science 115, 507–508 (1952).

    CAS  ADS  Article  Google Scholar 

  25. 25

    Marteinsson, V. T., Birrien, J. L., Kristjansson, J. K. & Prieur, D. First isolation of a thermophilic aerobic non-sporulating hetertotrophic bacteria from deep-sea hydrothermal vents. FEMS Microbiol. Ecol. 18, 163–174 (1995).

    CAS  Article  Google Scholar 

  26. 26

    Marteinsson, V. T. et al. Thermococcus barophilus sp. nov., a new barophilic and hyperthermophilic archaeon isolated under high hydrostatic pressure from a deep-sea hydrothermal vent. Int. J. Syst. Bacteriol. 49, 351–359 (1999).

    Article  Google Scholar 

  27. 27

    Zeng, S. et al. Pyrococcus CH1, an obligate piezophilic hyperthermophile : extending the upper pressure-temperature limits for life. ISME Journal 3, 873–876 (2009).

    CAS  Article  Google Scholar 

  28. 28

    Callac, N. et al. Pyrococcus kukulkanii sp. nov., a novel hyperthermophilic piezophilic archaeon isolated from a deep-sea hydrothermal vent at the Guaymas Basin. Int. J. Syst. Evol. Microbiol., doi: 10.1099/ijsem.0.001160 (2016).

  29. 29

    Birrien, J. et al. Pyrococcus yayanosii sp. nov., the first strict piezophilic hyperthermophilic archaeon isolated from a deep-sea hydrothermal vent. Int. J. Syst. Evol. Microbiol. 61, 2827–2881 (2011).

    CAS  Article  Google Scholar 

  30. 30

    Oger, P. & Jebbar, M. The many ways of coping with pressure. Res. Microbiol. 161, 799–809 (2010).

    Article  Google Scholar 

  31. 31

    Jebbar, M., Franzetti, B., Girard, E. & Oger, P. Microbial diversity and adaptation to high hydrostatic pressure in deep-sea hydrothermal vents prokaryotes. Extremophiles 19, 721–740 (2015).

    CAS  Article  Google Scholar 

  32. 32

    Balny, C., Masson, P. & Heremans, K. High pressure effects on biological macromolecules: from structural changes to alteration of cellular processes. BBA-Prot. Struct. Mol. Enzymol. 1595, 3–10 (2002).

    CAS  Article  Google Scholar 

  33. 33

    Michels, P. C. & Clark, D. S. Pressure-dependence of enzyme catalysis in Biocatalysis at Extreme Temperatures Vol. 498 ACS Symposium Series (eds M. W. W. Adams & R. M. Kelly ) pp. 108–121 (American Chemical Society, 1992).

    Article  Google Scholar 

  34. 34

    Vannier, P., Michoud, G., Oger, P., Marteinsson, V. þ. & Jebbar, M. Genome expression of Thermococcus barophilus and Thermococcus kodakarensis in response to different hydrostatic pressure conditions. Res. Microbiol. 166, 717–725 (2015).

    CAS  Article  Google Scholar 

  35. 35

    Cario, A., Grossi, V., Schaeffer, P. & Oger, P. Membrane homeoviscous adaptation in the piezo-hyperthermophilic archaeon Thermococcus barophilus . Front. Microbiol. 6, doi: 10.3389/fmicb.2015.01152 (2015).

  36. 36

    Cario, A., Mizgier, A., Thiel, A., Jebbar, M. & Oger, P. Restoration of the di-myo-inositol-phosphate pathway in the piezo-hyperthermophilic archaeon Thermococcus barophilus . Biochimie 118, 288–293 (2015).

    Article  Google Scholar 

  37. 37

    Xu, J. et al. Complete Genome Sequence of the Obligate Piezophilic Hyperthermophilic Archaeon Pyrococcus yayanosii CH1. J. Bacteriol. 193, 4297–4298 (2011).

    CAS  Article  Google Scholar 

  38. 38

    Vannier, P., Marteinsson, V., Fridjonsson, O., Oger, P. & Jebbar, M. Complete genome sequence of the hyperthermophilic piezophilic, heterotrophic and carboxydotrophic archaeon Thermococcus barophilus MP. J. Bacteriol. 193, 1481–1482 (2011).

    CAS  Article  Google Scholar 

  39. 39

    Nunes, O. C., Manaia, C. M., Dacosta, M. S. & Santos, H. Compatible solutes in the thermophilic bacteria Rhodothermus marinus and Thermus thermophilus . Appl. Environ. Microbiol. 61, 2351–2357 (1995).

    CAS  PubMed  PubMed Central  Google Scholar 

  40. 40

    Thiel, A., Michoud, G., Moalic, Y., Flament, D. & Jebbar, M. Genetic manipulations of the hyperthermophilic piezophilic archaeon Thermococcus barophilus . Appl. Environ. Microbiol. 80, 2299–2306 (2014).

    Article  Google Scholar 

  41. 41

    Borges, N., Matsumi, R., Imanaka, T., Atomi, H. & Santos, H. Thermococcus kodakarensis mutants deficient in di-myo-inositol phosphate use aspartate to cope with heat stress. J. Bacteriol. 192, 191–197 (2010).

    CAS  Article  Google Scholar 

  42. 42

    Esteves, A. M. et al. Mannosylglycerate and Di-myo-Inositol Phosphate Have Interchangeable Roles during Adaptation of Pyrococcus furiosus to Heat Stress. Appl. Environ. Microbiol. 80, 4226–4233 (2014).

    Article  Google Scholar 

  43. 43

    Lamosa, P., Turner, D. L., Ventura, R., Maycock, C. & Santos, H. Protein stabilization by compatible solutes–Effect of diglycerol phosphate on the dynamics of Desulfovibrio gigas rubredoxin studied by NMR. Eur. J. Biochem. 270, 4606–4614 (2003).

    CAS  Article  Google Scholar 

  44. 44

    Marteinsson, V. T. et al. Physiological responses to stress conditions and barophilic behavior of the hyperthermophilic vent archaeon Pyrococcus abyssi . Appl. Environ. Microbiol. 63, 1230–1236 (1997).

    CAS  PubMed  PubMed Central  Google Scholar 

  45. 45

    Le Chatelier, H. L. Sur un énoncé général des lois d'équilibres chimiques. C.-R Acad. Sci. 99, 786–789 (1884).

    Google Scholar 

  46. 46

    Eisenmenger, M. J. & Reyes de Corcuera, J. I. High pressure enhancement of enzymes: A review. Enz. Microb. Technol. 45, 331–347 (2009).

    CAS  Article  Google Scholar 

  47. 47

    Chilukuri, L. N., Bartlett, D. H. & Fortes, P. A. G. Comparison of high pressure-induced dissociation of single-stranded DNA. binding protein (SSB) from high pressure-sensitive and high pressure-adapted marine Shewanella species. Extremophiles 6, 377–383 (2002).

    CAS  Article  Google Scholar 

  48. 48

    Pais, T. M., Lamosa, P., Garcia-Moreno, B., Turner, D. L. & Santos, H. Relationship between protein stabilization and protein rigidification induced by mannosylglycerate. J. Mol. Biol. 394, 237–250 (2009).

    CAS  Article  Google Scholar 

  49. 49

    Peters, J. et al. Deep Sea Microbes Probed by Incoherent Neutron Scattering Under High Hydrostatic Pressure. Zeit. Physik. Chem.-Int. 228, 1121–1133 (2014).

    CAS  Google Scholar 

  50. 50

    Papaleo, E., Riccardi, L., Villa, C., Fantucci, P. & De Gioia, L. Flexibility and enzymatic cold-adaptation: a comparative molecular dynamics investigation of the elastase family. Biochim. Biophys. Acta 1764, 1397–1406 (2006).

    CAS  Article  Google Scholar 

  51. 51

    Lonhienne, T., Gerday, C. & Feller, G. Psychrophilic enzymes: revisiting the thermodynamic parameters of activation may explain local fexibility. Biochim. Biophys. Acta 1543, 1–10 (2000).

    CAS  Article  Google Scholar 

  52. 52

    Feller, G. Molecular adaptations to cold in psychrophilic enzymes. Cell. Mol. Life Sci. 60, 648–662 (2003).

    CAS  Article  Google Scholar 

  53. 53

    El-Turk, F. et al. The conformational flexibility of the carboxy terminal residues 105-114 is a key modulator of the catalytic activity and stability of macrophage migration inhibitory factor. Biochemistry 47, 10740–10756 (2008).

    CAS  Article  Google Scholar 

  54. 54

    Mulder, F., Schipper, D., Bott, R. & Boelens, R. Altered flexibility in the substrate-binding site of related native and engineered high-alkaline Bacillus subtilisins. J. Mol. Biol. 292, 111–123 (1999).

    CAS  Article  Google Scholar 

  55. 55

    Uversky, V. What does it mean to be natively unfolded? Eur. J. Biochem. 269, 2–12 (2002).

    CAS  Article  Google Scholar 

  56. 56

    Žoldák, G., Sprinzl, M. & Sedlák, E. Modulation of activity of NADH oxidase from Thermus thermophilus through change in flexibility in the enzyme active site induced by Hofmeister series anions. Eur. J. Biochem. 271, 48–57 (2004).

    Article  Google Scholar 

  57. 57

    Borges, N., Ramos, A., Raven, N. D. H., Sharp, R. J. & Santos, H. Comparative study of the thermostabilizing properties of mannosylglycerate and other compatible solutes on model enzymes. Extremophiles 6, 209–216 (2002).

    CAS  Article  Google Scholar 

  58. 58

    Goncalves, L. G., Lamosa, P., Huber, R. & Santos, H. Di-myo-inositol phosphate and novel UDP-sugars accumulate in the extreme hyperthermophile Pyrolobus fumarii . Extremophiles 12, 383–389 (2008).

    CAS  Article  Google Scholar 

  59. 59

    Takai, K., Sugai, A., Itoh, T. & Horikoshi, K. Palaeococcus ferrophilus gen. nov., sp nov., a barophilic, hyperthermophilic archaeon from a deep-sea hydrothermal vent chimney. Int. J. Syst. Evol. Microbiol. 50, 489–500 (2000).

    CAS  Article  Google Scholar 

  60. 60

    Lucas, S. et al. Complete genome sequence of the thermophilic piezophilic heterotrophic bacterium Marinitoga piezophila KA3. J. Bacteriol. 194, 5974–5975 (2012).

    CAS  Article  Google Scholar 

  61. 61

    Reed, R. H., Richardson, D. L., Warr, S. R. C. & Stewart, W. D. P. Carbohydrate accumulation and osmotic-stress in cyanobacteria. J. Gen. Microbiol. 130, 1–4 (1984).

    CAS  Google Scholar 

  62. 62

    Bradford, M. M. Rapid and sensitive method for quantfication of microgram quantities of protein utilizing priciple of protein-dye binding. Anal. Biochem. 72, 248–254 (1976).

    CAS  Article  Google Scholar 

Download references


The authors would like to thank Daniel Prieur, Jean-Louis Birrien and Anna-Louise Reysenbach for helpful discussions, and Hervé Cardon and Marc Moulin for skillful assistance with the high pressure devices. This work was supported in part by the Agence Nationale de la Recherche (ANR-10-BLAN-1752-01 Living deep) to PMO and MJ, and by the CNRS program PEPS ExoMod to PMO. AC was the recipient of a PhD grant from the Ministère de l’Enseignement Supérieur et de la Recherche. A.T. was supported by a postdoctoral fellowship from the Conseil Général 29 and from Ifremer.

Author information




A.C., M.J. and P.M.O. designed, performed and analyzed experiments. N.K. performed the NMR analyses. A.T. constructed the MG deletion mutants. All authors reviewed the manuscript.

Corresponding author

Correspondence to Phil M. Oger.

Ethics declarations

Competing interests

The authors declare no competing financial interests.

Supplementary information

Rights and permissions

This work is licensed under a Creative Commons Attribution 4.0 International License. The images or other third party material in this article are included in the article’s Creative Commons license, unless indicated otherwise in the credit line; if the material is not included under the Creative Commons license, users will need to obtain permission from the license holder to reproduce the material. To view a copy of this license, visit

Reprints and Permissions

About this article

Verify currency and authenticity via CrossMark

Cite this article

Cario, A., Jebbar, M., Thiel, A. et al. Molecular chaperone accumulation as a function of stress evidences adaptation to high hydrostatic pressure in the piezophilic archaeon Thermococcus barophilus. Sci Rep 6, 29483 (2016).

Download citation

Further reading


By submitting a comment you agree to abide by our Terms and Community Guidelines. If you find something abusive or that does not comply with our terms or guidelines please flag it as inappropriate.


Quick links

Nature Briefing

Sign up for the Nature Briefing newsletter — what matters in science, free to your inbox daily.

Get the most important science stories of the day, free in your inbox. Sign up for Nature Briefing