Prolonged exposure to hypergravity increases number and size of cells and enhances lignin deposition in the stem of Arabidopsis thaliana

We have performed a lab-based hypergravity cultivation experiment using a centrifuge equipped with a lighting system and examined long-term effects of hypergravity on the development of the main axis of the Arabidopsis ( Arabidopsis thaliana (L.) Heynh.) primary inflorescence, which comprises the ra...

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Bibliographic Details
Published in:Journal of plant research 2024-09, Vol.137 (5), p.927-937
Main Authors: Shinohara, Hironori, Muramoto, Masaki, Tamaoki, Daisuke, Kamachi, Hiroyuki, Inoue, Hiroshi, Kume, Atsushi, Karahara, Ichirou
Format: Article
Language:English
Subjects:
Acceleration
Arabidopsis - growth & development
Arabidopsis - physiology
Arabidopsis thaliana
Biomedical and Life Sciences
Cell number
Cell size
Deposition
Exposure
Fibers
Gravitational effects
Gravity
High gravity environments
Hypergravity
Life Sciences
Lignin
Lignin - metabolism
Long-term effects
Physical characteristics
Plant Biochemistry
Plant Ecology
Plant Leaves - growth & development
Plant Physiology
Plant Sciences
Plant Stems - anatomy & histology
Plant Stems - growth & development
Plants (botany)
Regular Paper – Morphology/Anatomy/Structural Biology
Rosette
Stems
Xylem
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Summary:We have performed a lab-based hypergravity cultivation experiment using a centrifuge equipped with a lighting system and examined long-term effects of hypergravity on the development of the main axis of the Arabidopsis ( Arabidopsis thaliana (L.) Heynh.) primary inflorescence, which comprises the rachis and peduncle, collectively referred to as the main stem for simplicity. Plants grown under 1 × g (gravitational acceleration on Earth) conditions for 20–23 days and having the first visible flower bud were exposed to hypergravity at 8 × g for 10 days. We analyzed the effect of prolonged hypergravity conditions on growth, lignin deposition, and tissue anatomy of the main stem. As a result, the length of the main stem decreased and cross-sectional area, dry mass per unit length, cell number, and lignin content of the main stem significantly increased under hypergravity. Lignin content in the rosette leaves also increased when they were exposed to hypergravity during their development. Except for interfascicular fibers, cross-sectional areas of the tissues composing the internode significantly increased under hypergravity in most types of the tissues in the basal part than the apical part of the main stem, indicating that the effect of hypergravity is more pronounced in the basal part than the apical part. The number of cells in the fascicular cambium and xylem significantly increased under hypergravity both in the apical and basal internodes of the main stem, indicating a possibility that hypergravity stimulates procambium activity to produce xylem element more than phloem element. The main stem was suggested to be strengthened through changes in its morphological characteristics as well as lignin deposition under prolonged hypergravity conditions.
ISSN:0918-9440
1618-0860
1618-0860
DOI:10.1007/s10265-024-01556-x