Microbial membrane lipid adaptations to high hydrostatic pressure in the marine environment

Tamby, Anandi; Damsté, Jaap S. Sinninghe; Villanueva, Laura

doi:10.3389/fmolb.2022.1058381

Cited by 17 publications

(9 citation statements)

References 66 publications

Supporting

Mentioning

Contrasting

Order By: Relevance

“…To counter the loss of membrane fluidity, microorganisms respond by increasing the proportion of unsaturated, short chain, and branched chain fatty acids in their membranes (Tamby et al, 2022 ). Here, the fadL (LFC −1.04) gene, encoding a long-chain fatty acid transport protein was downregulated, while three other genes involved in fatty acids synthesis including fabF_2, acpS and fabH2 , increased in expression ( p < 0.05) but did not surpass the LFC threshold of 1 (LFC 0.75, 0.74, 0.83, respectively).…”

Section: Discussionmentioning

confidence: 99%

Biological functions at high pressure: transcriptome response of Shewanella oneidensis MR-1 to hydrostatic pressure relevant to Titan and other icy ocean worlds

Malas,

Russo,

Bollengier

et al. 2024

Front. Microbiol.

View full text Add to dashboard Cite

High hydrostatic pressure (HHP) is a key driver of life's evolution and diversification on Earth. Icy moons such as Titan, Europa, and Enceladus harbor potentially habitable high-pressure environments within their subsurface oceans. Titan, in particular, is modeled to have subsurface ocean pressures ≥ 150 MPa, which are above the highest pressures known to support life on Earth in natural ecosystems. Piezophiles are organisms that grow optimally at pressures higher than atmospheric (0.1 MPa) pressure and have specialized adaptations to the physical constraints of high-pressure environments – up to ~110 MPa at Challenger Deep, the highest pressure deep-sea habitat explored. While non-piezophilic microorganisms have been shown to survive short exposures at Titan relevant pressures, the mechanisms of their survival under such conditions remain largely unelucidated. To better understand these mechanisms, we have conducted a study of gene expression for Shewanella oneidensis MR-1 using a high-pressure experimental culturing system. MR-1 was subjected to short-term (15 min) and long-term (2 h) HHP of 158 MPa, a value consistent with pressures expected near the top of Titan's subsurface ocean. We show that MR-1 is metabolically active in situ at HHP and is capable of viable growth following 2 h exposure to 158 MPa, with minimal pressure training beforehand. We further find that MR-1 regulates 264 genes in response to short-term HHP, the majority of which are upregulated. Adaptations include upregulation of the genes argA, argB, argC, and argF involved in arginine biosynthesis and regulation of genes involved in membrane reconfiguration. MR-1 also utilizes stress response adaptations common to other environmental extremes such as genes encoding for the cold-shock protein CspG and antioxidant defense related genes. This study suggests Titan's ocean pressures may not limit life, as microorganisms could employ adaptations akin to those demonstrated by terrestrial organisms.

show abstract

Section: Discussionmentioning

confidence: 99%

Biological functions at high pressure: transcriptome response of Shewanella oneidensis MR-1 to hydrostatic pressure relevant to Titan and other icy ocean worlds

Malas,

Russo,

Bollengier

et al. 2024

Front. Microbiol.

View full text Add to dashboard Cite

show abstract

“…This drives adaptive morphological and physiological remodeling in the inhabitant microbiome. High temperature and low pressure exert a similar effect on the biophysical properties of the membrane, which is a disruption of acyl chain packing order, which results in an increase in fluidity ( 58 , 59 ). In response, bacteria primarily increase the proportion of saturated fatty acids in the bilayer.…”

Section: Discussionmentioning

confidence: 99%

“…In addition, temperature and pressure changes affect headgroup chemistry. In general, high temperature and pressure usually induce an overall increase in relative abundance of polar lipids in the membrane ( 59 , 61 ). Also, zwitterionic lipids, which possess balanced positive and negative charges, pack more densely than their anionic counterparts, hence are elevated in some bacteria under high temperature and low pressure ( 59 ).…”

Section: Discussionmentioning

confidence: 99%

Changes in environmental and engineered conditions alter the plasma membrane lipidome of fractured shale bacteria

Ugwuodo,

Colosimo,

Adhikari

et al. 2024

Microbiol Spectr

View full text Add to dashboard Cite

Microorganisms that persist in fractured shale reservoirs cause several problems including secreting foul gases and forming biofilms. Current biocontrol measures often fail due to limited knowledge of their in situ activities. The plasma membrane protects the cell, mediates many of its critical functions, and responds to intracellular cues and ecological perturbations through physicochemical modifications. As such, it provides valuable insight into the physiological adaptation of microorganisms in disturbed environmental systems. Here, we (i) demonstrate how changes in salinity and hydraulic retention time (HRT) influence the plasma membrane intact polar lipid (IPL) chemistry of model bacterium, Halanaerobium congolense WG10, and mixed microbial consortia enriched from shale-produced fluids and (ii) elucidate adjustments in membrane IPL chemistry during biofilm growth relative to planktonic cells. We incubated H. congolense WG10 in chemostats under three salinities (7%, 13%, and 20% NaCl), operated under three HRTs (19.2, 24, and 48 h), and in drip flow biofilm reactors under the same salinity gradients. Also, mixed microbial consortia in produced fluids were enriched in triplicate chemostat vessels under three HRTs (19.2, 24, and 72 h) and biofilm reactors. Lipids were analyzed by ultra high performance liquid chromatography-tandem mass spectrometry (UPLC-MS/MS). Our results show that phosphatidylglycerols, cardiolipins, and phosphatidylethanolamines were predominantly enriched in planktonic H. congolense WG10 cells grown at hypersalinity (20%) compared to optimum (13%). In addition, several zwitterionic phosphatidylcholines and phosphatidylethanolamines were higher in abundance during biofilm growth. These observations suggest that microbial adaptation and biofilm formation in fractured shale are enabled by strategic plasma membrane IPL chemistry adjustments. IMPORTANCE Microorganisms inadvertently introduced into the shale reservoir during fracturing face multiple stressors including brine-level salinities and starvation. However, some anaerobic halotolerant bacteria adapt and persist for long periods of time. They produce hydrogen sulfide, which sours the reservoir and corrodes engineering infrastructure. In addition, they form biofilms on rock matrices, which decrease shale permeability and clog fracture networks. These reduce well productivity and increase extraction costs. Under stress, microbes remodel their plasma membrane to optimize its roles in protection and mediating cellular processes such as signaling, transport, and energy metabolism. Hence, by observing changes in the membrane lipidome of model shale bacteria, Halanaerobium congolense WG10, and mixed consortia enriched from produced fluids under varying subsurface conditions and growth modes, we provide insight that advances our knowledge of the fractured shale biosystem. We also offer data-driven recommendations for improving biocontrol efficacy and the efficiency of energy recovery from unconventional formations.

show abstract

“…For example, this could be driven by bacterial processes such as anammox leading to rapid nitrogen loss within a shallow layer of the sediment surface (Thamdrup et al., 2021). Other recent studies have also highlighted potential physiological adaptations of the benthic microbial community to the high‐pressure and low‐temperature present in the hadal realm though cell membrane lipid composition (Flores et al., 2022; Tamby et al., 2023), whereas long‐term selective forces, where co‐existing taxa are more dissimilar and the phylogenetic turnover is greater than expected over the redox zone, lead to large community shifts over time (Schauberger et al., 2023). Together, changes in the chemical composition of benthic microbes as well as their metabolisms could alter the overall elemental and stable isotope composition of sedimentary OM.…”

Section: Discussionmentioning

confidence: 99%

Particulate Organic Matter in the Atacama Trench: Tracing Sources and Possible Transport Mechanisms to the Hadal Seafloor

Flores,

Fernández‐Urruzola,

Cantarero

et al. 2023

JGR Biogeosciences

View full text Add to dashboard Cite

Oceanic trenches are an important sink for organic matter (OM). However, little is known about how much of the OM reaching the hadal region derives from the sunlit surface ocean and other sources. We provide new insight into the OM sources in the Atacama Trench by examining the elemental and stable isotope composition of carbon and nitrogen in bulk OM throughout the entire water column and down to bathyal and hadal sediments. Moreover, we estimated the particulate organic carbon (POC) concentration and downward carbon flux. Our results, based on two‐way variance analysis, showed statistical differences in δ15NPON between the epipelagic zone and the deep zones. However, no statistical differences in δ13CPOC and C:N ratio between hadalpelagic and shallower pelagic zones were found, except for δ13CPOC in the oxygen deficient zone. On the contrary, whereas the isotopic signatures of hadal sediments were distinct from those over the entire water column, they were similar to the values in bathyal sediments. Thus, our results suggest that bathyal sediments could contribute more OM to hadal sediments than the different zones of the water column. Indeed, whereas POC flux estimates derived from remote sensing data indicate that ∼16‐27% of POC could evade surface remineralization within the top 200 m and potentially be exported to depths beyond the mesopelagic region, model estimates suggest that ∼3.3% of it could reach hadal depths. Our results provide a quantitative baseline of pelagic‐benthic coupling which can aid in assessment of carbon cycling changes in future climate scenarios.

show abstract

Microbial membrane lipid adaptations to high hydrostatic pressure in the marine environment

Cited by 17 publications

References 66 publications

Biological functions at high pressure: transcriptome response of Shewanella oneidensis MR-1 to hydrostatic pressure relevant to Titan and other icy ocean worlds

Biological functions at high pressure: transcriptome response of Shewanella oneidensis MR-1 to hydrostatic pressure relevant to Titan and other icy ocean worlds

Changes in environmental and engineered conditions alter the plasma membrane lipidome of fractured shale bacteria

Particulate Organic Matter in the Atacama Trench: Tracing Sources and Possible Transport Mechanisms to the Hadal Seafloor

Contact Info

Product

Resources

About