AI Article Synopsis
- Gravity influences plant growth and development through complex signaling pathways that help plants perceive the gravitational stimulus.
- Certain cells in specific organs detect gravity, leading to rapid responses that affect various biochemical and genomic processes.
- The integration of these signals and mechanisms, including the movement of amyloplasts, requires further study to fully understand how plants adapt to gravitational forces.
Article Abstract
Gravity is one of the environmental cues that direct plant growth and development. Recent investigations of different gravity signalling pathways have added complexity to how we think gravity is perceived. Particular cells within specific organs or tissues perceive gravity stimulus. Many downstream signalling events transmit the perceived information into subcellular, biochemical, and genomic responses. They are rapid, non-genomic, regulatory, and cell-specific. The chain of events may pass by signalling lipids, the cytoskeleton, intracellular calcium levels, protein phosphorylation-dependent pathways, proteome changes, membrane transport, vacuolar biogenesis mechanisms, or nuclear events. These events culminate in changes in gene expression and auxin lateral redistribution in gravity response sites. The possible integration of these signalling events with amyloplast movements or with other perception mechanisms is discussed. Further investigation is needed to understand how plants coordinate mechanisms and signals to sense this important physical factor.
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| http://dx.doi.org/10.1007/s00709-015-0859-5 | DOI Listing |
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