The ∼3.48 billion-year-old Dresser Formation, Pilbara Craton, Western Australia, is a key geological unit for the study of Earth's earliest life and the habitats it occupied. Here, we describe a new suite of spheroidal to lenticular microstructures that morphologically resemble some previously reported Archean microfossils. Correlative microscopy shows that these objects have a size distribution, wall ultrastructure, and chemistry that are incompatible with a microfossil origin and instead are interpreted as pyritized and silicified fragments of vesicular volcanic glass. Organic kerogenous material is associated with much of the altered volcanic glass; variable quantities of organic carbon line or fill the insides of some individual vesicles, while relatively large, tufted organic-rich laminae envelop multiple vesicles.
The microstructures reported herein constitute a new type of abiogenic artifact (pseudo-fossil) that must be considered when evaluating potential signs of early life on Earth or elsewhere. In the sample studied here, where hundreds of these microstructures are present, the combined evidence permits a relatively straightforward interpretation as vesicular volcanic glass. However, reworked, isolated, and silicified microstructures of this type may prove particularly problematic in early or extraterrestrial life studies since they adsorb carbon onto their surfaces and are readily pyritized, mimicking a common preservation mechanism for bona fide microfossils. In those cases, nanoscale analysis of wall ultrastructure would be required to firmly exclude a biological origin. Key Words: Microfossils—Pseudo-fossils—Volcanic vesicles—Archean life—Pilbara Craton—Dresser Formation. Astrobiology 18, 539–555.
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References
1.
AckermandD., HekinianR., and StoffersP. (1998) Magmatic sulphides and oxides in volcanic rocks from the Pitcairn hotspot (South Pacific). Mineral Petrol, 64:149–162.
2.
BarleyM.E., DunlopJ.S.R., GloverJ.E., and GrovesD.I. (1979) Sedimentary evidence for an Archean shallow-water volcanic-sedimentary facies, eastern Pilbara block, Western Australia. Earth Planet Sci Lett, 43:74–84.
3.
BinnsR.A., BarrigaF.J.A.S., MillerD.J., et al.; the Shipboard Scientific Party. (2002) Site 1189. In Proceedings of the Ocean Drilling Program, Initial Reports, Vol. 193, Ocean Drilling Program, College Station, TX, doi10.2973/odp.proc.ir.193.104.2002.
4.
BranneyM.J. and SparksR.S.J. (1990) Fiamme formed by diagenesis and burial-compaction in soils and subaqueous sediments. J Geol Soc London, 147:919–922.
5.
BrasierM.D., MatthewmanR., McMahonS., and WaceyD. (2011) Pumice as a remarkable substrate for the origin of life. Astrobiology, 11:725–735.
6.
BrasierM.D., MatthewmanR., McMahonS., and WaceyD. (2013) Pumice from the ∼3460 Ma Apex Basalt, Western Australia: a natural laboratory for the early biosphere. Precambrian Res, 224:1–10.
7.
BryanS.E., CookA., EvansJ.P., CollsP.W., WellsM.G., LawrenceM.G., JellJ.S., GreigA., and LeslieR. (2004) Pumice rafting and faunal dispersion during 2001–2002 in the Southwest Pacific: record of a dacitic submarine explosive eruption from Tonga. Earth Planet Sci Lett, 227:135–154.
8.
BrydsonR. (2001) Electron Energy Loss Spectroscopy, Springer-Verlag, New York.
9.
BuhringC., SarntheinM., and Leg 184 Shipboard ScientificParty. (2000) Toba ash layers in the South China Sea: evidence of contrasting wind directions during eruption ca. 74 ka. Geology, 28:275–278.
10.
BuickR. and DunlopJ. (1990) Evaporitic sediments of Early Archean age from the Warrawoona Group, North Pole, Western Australia. Sedimentology, 37:247–277.
11.
DenizV. (2012) The effects of mill speed on kinetic breakage parameters of four different particulate pumices. Particulate Science and Technology: An International Journal, 31:101–108.
12.
DjokicT., Van KranendonkM.J., CampbellK.A., WalterM.R., and WardC.R. (2017) Earliest signs of life on land preserved in ca. 3.5 Ga hot spring deposits. Nat Commun, 8, doi:10.1038/ncomms15263.
13.
EngelA.E.J., NagyB., NagyL.A., EngelC.G., KrempG.O.W., and DrewC.M. (1968) Algal-like forms in Onverwacht Series, South Africa: oldest recognized lifelike forms on Earth. Science, 161:1005–1008.
14.
FurnesH., BanerjeeN.R., StaudigelH., MuehlenbachsK., McLoughlinN., de WitM., and Van KranendonkM. (2007) Comparing petrographic signatures of bioalteration in recent to Mesoarchean pillow lavas: tracing subsurface life in oceanic igneous rocks. Precambrian Res, 158:156–176.
15.
GnaserH. (2003) Ionization probability of sputtered cluster anions: Cn− and Sin−. Appl Surf Sci, 203–204:78–81.
16.
GreyK. and SugitaniK. (2009) Palynology of Archean microfossils (c. 3.0 Ga) from the Mount Grant area, Pilbara Craton, Western Australia: further evidence of biogenicity. Precambrian Res, 173:60–69.
17.
HeikenG. and WohletzK. (1985) Volcanic Ash, University of California Press, Berkeley.
18.
HerdR.A. and PinkertonH. (1997) Bubble coalescence in basaltic lava: its impact on the evolution of bubble populations. Journal of Volcanology and Geothermal Research, 75:137–157.
19.
HickmanA. (2012) Review of the Pilbara Craton and Fortescue Basin, Western Australia: crustal evolution providing environments for early life. Island Arc, 21:1–31.
20.
JavauxE.J., MarshallC.P., and BekkerA. (2010) Organic-walled microfossils in 3.2-billion-year-old shallow-marine siliciclastic deposits. Nature, 463:934–938.
21.
JutzelerM., MangaM., WhiteJ.D.L., TallingP.J., ProussevitchA.A., WattS.F.L., CassidyM., TaylorR.N., Le FriantA., and IshizukaO. (2017) Submarine deposits from pumiceous pyroclastic density currents travelling over water: an outstanding example from offshore Montserrat (IODP 340). GSA Bulletin, 129:392–414.
22.
KilburnM.R. and WaceyD. (2011) Elemental and isotopic analysis by NanoSIMS: insights for the study of stromatolites and early life on Earth. In Stromatolites: Interaction of Microbes with Sediments, Cellular Origin, Life in Extreme Habitats and Astrobiology Volume 18, edited by SeckbachJ. and TewariV., Springer, Berlin, pp 463–493.
23.
KnollA.H. (2015) Paleobiological perspectives on early microbial evolution. Cold Spring Harb Perspect Biol, 7, doi:10.1101/cshperspect.a018093.
24.
LepotK., BenzeraraK., and PhilippotP. (2011) Biogenic versus metamorphic origins of diverse microtubes in 2.7 Gyr old volcanic ashes: multi-scale investigations. Earth Planet Sci Lett, 312:37–47.
25.
LepotK., WillifordK.H., UshikuboT., SugitaniK., MimuraK., SpicuzzaM.J., and ValleyJ.W. (2013) Texture-specific isotopic compositions in 3.4 Gyr old organic matter support selective preservation in cell-like structures. Geochim Cosmochim Acta, 112:66–86.
26.
LepotK., AddadA., KnollA.H., WangJ., TroadecD., BecheA., and JavauxE.J. (2017) Iron minerals within specific microfossil morphospecies of the 1.88 Ga Gunflint Formation. Nat Commun, 8, doi:10.1038/ncomms14890.
27.
LiC.-F., LinJ., KulhanekD.K., WilliamsT., BaoR., BriaisA., BrownE.A., ChenY., CliftP.D., ColwellF.S., DaddK.A., DingW.-W., Hernandez-AlmeidaI., HuangX.-L., HyunS., JiangT., KoppersA.A.P., LiQ., LiuC., LiuQ., LiuZ., NagaiR.H., Peleo-AlampayA., SuX., SunZ., TejadaM.L.G., TrinhH.S., YehY.-C., ZhangC., ZhangF., ZhangG.-L., and ZhaoX. (2015) Site U1434. In Proceedings of the International Ocean Discovery Program, Vol. 349, edited by LiC.-F., LinJ., KulhanekD.K., and the Expedition 349 Scientists, International Ocean Discovery Program, College Station, TX, doi:10.14379/iodp.proc.349.106.2015.
28.
LoweD.R. (1999) Petrology and sedimentology of cherts and related silicified sedimentary rocks in the Swaziland Supergroup. In Geologic Evolution of the Barberton Greenstone Belt, South Africa, Geological Society of America Special Paper 329, edited by LoweD.R. and ByerlyG.R., Geological Society of America, Boulder, CO, pp 83–114.
29.
LoweD.R. and KnauthL.P. (1977) Sedimentology of the Onverwacht Group (3.4 by), Transvaal, South Africa, and its bearing on the characteristics and evolution of the early Earth. J Geol, 85:699–723.
30.
ManganM.T. and CashmanK.V. (1996) The structure of basaltic scoria and reticulate and inferences for vesiculation, foam formation, and fragmentation in lava fountains. Journal of Volcanology and Geothermal Research, 73:1–18.
31.
MooreJ.G. and CalkL. (1971) Sulfide spherules in vesicles of dredged pillow basalt. Am Mineral, 56:476–488.
32.
NijmanW., De BruijneK.C.H., and ValkeringM.E. (1999) Growth fault control of Early Archean cherts, barite mounds and chert-barite veins, North Pole Dome, Eastern Pilbara, Western Australia. Precambrian Res, 95:247–274.
33.
NoffkeN., ChristianD., WaceyD., and HazenR.M. (2013) Microbially induced sedimentary structures recording an ancient ecosystem in the 3.48 billion-year-old Dresser Formation, Pilbara, Western Australia. Astrobiology, 13:1103–1124.
34.
RustA.C. and CashmanK.V. (2011) Permeability controls on expansion and size distributions of pyroclasts. J Geophys Res, 116, doi:10.1029/2011JB008494.
35.
RutherfordM.J. and PapaleP. (2009) Origin of basalt fire-fountain eruptions on Earth versus the Moon. Geology, 37:219–222.
36.
SamuelssonJ., DawesP.R., and VidalG. (1999) Organic-walled microfossils from the Proterozoic Thule Supergroup, Northwest Greenland. Precambrian Res, 96:1–23.
37.
SchopfJ.W. (1976) Are the oldest ‘fossils’, fossils?. Orig Life, 7:19–36.
38.
SchopfJ.W. and KleinC. (1992) The Proterozoic Biosphere, a Multidisciplinary Study, Cambridge University Press, New York.
39.
Schultze-LamS., FerrisF.G., KonhauserK.O., and WieseR.G. (1995) In situ silicification of an Icelandic hot spring microbial mat: implications for microfossil formation. Can J Earth Sci, 32:2021–2026.
40.
ShenY., FarquharJ., MastersonA., KaufmanA.J., and BuickR. (2009) Evaluating the role of microbial sulfate reduction in the early Archean using quadruple isotope systematics. Earth Planet Sci Lett, 279:383–391.
41.
SugitaniK., GreyK., AllwoodA., NagaokaT., MimuraK., MinamiM., MarshallC.P., Van KranendonkM.J., and WalterM.R. (2007) Diverse microstructures from Archaean chert from the Mount Goldsworthy–Mount Grant area, Pilbara Craton, Western Australia: microfossils, dubiofossils, or pseudofossils?. Precambrian Res, 158:228–262.
42.
SugitaniK., GreyK., NagaokaT., and MimuraK. (2009) Three-dimensional morphological and textural complexity of Archean putative microfossils from the northeastern Pilbara Craton: indication of biogenicity of large (>15 mm) spheroidal and spindle-like structures. Astrobiology, 9:603–615.
43.
SugitaniK., LepotK., NagaokaT., MimuraK., Van KranendonkM.J., OehlerD.Z., and WalterM.R. (2010) Biogenicity of morphologically diverse carbonaceous microstructures from the ca. 3400 Ma Strelley Pool Formation, in the Pilbara Craton, Western Australia. Astrobiology, 10:899–920.
44.
SugitaniK., MimuraK., NagaokaT., LepotK., and TakeuchiM. (2013) Microfossil assemblage from the 3400 Ma Strelley Pool Formation in the Pilbara Craton, Western Australia: results from a new locality. Precambrian Res, 226:59–74.
45.
SugitaniK., MimuraK., TakeuchiM., LepotK., ItoS., and JavauxE.J. (2015a) Early evolution of large micro-organisms with cytological complexity revealed by microanalysis of 3.4 Ga organic-walled microfossils. Geobiology, 13:507–521.
46.
SugitaniK., MimuraK., TakeuchiM., YamaguchiT., SuzukiK., SendaR., AsaharaY., WallisS., and Van KranendonkM.J. (2015b) A Paleoarchean coastal hydrothermal field inhabited by diverse microbial communities: the Strelley Pool Formation, Pilbara Craton, Western Australia. Geobiology, 13:522–545.
47.
ThorsethI.H., FurnesH., and HeldalM. (1992) The importance of microbiological activity in the alteration of natural basaltic glass. Geochim Cosmochim Acta, 56:845–850.
48.
UenoY., IsosakiY., and McNamaraK.J. (2006) Coccoid-like microstructures in a 3.0 Ga chert from Western Australia. Int Geol Rev, 48:78–88.
49.
UenoY., OnoS., RumbleD., and MaruyamaS. (2008) Quadruple sulfur isotope analysis of ca. 3.5 Ga Dresser Formation: new evidence for microbial sulfate reduction in the early Archean. Geochim Cosmochim Acta, 72:5675–5691.
50.
Van KranendonkM.J. (2006) Volcanic degassing, hydrothermal circulation and the flourishing of early life on Earth: a review of the evidence from c. 3490–3240 Ma rocks of the Pilbara Supergroup, Pilbara Craton, Western Australia. Earth-Science Reviews, 74:197–240.
51.
Van KranendonkM.J., SmithiesH., HickmanA.H., and ChampionD.C. (2007) Review: secular tectonic evolution of Archean continental crust: interplay between horizontal and vertical processes in the formation of the Pilbara Craton, Australia. Terra Nova, 19:1–38.
52.
Van KranendonkM.J., PhilippotP., LepotK., BodorkosS., and PirajnoF. (2008) Geological setting of Earth's oldest fossils in the ca. 3.5 Ga Dresser Formation, Pilbara Craton, Western Australia. Precambrian Res, 167:93–124.
53.
WaceyD. (2009) Early Life on Earth: A Practical Guide, Springer, Dordrecht, The Netherlands.
54.
WaceyD., KilburnM.R., McLoughlinN., ParnellJ., StoakesC.A., and BrasierM.D. (2008) Use of NanoSIMS in the search for early life on Earth: ambient inclusion trails in a c. 3400 Ma sandstone. J Geol Soc London, 165:43–53.
55.
WaceyD., KilburnM.R., SaundersM., CliffJ., and BrasierM.D. (2011) Microfossils of sulfur metabolizing cells in ∼3.4 billion year old rocks of Western Australia. Nat Geosci, 4:698–702.
56.
WaceyD., MenonS., GreenL., GerstmannD., KongC., McLoughlinN., SaundersM., and BrasierM.D. (2012) Taphonomy of very ancient microfossils from the ∼3400 Ma Strelley Pool Formation and ∼1900 Ma Gunflint Formation: new insights using a focused ion beam. Precambrian Res, 220–221:234–250.
57.
WaceyD., McloughlinN., KilburnM.R., SaundersM., CliffJ., KongC., BarleyM.E., and BrasierM.D. (2013) Nano-scale analysis reveals differential heterotrophic consumption in the ∼1.9 Ga Gunflint Chert. Proc Natl Acad Sci USA, 110:8020–8024.
58.
WaceyD., SaundersM., RobertsM., MenonS., GreenL., KongC., CulwickT., StrotherP., and BrasierM.D. (2014) Enhanced cellular preservation by clay minerals in 1 billion-year-old lakes. Sci Rep, 4, doi:10.1038/srep05841.
59.
WaceyD., NoffkeN., CliffJ., BarleyM.E., and FarquharJ. (2015) Micro-scale quadruple sulfur isotope analysis of pyrite from the ∼3480 Ma Dresser Formation: new insights into sulfur cycling on the early Earth. Precambrian Res, 258:24–35.
60.
WaceyD., SaundersM., KongC., and KilburnM. (2017) Remarkably preserved tephra with microfossil-like morphology from the ∼3.43 Ga Strelley Pool Formation, Pilbara, Western Australia [abstract 3686]. In Goldschmidt Conference Abstracts, 14–18 August 2017, Paris, France.
61.
WalshM.M. (1992) Microfossils and possible microfossils from the Early Archean Onverwacht Group, Barberton Mountain Land, South Africa. Precambrian Res, 54:271–293.
62.
WalshM.M. (2004) Evaluation of early Archean volcaniclastic and volcanic flow rocks as possible sites for carbonaceous fossil microbes. Astrobiology, 4:429–437.
63.
WestallF., de VriesS.T., NijmanW., RouchonV., OrbergerB., PearsonV., WatsonJ., VerchovskyA., WrightI., RouzardJ.-N., MarchesiniD., and SeverineA. (2006) The 3.466 Ga “Kitty's Gap Chert”, an Early Archaean microbial ecosystem. In Processes on the Early Earth, Geological Society of America Special Publication Volume 405, edited by ReimoldW.U. and GibsonR., Geological Society of America, Boulder, CO, pp 105–131.
64.
WestallF., FoucherF., CavalazziB., de VriesS.T., NijmanW., PearsonV., WatsonJ., VerchovskyA., WrightI., RouzaudJ.-N., MarchesiniD., and SeverineA. (2011) Volcaniclastic habitats for early life on Earth and Mars: a case study from ∼3.5 Ga-old rocks from the Pilbara, Australia. Planet Space Sci, 59:1093–1106.
65.
WhitmanW.B., GoodfellowM., KampferP., BusseH.-J., TrujilloM.E., LudwigW., and SuzukiK.-I. (2012) Bergey's Manual of Systematic Bacteriology, 2nd ed., Vol. 5, parts A–B, Springer-Verlag, New York.
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