Microbial sedimentary imprint on the deep Dead Sea sediment

A study of an International Continental Drilling Program core recovered from the middle of the modern Dead Sea has identified microbial traces within this subsurface hypersaline environment. A comparison with an active microbial mat exhibiting similar evaporative processes characterized iron‐sulphur mineralization and exopolymeric substances resulting from microbial activity. Exopolymeric substances were identified in the drilled sediment but unlike other hypersaline environments, it appears that they have a limited effect on the precipitation of calcium carbonate in the sedimentary column. Sulphate reduction, however, plays a role in all types of evaporative facies, leading to the formation of diagenetic iron sulphides in glacial and interglacial intervals. Their synthesis seems to occur under progressive sulphidation that generally stops at greigite because of incomplete sulphate reduction. The latter may be caused by a lack of suitable organic matter in this hypersaline, hence energy‐demanding, environment. Pyrite may be found in periods of high lake productivity, when more labile organic matter is available. The carbon and sulphur cycles are thus influenced by microbial activity in the Dead Sea environment and this influence results in diagenetic transformations in the deep sediment.

[1]  M. Canti Formation Processes , 2018, The Encyclopedia of Archaeological Sciences.

[2]  D. Ionescu,et al.  Impact of paleoclimate on the distribution of microbial communities in the subsurface sediment of the Dead Sea , 2015, Geobiology.

[3]  Steven L. Goldstein,et al.  Dead Sea drawdown and monsoonal impacts in the Levant during the last interglacial , 2015 .

[4]  D. Arizteguí,et al.  Present and future of subsurface biosphere studies in lacustrine sediments through scientific drilling , 2015, International Journal of Earth Sciences.

[5]  D. Ionescu,et al.  Sulfate reduction and sulfide oxidation in extremely steep salinity gradients formed by freshwater springs emerging into the Dead Sea. , 2014, FEMS microbiology ecology.

[6]  M. Stein,et al.  Lithology of the long sediment record recovered by the ICDP Dead Sea Deep Drilling Project (DSDDP) , 2014 .

[7]  D. Ionescu,et al.  Archaeal populations in two distinct sedimentary facies of the subsurface of the Dead Sea. , 2014, Marine genomics.

[8]  M. Stein,et al.  Long-term freshening of the Dead Sea brine revealed by porewater Cl− and δO18 in ICDP Dead Sea deep-drill , 2014 .

[9]  S. Joye,et al.  Anaerobic oxidation of methane by sulfate in hypersaline groundwater of the Dead Sea aquifer , 2014, Geobiology.

[10]  A. Starinsky,et al.  Groundwater ages and reaction rates during seawater circulation in the Dead Sea aquifer , 2013 .

[11]  A. Turchyn,et al.  Fire and Brimstone: The Microbially Mediated Formation of Elemental Sulfur Nodules from an Isotope and Major Element Study in the Paleo-Dead Sea , 2013, PloS one.

[12]  J. Kallmeyer,et al.  Sulfate reduction controlled by organic matter availability in deep sediment cores from the saline, alkaline Lake Van (Eastern Anatolia, Turkey) , 2013, Front. Microbiol..

[13]  A. Lücke,et al.  Origin and significance of diagenetic concretions in sediments of Laguna Potrok Aike, southern Argentina , 2013, Journal of Paleolimnology.

[14]  P. Meister Two opposing effects of sulfate reduction on carbonate precipitation in normal marine, hypersaline, and alkaline environments , 2013 .

[15]  P. Visscher,et al.  Inside the alkalinity engine: the role of electron donors in the organomineralization potential of sulfate‐reducing bacteria , 2012, Geobiology.

[16]  Jörg Peplies,et al.  Microbial and Chemical Characterization of Underwater Fresh Water Springs in the Dead Sea , 2012, PloS one.

[17]  A. Oren,et al.  Dynamics and Persistence of Dead Sea Microbial Populations as Shown by High-Throughput Sequencing of rRNA , 2012, Applied and Environmental Microbiology.

[18]  A. Oren Thermodynamic limits to microbial life at high salt concentrations. , 2011, Environmental microbiology.

[19]  Itai Sharon,et al.  Comparative community genomics in the Dead Sea: an increasingly extreme environment , 2010, The ISME Journal.

[20]  E. Perri,et al.  Microbial biomineralization processes forming modern Ca:Mg carbonate stromatolites , 2010 .

[21]  R. Reid,et al.  Processes of carbonate precipitation in modern microbial mats , 2009 .

[22]  Avinash Mishra,et al.  Isolation and characterization of extracellular polymeric substances from micro-algae Dunaliellasalina under salt stress. , 2009, Bioresource technology.

[23]  J. Hartmann,et al.  Water input requirements of the rapidly shrinking Dead Sea , 2009, Naturwissenschaften.

[24]  S. Bernasconi,et al.  Microbes produce nanobacteria-like structures, avoiding cell entombment , 2008 .

[25]  M. Stein,et al.  Gypsum as a monitor of the paleo-limnological hydrological conditions in Lake Lisan and the Dead Sea , 2008 .

[26]  Olivier Braissant,et al.  Exopolymeric substances of sulfate‐reducing bacteria: Interactions with calcium at alkaline pH and implication for formation of carbonate minerals , 2007 .

[27]  L. Benning,et al.  Greigite: a true intermediate on the polysulfide pathway to pyrite , 2007, Geochemical transactions.

[28]  P. Zuddas,et al.  Nucleation of calcium carbonate on bacterial nanoglobules , 2006 .

[29]  T. Tyliszczak,et al.  Nanoscale detection of organic signatures in carbonate microbialites. , 2006, Proceedings of the National Academy of Sciences of the United States of America.

[30]  A. Roberts,et al.  Magnetite dissolution, diachronous greigite formation, and secondary magnetizations from pyrite oxidation: Unravelling complex magnetizations in Neogene marine sediments from New Zealand , 2006 .

[31]  P. Visscher,et al.  Microbial lithification in marine stromatolites and hypersaline mats. , 2005, Trends in microbiology.

[32]  M. Stein,et al.  Sea-rain-lake relation in the Last Glacial East Mediterranean revealed by δ18O-δ13C in Lake Lisan aragonites , 2005 .

[33]  M. Stein,et al.  The sources and evolution of sulfur in the hypersaline Lake Lisan (paleo-Dead Sea) , 2005 .

[34]  D. Newman,et al.  Microbial Kinetic Controls on Calcite Morphology in Supersaturated Solutions , 2005 .

[35]  Pieter T. Visscher,et al.  Microbe–mineral interactions: early carbonate precipitation in a hypersaline lake (Eleuthera Island, Bahamas) , 2004 .

[36]  R. Popa,et al.  Pyrite Framboids as Biomarkers for Iron-Sulfur Systems , 2004 .

[37]  A. Decho,et al.  ISOLATION AND BIOCHEMICAL CHARACTERIZATION OF EXTRACELLULAR POLYMERIC SECRETIONS (EPS) FROM MODERN SOFT MARINE STROMATOLITES (BAHAMAS) AND ITS INHIBITORY EFFECT ON CACO3 PRECIPITATION , 2002, Preparative biochemistry & biotechnology.

[38]  V. Müller,et al.  Osmoadaptation in bacteria and archaea: common principles and differences. , 2001, Environmental microbiology.

[39]  A. Oren The bioenergetic basis for the decrease in metabolic diversity at increasing salt concentrations: implications for the functioning of salt lake ecosystems , 2001, Hydrobiologia.

[40]  R. Wilkin,et al.  Variations in pyrite texture, sulfur isotope composition, and iron systematics in the Black Sea: evidence for Late Pleistocene to Holocene excursions of the o , 2001 .

[41]  B. Spiro,et al.  The sulfur system in anoxic subsurface brines and its implication in brine evolutionary pathways: the Ca-chloride brines in the Dead Sea area , 2001 .

[42]  B. Lazar,et al.  Dynamics of the carbon dioxide system in the Dead Sea , 2001 .

[43]  R. Reid,et al.  Microscale observations of sulfate reduction: Correlation of microbial activity with lithified micritic laminae in modern marine stromatolites , 2000 .

[44]  H. Paerl,et al.  The role of microbes in accretion, lamination and early lithification of modern marine stromatolites , 2000, Nature.

[45]  John,et al.  Formation of lithified micritic laminae in modern marine stromatolites (Bahamas); the role of sulfur cycling , 1998 .

[46]  R. Frankel,et al.  Reaction sequence of iron sulfide minerals in bacteria and their use as biomarkers. , 1998, Science.

[47]  Steven L. Goldstein,et al.  Strontium isotopic, chemical, and sedimentological evidence for the evolution of Lake Lisan and the Dead Sea , 1997 .

[48]  J. Morse,et al.  Pyrite formation under conditions approximating those in anoxic sediments: II. Influence of precursor iron minerals and organic matter , 1997 .

[49]  J. Middelburg,et al.  Pyrite contents, microtextures, and sulfur isotopes in relation to formation of the youngest eastern Mediterranean sapropel , 1997 .

[50]  H. Barnes,et al.  Pyrite formation by reactions of iron monosulfides with dissolved inorganic and organic sulfur species , 1996 .

[51]  F. Sansone,et al.  Texture of Microbial Sediments Revealed by Cryo-Scanning Electron Microscopy , 1996 .

[52]  J. Morse,et al.  Pyrite formation under conditions approximating those in anoxic sediments I. Pathway and morphology , 1996 .

[53]  A. Oren,et al.  A bloom of Dunaliella parva in the Dead Sea in 1992: biological and biogeochemical aspects , 1995, Hydrobiologia.

[54]  D. Canfield,et al.  The reactivity of sedimentary iron minerals toward sulfide , 1992 .

[55]  A. Almogi‐Labin,et al.  Living Ammonia from a hypersaline inland pool, Dead Sea area, Israel , 1992 .

[56]  G. Luther Pyrite synthesis via polysulfide compounds , 1991 .

[57]  M. Schoonen,et al.  Reactions forming pyrite and marcasite from solution: I. Nucleation of FeS2 below 100°C , 1991 .

[58]  K. Stetter,et al.  Pyrite formation linked with hydrogen evolution under anaerobic conditions , 1990, Nature.

[59]  M. Stiller,et al.  Iron in the Dead Sea , 1984 .

[60]  R. Berner Sedimentary pyrite formation: An update , 1984 .

[61]  A. Oren Population dynamics of halobacteria in the Dead Sea water column1 , 1983 .

[62]  A. Oren,et al.  Population dynamics of Dunaliella parva in the Dead Sea1 , 1982 .

[63]  J. Gat,et al.  The Dead Sea: Deepening of the Mixolimnion Signifies the Overture to Overturn of the Water Column , 1979, Science.

[64]  A. Nissenbaum The microbiology and biogeochemistry of the Dead Sea , 1975, Microbial Ecology.

[65]  D. Rickard Kinetics and mechanism of pyrite formation at low temperatures , 1975 .

[66]  I. Kaplan,et al.  Pyrite Framboid Formation; Laboratory Synthesis and Marine Sediments , 1973 .

[67]  P. Visscher,et al.  Two opposing effects of sulfate reduction on carbonate precipitation in normal marine, hypersaline, and alkaline environments: COMMENT , 2014 .

[68]  N. Gunde-Cimerman,et al.  Fungal life in the dead sea. , 2012, Progress in molecular and subcellular biology.

[69]  B. Lazar,et al.  Characterization and Dating of Saline Groundwater in the Dead Sea Area , 2010, Radiocarbon.

[70]  N. Nowaczyk,et al.  Magnetic properties of Lake Lisan and Holocene Dead Sea sediments and the fidelity of chemical and detrital remanent magnetization , 2006 .

[71]  George W. Luther,et al.  Kinetics of pyrite formation by the H2S oxidation of iron (II) monosulfide in aqueous solutions between 25 and 125°C: The rate equation , 1997 .

[72]  H. Barnes,et al.  Formation processes of framboidal pyrite , 1997 .

[73]  D. D. Des Marais The biogeochemistry of hypersaline microbial mats. , 1995, Advances in microbial ecology.

[74]  R. Berner Sedimentary pyrite formation , 1970 .