Scientific access to spaceflight and especially the International Space Station has revealed that physiological adaptation to spaceflight is accompanied or enabled by changes in gene expression that significantly alter the transcriptome of cells in spaceflight. A wide range of experiments have shown that plant physiological adaptation to spaceflight involves gene expression changes that alter cell wall and other metabolisms. However, while transcriptome profiling aptly illuminates changes in gene expression that accompany spaceflight adaptation, mutation analysis is required to illuminate key elements required for that adaptation.
Here we report how transcriptome profiling was used to gain insight into the spaceflight adaptation role of Altered response to gravity 1 (Arg1), a gene known to affect gravity responses in plants on Earth. The study compared expression profiles of cultured lines of Arabidopsis thaliana derived from wild-type (WT) cultivar Col-0 to profiles from a knock-out line deficient in the gene encoding ARG1 (ARG1 KO), both on the ground and in space. The cell lines were launched on SpaceX CRS-2 as part of the Cellular Expression Logic (CEL) experiment of the BRIC-17 spaceflight mission. The cultured cell lines were grown within 60 mm Petri plates in Petri Dish Fixation Units (PDFUs) that were housed within the Biological Research In Canisters (BRIC) hardware. Spaceflight samples were fixed on orbit. Differentially expressed genes were identified between the two environments (spaceflight and comparable ground controls) and the two genotypes (WT and ARG1 KO). Each genotype engaged unique genes during physiological adaptation to the spaceflight environment, with little overlap. Most of the genes altered in expression in spaceflight in WT cells were found to be Arg1-dependent, suggesting a major role for that gene in the physiological adaptation of undifferentiated cells to spaceflight. Key Words: ARG1—Spaceflight—Gene expression—Physiological adaptation—BRIC. Astrobiology 17, 1077–1111.
Get full access to this article
View all access options for this article.
References
1.
AbasL., BenjaminsR., MalenicaN., PaciorekT., WisniewskaJ., Moulinier-AnzolaJ.C., SiebererT., FrimlJ., and LuschnigC. (2006) Intracellular trafficking and proteolysis of the Arabidopsis auxin-efflux facilitator PIN2 are involved in root gravitropism. Nat Cell Biol, 8:249–256.
2.
BerkeyR., BendigeriD., and XiaoS. (2012) Sphingolipids and plant defense/disease: the “death” connection and beyond. Front Plant Sci, 3, doi:10.3389/fpls.2012.00068.
3.
BlancaflorE.B. (2013) Regulation of plant gravity sensing and signaling by the actin cytoskeleton. Am J Bot, 100:143–152.
4.
BoonsirichaiK., SedbrookJ.C., ChenR., GilroyS., and MassonP.H. (2003) ALTERED RESPONSE TO GRAVITY is a peripheral membrane protein that modulates gravity-induced cytoplasmic alkalinization and lateral auxin transport in plant statocytes. Plant Cell, 15:2612–2625.
5.
CabreraJ., BarcalaM., FenollC., and EscobarC. (2014) Transcriptomic signatures of transfer cells in early developing nematode feeding cells of Arabidopsis focused on auxin and ethylene signaling. Front Plant Sci, 5, doi:10.3389/fpls.2014.00107.
6.
CaplanA.J., CyrD.M., and DouglasM.G. (1993) Eukaryotic homologues of Escherichia coli dnaJ: a diverse protein family that functions with hsp70 stress proteins. Mol Biol Cell, 4:555–563.
7.
ChevalierD., BatouxM., FultonL., PfisterK., YadavR.K., SchellenbergM., and SchneitzK. (2005) STRUBBELIG defines a receptor kinase-mediated signaling pathway regulating organ development in Arabidopsis. Proc Natl Acad Sci USA, 102:9074–9079.
8.
DuZ., ZhouX., LingY., ZhangZ., and SuZ. (2010) agriGO: a GO analysis toolkit for the agricultural community. Nucleic Acids Res, 38:W64–W70.
9.
FenglerS., SpirerI., NeefM., EckeM., NieseltK., and HamppR. (2015) A whole-genome microarray study of Arabidopsis thaliana semisolid callus cultures exposed to microgravity and nonmicrogravity related spaceflight conditions for 5 days on board of Shenzhou 8. Biomed Res Int, 2015, doi:10.1155/2015/547495.
10.
GagneJ.M., SongS.K., and ClarkS.E. (2008) POLTERGEIST and PLL1 are required for stem cell function with potential roles in cell asymmetry and auxin signaling. Commun Integr Biol, 1:53–55.
11.
GaoX., NagawaS., WangG., and YangZ. (2008) Cell polarity signaling: focus on polar auxin transport. Mol Plant, 1:899–909.
12.
GleesonL., SquiresS., and BisgroveS.R. (2012) The microtubule associated protein END BINDING 1 represses root responses to mechanical cues. Plant Sci, 187:1–9.
13.
GuanC., RosenE.S., BoonsirichaiK., PoffK.L., and MassonP.H. (2003) The ARG1-LIKE2 gene of Arabidopsis functions in a gravity signal transduction pathway that is genetically distinct from the PGM pathway. Plant Physiol, 133:100–112.
14.
HarrisonB. and MassonP.H. (2008a) ARG1 and ARL2 form an actin-based gravity-signaling chaperone complex in root statocytes?. Plant Signal Behav, 3:650–653.
15.
HarrisonB.R. and MassonP.H. (2008b) ARL2, ARG1 and PIN3 define a gravity signal transduction pathway in root statocytes. Plant J, 53:380–392.
16.
HsiehW.P., HsiehH.L., and WuS.H. (2012) Arabidopsis bZIP16 transcription factor integrates light and hormone signaling pathways to regulate early seedling development. Plant Cell, 24:3997–4011.
17.
HuangH., QuintM., and GrayW.M. (2013) The eta7/csn3-3 auxin response mutant of Arabidopsis defines a novel function for the CSN3 subunit of the COP9 signalosome. PLoS One, 8, doi:10.1371/journal.pone.0066578.
18.
HubbellE., LiuW.M., and MeiR. (2002) Robust estimators for expression analysis. Bioinformatics, 18:1585–1592.
19.
IngberD. (1999) How cells (might) sense microgravity. FASEB J, 13:S3–S15.
20.
JeongS., EilbertE., BolbolA., and LukowitzW. (2016) Going mainstream: how is the body axis of plants first initiated in the embryo?. Dev Biol, 419:78–84.
21.
JohnsonC.M., SubramanianA., EdelmannR.E., and KissJ.Z. (2015) Morphometric analyses of petioles of seedlings grown in a spaceflight experiment. J Plant Res, 128:1007–1016.
22.
JouhetJ. and GrayJ.C. (2009) Interaction of actin and the chloroplast protein import apparatus. J Biol Chem, 284:19132–19141.
23.
KamadaM., HigashitaniA., and IshiokaN. (2005) Proteomic analysis of Arabidopsis root gravitropism. Biol Sci Space, 19:148–154.
24.
KatoT., MoritaM.T., FukakiH., YamauchiY., UeharaM., NiihamaM., and TasakaM. (2002) SGR2, a phospholipase-like protein, and ZIG/SGR4, a SNARE, are involved in the shoot gravitropism of Arabidopsis. Plant Cell, 14:33–46.
25.
KimuraY., YaharaI., and LindquistS. (1995) Role of the protein chaperone YDJ1 in establishing Hsp90-mediated signal transduction pathways. Science, 268:1362–1365.
26.
Kleine-VehnJ., DingZ., JonesA.R., TasakaM., MoritaM.T., and FrimlJ. (2010) Gravity-induced PIN transcytosis for polarization of auxin fluxes in gravity-sensing root cells. Proc Natl Acad Sci USA, 107:22344–22349.
27.
KoizumiK., HayashiT., WuS., and GallagherK.L. (2012) The SHORT-ROOT protein acts as a mobile, dose-dependent signal in patterning the ground tissue. Proc Natl Acad Sci USA, 109:13010–13015.
28.
KwonT., SparksJ.A., NakashimaJ., AllenS.N., TangY., and BlancaflorE.B. (2015) Transcriptional response of Arabidopsis seedlings during spaceflight reveals peroxidase and cell wall remodeling genes associated with root hair development. Am J Bot, 102:21–35.
29.
LehmanA., BlackR., and EckerJ.R. (1996) HOOKLESS1, an ethylene response gene, is required for differential cell elongation in the Arabidopsis hypocotyl. Cell, 85:183–194.
30.
MoritaM.T. and NakamuraM. (2012) Dynamic behavior of plastids related to environmental response. Curr Opin Plant Biol, 15:722–728.
31.
NedukhaE.M. (1997) Effects of microgravity on the structure and function of plant cell walls. Int Rev Cytol, 170:39–77.
32.
NomotoY., KubozonoS., YamashinoT., NakamichiN., and MizunoT. (2012) Circadian clock- and PIF4-controlled plant growth: a coincidence mechanism directly integrates a hormone signaling network into the photoperiodic control of plant architectures in Arabidopsis thaliana. Plant Cell Physiol, 53:1950–1964.
33.
ObayashiT., HayashiS., SaekiM., OhtaH., and KinoshitaK. (2009) ATTED-II provides coexpressed gene networks for Arabidopsis. Nucleic Acids Res, 37:D987–D991.
34.
PaulA.-L., ZupanskaA., OstrowD.T., ZhangY., SunY., LiJ.-L., ShankerS., FarmerieW.G., AmalfitanoC.E., and FerlR.J. (2012) Spaceflight transcriptomes: unique responses to a novel environment. Astrobiology, 12:40–56.
35.
PaulA.-L., ZupanskaA.K., SchultzE.R., and FerlR.J. (2013) Organ-specific remodeling of the Arabidopsis transcriptome in response to spaceflight. BMC Plant Biol, 13, doi:10.1186/1471-2229-13-112.
36.
QinZ., ZhangX., XinW., LiJ., and HuY. (2014) The Arabidopsis transcription factor IIB-related protein BRP4 is involved in the regulation of mitotic cell-cycle progression during male gametogenesis. J Exp Bot, 65:2521–2531.
37.
R Development Core Team. (2012) R: A Language and Environment for Statistical Computing,R Foundation for Statistical Computing, Vienna, Austria.
38.
ReaG., CristofaroF., PaniG., PascucciB., GhugeS.A., CorsettoP.A., ImbrianiM., VisaiL., and RizzoA.M. (2016) Microgravity-driven remodeling of the proteome reveals insights into molecular mechanisms and signal networks involved in response to the space flight environment. J Proteomics, 137:3–18.
39.
ReimandJ., KullM., PetersonH., HansenJ., and ViloJ. (2007) g:Profiler—a web-based toolset for functional profiling of gene lists from large-scale experiments. Nucleic Acids Res, 35:W193–W200.
40.
ReinhartB.J., LiuT., NewellN.R., MagnaniE., HuangT., KerstetterR., MichaelsS., and BartonM.K. (2013) Establishing a framework for the Ad/Abaxial regulatory network of Arabidopsis: ascertaining targets of Class III HOMEODOMAIN LEUCINE ZIPPER and KANADI regulation. Plant Cell, 25:3228–3249.
41.
SaedlerR., JakobyM., MarinB., Galiana-JaimeE., and HulskampM. (2009) The cell morphogenesis gene SPIRRIG in Arabidopsis encodes a WD/BEACH domain protein. Plant J, 59:612–621.
42.
SalmiM.L. and RouxS.J. (2008) Gene expression changes induced by space flight in single-cells of the fern Ceratopteris richardii. Planta, 229:151–159.
43.
SatoE.M., HijaziH., BennettM.J., VissenbergK., and SwarupR. (2015) New insights into root gravitropic signalling. J Exp Bot, 66:2155–2165.
44.
SchenkP.M., KazanK., MannersJ.M., AndersonJ.P., SimpsonR.S., WilsonI.W., SomervilleS.C., and MacleanD.J. (2003) Systemic gene expression in Arabidopsis during an incompatible interaction with Alternaria brassicicola. Plant Physiol, 132:999–1010.
45.
SchülerO., HemmersbachR., and BöhmerM. (2015) A bird's-eye view of molecular changes in plant gravitropism using omics techniques. Front Plant Sci, 6, doi:10.3389/fpls.2015.01176.
46.
SchwabB., MathurJ., SaedlerR., SchwarzH., FreyB., ScheideggerC., and HulskampM. (2003) Regulation of cell expansion by the DISTORTED genes in Arabidopsis thaliana: actin controls the spatial organization of microtubules. Mol Genet Genomics, 269:350–360.
47.
SedbrookJ., BoonsirichaiK., ChenR., HilsonP., PearlmanR., RosenE., RutherfordR., BatizaA., CarrollK., SchulzT., and MassonP.H. (1998) Molecular genetics of root gravitropism and waving in Arabidopsis thaliana. Gravit Space Biol Bull, 11:71–78.
48.
SedbrookJ.C., ChenR., and MassonP.H. (1999) ARG1 (altered response to gravity) encodes a DnaJ-like protein that potentially interacts with the cytoskeleton. Proc Natl Acad Sci USA, 96:1140–1145.
49.
SenechalF., GraffL., SurcoufO., MarceloP., RayonC., BoutonS., MareckA., MouilleG., StintziA., HöfteH., LerougeP., SchallerA., and PellouxJ. (2014) Arabidopsis PECTIN METHYLESTERASE17 is co-expressed with and processed by SBT3.5, a subtilisin-like serine protease. Ann Bot, 114:1161–1175.
50.
SmythG.K. (2004) Linear models and empirical Bayes methods for assessing differential expression in microarray experiments. Stat Appl Genet Mol Biol 3,Article3.
51.
SogaK., HaradaK., WakabayashiK., HosonT., and KamisakaS. (1999) Increased molecular mass of hemicellulosic polysaccharides is involved in growth inhibition of maize coleoptiles and mesocotyls under hypergravity conditions. J Plant Res, 112:273–278.
52.
SogaK., WakabayashiK., KamisakaS., and HosonT. (2002) Stimulation of elongation growth and xyloglucan breakdown in Arabidopsis hypocotyls under microgravity conditions in space. Planta, 215:1040–1046.
53.
StangaJ.P., BoonsirichaiK., SedbrookJ.C., OteguiM.S., and MassonP.H. (2009) A role for the TOC complex in Arabidopsis root gravitropism. Plant Physiol, 149:1896–1905.
54.
SuP.H. and LiH.M. (2010) Stromal Hsp70 is important for protein translocation into pea and Arabidopsis chloroplasts. Plant Cell, 22:1516–1531.
55.
SurpinM. (2014) Plant chemical genomics: gravity sensing and response. Methods Mol Biol, 1056:115–124.
56.
SurpinM., Rojas-PierceM., CarterC., HicksG.R., VasquezJ., and RaikhelN.V. (2005) The power of chemical genomics to study the link between endomembrane system components and the gravitropic response. Proc Natl Acad Sci USA, 102:4902–4907.
57.
TameshigeT., HirakawaY., ToriiK.U., and UchidaN. (2015) Cell walls as a stage for intercellular communication regulating shoot meristem development. Front Plant Sci, 6, doi:10.3389/fpls.2015.00324.
58.
van WykS.G., Du PlessisM., CullisC.A., KunertK.J., and VorsterB.J. (2014) Cysteine protease and cystatin expression and activity during soybean nodule development and senescence. BMC Plant Biol, 14, doi:10.1186/s12870-014-0294-3.
59.
VandenbrinkJ.P. and KissJ.Z. (2016) Space, the final frontier: a critical review of recent experiments performed in microgravity. Plant Sci, 243:115–119.
60.
VorselenD., RoosW.H., MacKintoshF.C., WuiteG.J., and van LoonJ.J. (2014) The role of the cytoskeleton in sensing changes in gravity by nonspecialized cells. FASEB J, 28:536–547.
61.
WalperE., WeisteC., MuellerM.J., HambergM., and Droge-LaserW. (2016) Screen identifying Arabidopsis transcription factors involved in the response to 9-lipoxygenase-derived oxylipins. PLoS One, 11, doi:10.1371/journal.pone.0153216.
62.
YoungJ.C., BarralJ.M., and Ulrich HartlF. (2003) More than folding: localized functions of cytosolic chaperones. Trends Biochem Sci, 28:541–547.
63.
ZouN., LiB., ChenH., SuY., KronzuckerH.J., XiongL., BaluskaF., and ShiW. (2013) GSA-1/ARG1 protects root gravitropism in Arabidopsis under ammonium stress. New Phytol, 200:97–111.
64.
ZupanskaA.K., DenisonF.C., FerlR.J., and PaulA.-L. (2013) Spaceflight engages heat shock protein and other molecular chaperone genes in tissue culture cells of Arabidopsis thaliana. Am J Bot, 100:235–248.
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.
