Somatic embryos of daylily in space

Poor growth and nuclear abnormalities observable in some space-grown plants have been hypothesized as due to a combination of factors such as degree of development, the specific way the plants are grown and the way they experience multiple stresses, some of which are space-specific. Data from a 132-...

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Veröffentlicht in:	Advances in space research 1999, Vol.23 (12), p.1987-1997
1. Verfasser:	Krikorian, A.D.
Format:	Artikel
Sprache:	eng
Schlagworte:	Cell Division Chromosome Aberrations Ethylenes - metabolism Liliaceae - cytology Liliaceae - embryology Liliaceae - genetics Liliaceae - growth & development Plant Growth Regulators - metabolism Space Flight Space life sciences Weightlessness
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container_end_page	1997
container_issue	12
container_start_page	1987
container_title	Advances in space research
container_volume	23
creator	Krikorian, A.D.
description	Poor growth and nuclear abnormalities observable in some space-grown plants have been hypothesized as due to a combination of factors such as degree of development, the specific way the plants are grown and the way they experience multiple stresses, some of which are space-specific. Data from a 132-day experiment on ‘Mir’ using embryogenic cell cultures of daylily ( Hemerocallis) allow seemingly contradictory evidence from earlier Shuttle missions to be harmonized: a) the more developed an embryo the less likely it is to suffer catastrophic cell stress during growth, whereas the less developed it is, the greater its vulnerability; (b) the extent to which the stress becomes manifest is also dependent on the extent of pre-existing stresses imposed by suboptimal growing conditions; (c) an appropriate, albeit undesirable, ‘stress match’ with other non-equilibrium determinants, much like a ‘tug of war’, can result in genomic variations in space. It is not understood what is/are the feature(s) of the space environment that cause the various cell division perturbations but they have not yet been mimicked on earth. The stress symptoms were found only in space materials and, as predicted, they were most frequently encountered in smaller, less-developed materials grown under non-optimized conditions. It is concluded that, while any substantial deviation from ‘optimum’ can be a ‘stress’, spaceflight subjects vulnerable materials to cell division or DNA-repair stress(es) that appear distinctive, but remain elusive so far. Fastidiously-controlled growing environments must be devised to resolve the matter of direct versus indirect effects of space. On a practical level, it is predicted that adapting plant biotechnologies to space conditions will not be a casual matter.
doi_str_mv	10.1016/S0273-1177(99)00345-2
format	Article
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source	MEDLINE; Elsevier ScienceDirect Journals
subjects	Cell Division Chromosome Aberrations Ethylenes - metabolism Liliaceae - cytology Liliaceae - embryology Liliaceae - genetics Liliaceae - growth & development Plant Growth Regulators - metabolism Space Flight Space life sciences Weightlessness
title	Somatic embryos of daylily in space
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