Effect of Microgravity Simulation on Plant Germination

International Journal of Emerging Research in Science, Engineering, and Management
Vol. 1, Issue 1, pp. 10-14, July 2025.

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Effect of Microgravity Simulation on Plant Germination

J Venkatagiri

Z. Chaitanya

Associate Professor, Department of CSE, Ramaiah University of Applied Sciences, Bengaluru, Karnataka, India.

Assistant Professor, Department of ECE, Geethanjali Institute of Science and Technology, Nellore, India.

Abstract: The exploration of plant growth under microgravity conditions has garnered significant attention due to its implications for long-term space missions and extraterrestrial agriculture. Germination, being the first critical stage in a plant’s life cycle, is especially sensitive to gravitational cues. This paper investigates the effects of simulated microgravity on plant germination by analyzing outcomes from various experimental setups such as clinostats, random positioning machines, and spaceflight missions. The literature reveals varied responses depending on plant species and experimental conditions, including altered root and shoot orientation, changes in hormone levels such as indole-3-acetic acid and gibberellic acid, and modifications in cellular structures. Studies also highlight the adaptability of certain plants, such as Arabidopsis thaliana, Vigna radiata, and wheatgrass, under microgravity, with some showing enhanced biochemical properties. Furthermore, recent advances in simulation protocols and hardware miniaturization have enabled more precise and autonomous germination studies in microgravity environments. These insights are crucial for optimizing plant cultivation systems in space and understanding fundamental biological processes influenced by gravity.

Keywords: Arabidopsis, Clinostat, Germination, Microgravity, Space Agriculture.

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This article is part of Volume 1, Issue 1 (July 2025)