A novel phototropic response to red light is revealed in microgravity.

The aim of this study was to investigate phototropism in plants grown in microgravity conditions without the complications of a 1-g environment. Experiments performed on the International Space Station (ISS) were used to explore the mechanisms of both blue-light- and red-light-induced phototropism in plants. This project utilized the European Modular Cultivation System (EMCS), which has environmental controls for plant growth as well as centrifuges for gravity treatments used as a 1-g control. Images captured from video tapes were used to analyze the growth, development, and curvature of Arabidopsis thaliana plants that developed from seed in space. A novel positive phototropic response to red light was observed in hypocotyls of seedlings that developed in microgravity. This response was not apparent in seedlings grown on Earth or in the 1-g control during the space flight. In addition, blue-light-based phototropism had a greater response in microgravity compared with the 1-g control. Although flowering plants are generally thought to lack red light phototropism, our data suggest that at least some flowering plants may have retained a red light sensory system for phototropism. Thus, this discovery may have important implications for understanding the evolution of light sensory systems in plants.

[1]  Nina Jonsson,et al.  Development and Growth , 2011 .

[2]  T. Wada,et al.  RPT2: A Signal Transducer of the Phototropic Response in Arabidopsis , 2000, Plant Cell.

[3]  T. Kagawa,et al.  Phototropin and light-signaling in phototropism. , 2006, Current opinion in plant biology.

[4]  Melanie J Correll,et al.  Phytochromes A and B Mediate Red-Light-Induced Positive Phototropism in Roots1 , 2003, Plant Physiology.

[5]  Richard E. Edelmann,et al.  Operations of a spaceflight experiment to investigate plant tropisms , 2009 .

[6]  L. Hennig,et al.  Phytochrome E controls light-induced germination of Arabidopsis. , 2002, Plant physiology.

[7]  Plants circling in outer space. , 2009, The New phytologist.

[8]  A. Johnsson,et al.  Gravity amplifies and microgravity decreases circumnutations in Arabidopsis thaliana stems: results from a space experiment. , 2009, The New phytologist.

[9]  N. Suetsugu,et al.  Phytochrome‐dependent Photomovement Responses Mediated by Phototropin Family Proteins in Cryptogam Plants † , 2007, Photochemistry and photobiology.

[10]  P. Song,et al.  Phytochrome-mediated photomorphogenesis in plants , 2007, Journal of Plant Biology.

[11]  J. Kiss,et al.  Red-light-induced positive phototropism in Arabidopsis roots , 2001, Planta.

[12]  T. Berleth,et al.  Growth and development: Integrating signals and differentiating tissues — the ‘calculus’ of plant development , 2006 .

[13]  F. Mittmann,et al.  Analysis of the phytochrome gene family in Ceratodon purpureus by gene targeting reveals the primary phytochrome responsible for photo- and polarotropism , 2009, Planta.

[14]  E. Schäfer,et al.  The light-induced reduction of the gravitropic growth-orientation of seedlings of Arabidopsis thaliana (L.) Heynh. is a photomorphogenic response mediated synergistically by the far-red-absorbing forms of phytochromes A and B , 2004, Planta.

[15]  J. Kiss,et al.  The role of phytochrome C in gravitropism and phototropism in Arabidopsis thaliana. , 2008, Functional plant biology : FPB.

[16]  Melanie J. Correll,et al.  Interactions Between Gravitropism and Phototropism in Plants , 2002, Journal of Plant Growth Regulation.

[17]  J. Christie Phototropin blue-light receptors. , 2007, Annual review of plant biology.

[18]  Richard E. Edelmann,et al.  Gravitropism of hypocotyls of wild-type and starch-deficient Arabidopsis seedlings in spaceflight studies , 1999, Planta.

[19]  C. Fankhauser,et al.  Phytochrome-mediated light signalling in Arabidopsis. , 2004, Current opinion in plant biology.

[20]  G. Blaauw‐Jansen,et al.  Effect of red light on irreversible and reversible expansion of Avena coleoptile sections , 1966, Planta.

[21]  E. Schäfer,et al.  Interaction of gravi- and phototropic stimulation in the response of maize (Zea mays L.) coleoptiles , 1988, Planta.

[22]  J. Kiss,et al.  Phytochromes play a role in phototropism and gravitropism in Arabidopsis roots. , 2003, Advances in space research : the official journal of the Committee on Space Research.

[23]  M. Iino,et al.  Phytochrome is required for the occurrence of time-dependent phototropism in maize coleoptiles , 1996, Plant, cell & environment.

[24]  Contributions of Space Experiments to the Study of Gravitropism , 2002, Journal of Plant Growth Regulation.

[25]  Eugénie Carnero-Diaz,et al.  Gravisensitivity and automorphogenesis of lentil seedling roots grown on board the International Space Station. , 2008, Physiologia plantarum.

[26]  Harry Smith,et al.  Analysis of growth rates during phototropism: modifications by separate light‐growth responses , 1987 .

[27]  John Z. Kiss,et al.  Space‐Based Research on Plant Tropisms , 2008 .

[28]  J. Kiss,et al.  Development and Growth of Several Strains of Arabidopsis Seedlings in Microgravity1 , 2000, International Journal of Plant Sciences.

[29]  E. Schäfer,et al.  Phytochrome-mediated phototropism in maize seedling shoots , 2004, Planta.

[30]  G. Whitelam,et al.  The signal transducing photoreceptors of plants. , 2005, The International journal of developmental biology.

[31]  G. Blaauw‐Jansen THE INFLUENCE OF RED AND FAR RED LIGHT ON GROWTH AND PHOTOTROPISM OF THE AVENA SEEDLING , 1959 .

[32]  M. Iino Phototropism : mechanisms and ecological implications , 1990 .

[33]  P. Quail,et al.  Multiple Phytochromes Are Involved in Red-Light-Induced Enhancement of First-Positive Phototropism in Arabidopsis thaliana , 1997, Plant physiology.

[34]  R. Hangarter,et al.  Gravity, light and plant form. , 1997, Plant, cell & environment.

[35]  K. L. Poff,et al.  Growth Distribution during Phototropism of Arabidopsis thaliana Seedlings , 1993, Plant physiology.

[36]  E Brinckmann Spaceflight opportunities on the ISS for plant research--the ESA perspective. , 1999, Advances in space research : the official journal of the Committee on Space Research.

[37]  J. Kiss Negative phototropism in young gametophytes of the fern Schizaea pusilla , 1994 .

[38]  C. Fankhauser,et al.  Hypocotyl growth orientation in blue light is determined by phytochrome A inhibition of gravitropism and phototropin promotion of phototropism. , 2004, The Plant journal : for cell and molecular biology.

[39]  S. Vitha,et al.  Interaction of root gravitropism and phototropism in Arabidopsis wild-type and starchless mutants. , 2000, Plant physiology.

[40]  R. Hangarter,et al.  Phototropism: Bending towards Enlightenment , 2006, The Plant Cell Online.

[41]  P. Robson,et al.  Genetic and Transgenic Evidence That Phytochromes A and B Act to Modulate the Gravitropic Orientation of Arabidopsis thaliana Hypocotyls , 1996, Plant physiology.

[42]  E. Brinckmann,et al.  ESA hardware for plant research on the International Space Station , 2005 .

[43]  C. Darwin Power of Movement in Plants , 1880 .

[44]  J. Kiss,et al.  Modulation of phototropism by phytochrome E and attenuation of gravitropism by phytochromes B and E in inflorescence stems , 2006 .

[45]  Allan H. Brown,et al.  The phototropic response of Triticum aestivum coleoptiles under conditions of low gravity , 1995 .

[46]  John Z. Kiss,et al.  Chapter 1 Phototropism and Gravitropism in Plants , 2009 .

[47]  Y. Shimura,et al.  Mutational Analysis of Root Gravitropism and Phototropism of Arabidopsis thaliana Seedlings , 1992 .

[48]  J. Kiss,et al.  PKS1 plays a role in red-light-based positive phototropism in roots. , 2008, Plant, Cell and Environment.

[49]  F. Sack,et al.  Irradiance-dependent regulation of gravitropism by red light in protonemata of the moss Ceratodon purpureus , 1999, Planta.

[50]  A. H. Blaauw Licht und Wachstum , 1918 .

[51]  P. B. Green,et al.  High‐resolution measurement of growth during first positive phototropism in maize , 1985 .

[52]  Richard E. Edelmann,et al.  Ground-based studies of tropisms in hardware developed for the European Modular Cultivation System (EMCS) , 2005 .

[53]  P. Quail,et al.  Phytochrome A Regulates Red-Light Induction of Phototropic Enhancement in Arabidopsis , 1996, Plant physiology.

[54]  D. Marshall Porterfield,et al.  The Biophysical Limitations in Physiological Transport and Exchange in Plants Grown in Microgravity , 2002, Journal of Plant Growth Regulation.

[55]  J. Kiss,et al.  The influence of microgravity and spaceflight on columella cell ultrastructure in starch-deficient mutants of Arabidopsis. , 1999, American journal of botany.

[56]  Robert Ferl,et al.  Plants in space. , 2002, Current opinion in plant biology.

[57]  M. Evans,et al.  Kinetics of constant gravitropic stimulus responses in Arabidopsis roots using a feedback system. , 2000, Plant physiology.