Journal of Experimental Botany

JXB Advance Access published online on July 16, 2003
Journal of Experimental Botany, doi:10.1093/jxb/erg218
© 2003 by Oxford University Press

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Received January 28, 2003; accepted May 15, 2003
© 2003 Society for Experimental Biology

RESEARCH PAPER

Ultrastructure of potato tubers formed in microgravity under controlled environmental conditions

Martha E. Cook ^1* and Judith G. Croxdale ²

¹ Department of Biological Sciences, Illinois State University, Normal, IL 61790, USA
² Department of Botany, University of Wisconsin, Madison, WI 53706, USA

^* To whom correspondence should be addressed. E-mail: mecook1{at}ilstu.edu.

	Abstract

Previous spaceflight reports attribute changes in plant ultrastructure to microgravity, but it was thought that the changes might result from growth in uncontrolled environments during spaceflight. To test this possibility, potato explants were examined (a leaf, axillary bud, and small stem segment) grown in the ASTROCULTURE^TM plant growth unit, which provided a controlled environment. During the 16 d flight of space shuttle Columbia (STS-73), the axillary bud of each explant developed into a mature tuber. Upon return to Earth, tuber slices were examined by transmission electron microscopy. Results showed that the cell ultrastructure of flight-grown tubers could not be distinguished from that of tuber cells grown in the same growth unit on the ground. No differences were observed in cellular features such as protein crystals, plastids with starch grains, mitochondria, rough ER, or plasmodesmata. Cell wall structure, including underlying microtubules, was typical of ground-grown plants. Because cell walls of tubers formed in space were not required to provide support against the force due to gravity, it was hypothesized that these walls might exhibit differences in wall components as compared with walls formed in Earth-grown tubers. Wall components were immunolocalized at the TEM level using monoclonal antibodies JIM 5 and JIM 7, which recognize epitopes of pectins, molecules thought to contribute to wall rigidity and cell adhesion. No difference in presence, abundance or distribution of these pectin epitopes was seen between space- and Earth-grown tubers. This evidence indicates that for the parameters studied, microgravity does not affect the cellular structure of plants grown under controlled environmental conditions.

Key words: Cell wall, microgravity, pectin, plant, Solanum, spaceflight, tuber, ultrastructure.

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