Every spacecraft sent to Mars is allowed to land viable microbial bioburden, including hardy endospore-forming bacteria resistant to environmental extremes. Earth's stratosphere is severely cold, dry, irradiated, and oligotrophic; it can be used as a stand-in location for predicting how stowaway microbes might respond to the martian surface. We launched E-MIST, a high-altitude NASA balloon payload on 10 October 2015 carrying known quantities of viable Bacillus pumilus SAFR-032 (4.07 × 107 spores per sample), a radiation-tolerant strain collected from a spacecraft assembly facility. The payload spent 8 h at ∼31 km above sea level, exposing bacterial spores to the stratosphere. We found that within 120 and 240 min, spore viability was significantly reduced by 2 and 4 orders of magnitude, respectively. By 480 min, <0.001% of spores carried to the stratosphere remained viable. Our balloon flight results predict that most terrestrial bacteria would be inactivated within the first sol on Mars if contaminated spacecraft surfaces receive direct sunlight. Unfortunately, an instrument malfunction prevented the acquisition of UV light measurements during our balloon mission. To make up for the absence of radiometer data, we calculated a stratosphere UV model and conducted ground tests with a 271.1 nm UVC light source (0.5 W/m2), observing a similarly rapid inactivation rate when using a lower number of contaminants (640 spores per sample). The starting concentration of spores and microconfiguration on hardware surfaces appeared to influence survivability outcomes in both experiments. With the relatively few spores that survived the stratosphere, we performed a resequencing analysis and identified three single nucleotide polymorphisms compared to unexposed controls. It is therefore plausible that bacteria enduring radiation-rich environments (e.g., Earth's upper atmosphere, interplanetary space, or the surface of Mars) may be pushed in evolutionarily consequential directions. Key Words: Planetary protection—Stratosphere—Balloon—Mars analog environment—E-MIST payload—Bacillus pumilus SAFR-032. Astrobiology 17, 337–350.
Get full access to this article
View all access options for this article.
References
1.
AdamsJ.H., AdcockL., AppleJ., ChristlM., CleveandW., CoxM., DietzK., FergusonC., FountainW., and GhitaB. (2007) Deep space test bed for radiation studies. Nucl Instrum Methods Phys Res A, 579:522–525.
2.
Beck-WinchatzB. and BrambleJ. (2014) High-altitude ballooning student research with yeast and plant seeds. Gravit Space Res, 2:117–127.
3.
BenardiniJ.N., III, La DucM.T., BeaudetR.A., and KoukolR. (2014) Implementing planetary protection measures on the Mars Science Laboratory. Astrobiology, 14:27–32.
4.
CockellC.S., CatlingD.C., DavisW.L., SnookK., KepnerR.L., LeeP., and McKayC.P. (2000) The ultraviolet environment of Mars: biological implications past, present, and future. Icarus, 146:343–359.
5.
CockellC.S., SchuergerA.C., BilliD., FriedmannE.I., and PanitzC. (2005) Effects of a simulated martian UV flux on the cyanobacterium Chroococcidiopsis sp. 029. Astrobiology, 5:127–140.
6.
CucinottaF.A., SchimmerlingW., WilsonJ.W., PetersonL.E., BadhwarG.D., SagantiP.B., and DicelloJ.F. (2001) Space radiation cancer risks and uncertainties for Mars missions. Radiat Res, 156:682–688.
7.
DachevT.P. (2013) Profile of the ionizing radiation exposure between the Earth surface and free space. J Atmos Sol Terr Phys, 102:148–156.
8.
de la VegaU.P., RettbergP., and ReitzG. (2007) Simulation of the environmental climate conditions on martian surface and its effect on Deinococcus radiodurans. Adv Space Res, 40:1672–1677.
9.
DiazB. and Schulze-MakuchD. (2006) Microbial survival rates of Escherichia coli and Deinococcus radiodurans under low temperature, low pressure, and UV-irradiation conditions, and their relevance to possible martian life. Astrobiology, 6:332–347.
10.
FendrihanS., BércesA., LammerH., MussoM., RontóG., PolacsekT.K., HolzingerA., KolbC., and Stan-LotterH. (2009) Investigating the effects of simulated martian ultraviolet radiation on Halococcus dombrowskii and other extremely halophilic archaebacteria. Astrobiology, 9:104–112.
11.
GhosalD., OmelchenkoM.V., GaidamakovaE.K., MatrosovaV.Y., VasilenkoA., VenkateswaranA., ZhaiM., KostandarithesH.M., BrimH., MakarovaK.S., WackettL.P., FredricksonJ.K., and DalyM.J. (2005) How radiation kills cells: survival of Deinococcus radiodurans and Shewanella oneidensis under oxidative stress. FEMS Microbiol Rev, 29:361–375.
GómezF., Mateo-MartíE., Prieto-BallesterosO., Martín-GagoJ., and AmilsR. (2010) Protection of chemolithoautotrophic bacteria exposed to simulated Mars environmental conditions. Icarus, 209:482–487.
14.
HasslerD.M., ZeitlinC., Wimmer-SchweingruberR.F., EhresmannB., RafkinS., EigenbrodeJ.L., BrinzaD.E., WeigleG., BöttcherS., and BöhmE. (2014) Mars' surface radiation environment measured with the Mars Science Laboratory's Curiosity rover. Science, 343, doi:10.1126/science.1244797.
15.
HorneckG.P., RettbergP., ReitzG., WehnerJ., EschweilerU., StrauchK., PanitzC., StarkeV., and Baumstark-KhanC. (2001) Protection of bacterial spores in space, a contribution to the discussion on panspermia. Orig Life Evol Biosph, 31:527–547.
16.
HorneckG., KlausD.M., and MancinelliR.L. (2010) Space microbiology. Microbiol Mol Biol Rev, 74:121–156.
17.
HorneckG., MoellerR., CadetJ., DoukiT., MancinelliR.L., NicholsonW.L., PanitzC., RabbowE., RettbergP., SpryA., StackebrandtE., VaishampayanP., and VenkateswaranK.J. (2012) Resistance of bacterial endospores to outer space for planetary protection purposes—experiment PROTECT of the EXPOSE-E mission. Astrobiology, 12:445–456.
18.
JohnsonA.P., PrattL.M., VishnivetskayaT., PfiffnerS., BryanR.A., DadachovaE., WhyteL., RadtkeK., ChanE., and TronickS. (2011) Extended survival of several organisms and amino acids under simulated martian surface conditions. Icarus, 211:1162–1178.
19.
JonesW.V. (2014) Evolution of scientific ballooning and its impact on astrophysics research. Adv Space Res, 53:1405–1414.
20.
KempfM.J., ChenF., KernR., and VenkateswaranK. (2005) Recurrent isolation of hydrogen peroxide–resistant spores of Bacillus pumilus from a spacecraft assembly facility. Astrobiology, 5:391–405.
21.
KerneyK.R. and SchuergerA.C. (2011) Survival of Bacillus subtilis endospores on ultraviolet-irradiated rover wheels and Mars regolith under simulated martian conditions. Astrobiology, 11:477–485.
22.
KminekG. and RummelJ.D. (2015) COSPAR's planetary protection policy. Space Research Today, 193:7–19.
23.
KriskoA. and RadmanM. (2013) Biology of extreme radiation resistance: the way of Deinococcus radiodurans. Cold Spring Harb Perspect Biol, 5, doi:10.1101/cshperspect.a012765.
24.
KrulwichT.A., HicksD.B., and ItoM. (2009) Cation/proton antiporter complements of bacteria: why so large and diverse?. Mol Microbiol, 74:257–260.
25.
KuhnW. and AtreyaS. (1979) Solar radiation incident on the martian surface. J Mol Evol, 14:57–64.
26.
KyllingA., DanielsenT., BlumthalerM., SchrederJ., and JohnsenB. (2003) Twilight tropospheric and stratospheric photodissociation rates derived from balloon borne radiation measurements. Atmos Chem Phys, 3:377–385.
27.
La DucM.T., OsmanS., VaishampayanP., PicenoY., AndersenG., SpryJ.A., and VenkateswaranK. (2009) Comprehensive census of bacteria in clean rooms by using DNA microarray and cloning methods. Appl Environ Microbiol, 75:6559–6567.
28.
La DucM.T., VaishampayanP., NilssonH.R., TorokT., and VenkateswaranK. (2012) Pyrosequencing-derived bacterial, archaeal, and fungal diversity of spacecraft hardware destined for Mars. Appl Environ Microbiol, 78:5912–5922.
29.
LinkL., SawyerJ., VenkateswaranK., and NicholsonW. (2004) Extreme spore UV resistance of Bacillus pumilus isolates obtained from an ultraclean spacecraft assembly facility. Microb Ecol, 47:159–163.
30.
MancinelliR.L. and KlovstadM. (2000) Martian soil and UV radiation: microbial viability assessment on spacecraft surfaces. Planet Space Sci, 48:1093–1097.
31.
MancinelliR.L., WhiteM.R., and RothschildL.J. (1998) Biopan-survival I: exposure of the osmophiles Synechococcus sp. (Nageli) and Haloarcula sp. to the space environment. Adv Space Res, 22:324–327.
32.
McKayC.P., FriedmannE.I., Gómez-SilvaB., Cáceres-VillanuevaL., AndersenD.T., and LandheimR. (2003) Temperature and moisture conditions for life in the extreme arid region of the Atacama Desert: four years of observations including the El Niño of 1997–1998. Astrobiology, 3:393–406.
33.
McPetersR., HeathD., and BhartiaP. (1984) Average ozone profiles for 1979 from the NIMBUS 7 SBUV instrument. J Geophys Res: Atmospheres, 89:5199–5214.
34.
McPetersR.D., BhartiaP., KruegerA.J., HermanJ.R., SchlesingerB.M., WellemeyerC.G., SeftorC.J., JarossG., TaylorS.L., and SwisslerT. (1996) Nimbus-7 total ozone mapping spectrometer (TOMS) data products user's guide. NASA-RP-1384, National Aeronautics and Space Administration, Washington, DC.
35.
McPetersR.D., LabowG.J., and LoganJ.A. (2007) Ozone climatological profiles for satellite retrieval algorithms. J Geophys Res: Atmospheres, 112, doi:10.1029/2005JD006823.
36.
MertensC.J., GronoffG.P., NormanR.B., HayesB.M., LusbyT.C., StraumeT., TobiskaW.K., HandsA., RydenK., BentonE., WileyS., GerseyB., WilkinsR., and XuX. (2016) Cosmic radiation dose measurements from the RaD-X flight campaign. Space Weather, 14:874–898.
37.
MoellerR., ReitzG., NicholsonW.L., The Protect Team, and HorneckG. (2012) Mutagenesis in bacterial spores exposed to space and simulated martian conditions: data from the EXPOSE-E spaceflight experiment PROTECT. Astrobiology, 12:457–468.
38.
MooresJ., SmithP., TannerR., SchuergerA., and VenkateswaranK. (2007) The shielding effect of small-scale martian surface geometry on ultraviolet flux. Icarus, 192:417–433.
39.
NASA. (2005) Planetary protection provisions for robotic extraterrestrial missions. NPR 8020.12 C, National Aeronautics and Space Administration, Washington, DC.
40.
NicholsonW. and SetlowP. (1990) Sporulation, germination and outgrowth. In Molecular Biology Methods for Bacillus, John Wiley and Sons, Hoboken, NJ, pp 391–450.
41.
NicholsonW.L., SchuergerA.C., and SetlowP. (2005) The solar UV environment and bacterial spore UV resistance: considerations for Earth-to-Mars transport by natural processes and human spaceflight. Mutat Res, 571:249–264.
42.
NicholsonW.L., MoellerR., the Protect Team, and HorneckG. (2012) Transcriptomic responses of germinating Bacillus subtilis spores exposed to 1.5 years of space and simulated martian conditions on the EXPOSE-E experiment PROTECT. Astrobiology, 12:469–486.
43.
OsmanS., PeetersZ., La DucM.T., MancinelliR., EhrenfreundP., and VenkateswaranK. (2008) Effect of shadowing on survival of bacteria under conditions simulating the martian atmosphere and UV radiation. Appl Environ Microbiol, 74:959–970.
44.
PeetersZ., VosD., Ten KateI., SelchF., van SluisC., SorokinD.Y., MuijzerG., Stan-LotterH., Van LoosdrechtM., and EhrenfreundP. (2010) Survival and death of the haloarchaeon Natronorubrum strain HG-1 in a simulated martian environment. Adv Space Res, 46:1149–1155.
45.
RettbergP., AnesioA.M., BakerV.R., BarossJ.A., CadyS.L., DetsisE., ForemanC.M., HauberE., OriG.G., and PearceD.A. (2016) Planetary protection and Mars Special Regions—a suggestion for updating the definition. Astrobiology, 16:119–125.
46.
RummelJ.D., BeatyD.W., JonesM.A., BakermansC., BarlowN.G., BostonP.J., ChevrierV.F., ClarkB.C., de VeraJ.-P.P., and GoughR.V. (2014) A new analysis of Mars “Special Regions”: findings of the second MEPAG Special Regions Science Analysis Group (SR-SAG2). Astrobiology, 14:887–968.
47.
SchaefferP., MilletJ., and AubertJ.P. (1965) Catabolic repression of bacterial sporulation. Proc Natl Acad Sci USA, 54:704–711.
48.
SchimmerlingW. (2007) Overview of NASA's space radiation research program. Gravit Space Res, 16:5–10.
49.
SchuergerA.C. and NicholsonW.L. (2016) Twenty-three species of hypobarophilic bacteria recovered from diverse ecosystems exhibit growth under simulated martian conditions at 0.7 kPa. Astrobiology, 16:335–347.
50.
SchuergerA.C., MancinelliR.L., KernR.G., RothschildL.J., and McKayC.P. (2003) Survival of endospores of Bacillus subtilis on spacecraft surfaces under simulated martian environments. Icarus, 165:253–276.
51.
SchuergerA.C., RichardsJ.T., HintzeP.E., and KernR.G. (2005) Surface characteristics of spacecraft components affect the aggregation of microorganisms and may lead to different survival rates of bacteria on Mars landers. Astrobiology, 5:545–559.
52.
SchuergerA.C., RichardsJ., NewcombeD., and VenkateswaranK. (2006) Rapid inactivation of seven Bacillus spp. under simulated Mars UV irradiation. Icarus, 181:52–62.
53.
SmithD.J. (2013) Microbes in the upper atmosphere and unique opportunities for astrobiology research. Astrobiology, 13:981–990.
54.
SmithD.J., SchuergerA.C., DavidsonM.M., PacalaS.W., BakermansC., and OnstottT.C. (2009) Survivability of Psychrobacter cryohalolentis K5 under simulated martian surface conditions. Astrobiology, 9:221–228.
55.
SmithD.J., GriffinD.W., McPetersR.D., WardP.D., and SchuergerA.C. (2011) Microbial survival in the stratosphere and implications for global dispersal. Aerobiologia, 27:319–332.
56.
SmithD.J., ThakrarP.J., BharratA.E., DokosA.G., KinneyT.L., JamesL.M., LaneM.A., KhodadadC.L., MaguireF., and MaloneyP.R. (2014) A balloon-based payload for Exposing Microorganisms in the Stratosphere (E-MIST). Gravit Space Res, 2:70–80.
57.
TauscherC., SchuergerA.C., and NicholsonW.L. (2006) Survival and germinability of Bacillus subtilis spores exposed to simulated Mars solar radiation: implications for life detection and planetary protection. Astrobiology, 6:592–605.
58.
TirumalaiM.R., RastogiR., ZamaniN., O'Bryant WilliamsE., AllenS., DioufF., KwendeS., WeinstockG.M., VenkateswaranK.J., and FoxG.E. (2013) Candidate genes that may be responsible for the unusual resistances exhibited by Bacillus pumilus SAFR-032 spores. PLoS One, 8, doi:10.1371/journal.pone.0066012.
59.
VaishampayanP.A., RabbowE., HorneckG., and VenkateswaranK.J. (2012) Survival of Bacillus pumilus spores for a prolonged period of time in real space conditions. Astrobiology, 12:487–497.
60.
VaishampayanP., ProbstA.J., La DucM.T., BargomaE., BenardiniJ.N., AndersenG.L., and VenkateswaranK. (2013) New perspectives on viable microbial communities in low-biomass cleanroom environments. ISME J, 7:312–324.
61.
Wynn-WilliamsD. and EdwardsH. (2000) Antarctic ecosystems as models for extraterrestrial surface habitats. Planet Space Sci, 48:1065–1075.
62.
ZurekR.W., BarnesJ.R., HaberleR.M., PollackJ.B., TillmanJ.E., and LeovyC.B. (1992) Dynamics of the atmosphere of Mars. In Mars, edited by MatthewsM.S., KiefferH.H., JakoskyB.M., and SnyderC., University of Arizona Press, Tucson, pp 835–933.
Supplementary Material
Please find the following supplemental material available below.
For Open Access articles published under a Creative Commons License, all supplemental material carries the same license as the article it is associated with.
For non-Open Access articles published, all supplemental material carries a non-exclusive license, and permission requests for re-use of supplemental material or any part of supplemental material shall be sent directly to the copyright owner as specified in the copyright notice associated with the article.
