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Cell Signaling in Plants01:25

Cell Signaling in Plants

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Plant cells communicate to coordinate their cycle of growth, flowering and fruiting, and activities in roots, shoots, and leaves in response to the changing environmental conditions. Plant signaling is distinct from animal signaling. Plants primarily utilize enzyme-linked receptors, whereas the largest class of cell-surface receptors in animals are G-protein coupled receptors (GPCRs). Unlike animals, receptor tyrosine kinases are rare in plants. Instead, plants have a diverse class of...
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Intracellular Signaling Cascades01:24

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Once a ligand binds to a receptor, the signal is transmitted through the membrane and into the cytoplasm. The continuation of a signal in this manner is called signal transduction. Signal transduction only occurs with cell-surface receptors, which cannot interact with most components of the cell, such as DNA. Only internal receptors can interact directly with DNA in the nucleus to initiate protein synthesis. When a ligand binds to its receptor, conformational changes occur that affect the...
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Endocrine Signaling01:45

Endocrine Signaling

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Endocrine cells produce hormones to communicate with remote target cells found in other organs. The hormone reaches these distant areas using the circulatory system. This exposes the whole organism to the hormone but only those cells expressing hormone receptors or target cells are affected. Thus, endocrine signaling induces slow responses from its target cells but these effects also last longer.
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Interactions Between Signaling Pathways01:19

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Signaling cascades usually lack linearity. Multiple pathways interact and regulate one another, allowing cells to integrate and respond to diverse environmental stimuli.
Convergence and divergence, and cross-talk between signaling pathways
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Amplifying Signals via Enzymatic Cascade01:22

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When a ligand binds to a cell-surface receptor, the receptor's intracellular domain changes shape, which may either activate its enzyme function or allow its binding to other molecules. The initial signal is amplified by most signal transduction pathways. This means that a single ligand molecule can activate multiple molecules of a downstream target. Proteins that relay a signal are most commonly phosphorylated at one or more sites, activating or inactivating the protein. Kinases catalyze...
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Amplifying Signals via Second Messengers01:15

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Many receptor binding ligands are hydrophilic; they do not cross the cell membrane but bind to cell-surface receptors. Thus, their message must be relayed by second messengers present in the cell cytoplasm. There are several second messenger pathways, each with its own way of relaying information. For example, the G protein-coupled receptors can activate both phosphoinositol and cyclic AMP (cAMP) second messenger pathways. The phosphoinositol pathway is active when the receptor induces...
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ARF19 acts as a transient auxin response enhancer during root gravitropism.

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Related Experiment Video

Updated: Apr 3, 2026

A Strategy to Validate the Role of Callose-mediated Plasmodesmal Gating in the Tropic Response
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A Strategy to Validate the Role of Callose-mediated Plasmodesmal Gating in the Tropic Response

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Auxin signal transduction.

Gretchen Hagen1

  • 1Department of Biochemistry, University of Missouri-Columbia, Columbia, MO 65211, U.S.A. hageng@missouri.edu.

Essays in Biochemistry
|September 17, 2015
PubMed
Summary
This summary is machine-generated.

The plant hormone auxin (indole-3-acetic acid, IAA) regulates plant growth. Complex signaling pathways, involving nuclear receptors and multigene families, control gene expression and protein degradation, influencing diverse plant development.

Keywords:
Aux/IAA repressor proteinsSCF complexTIR1/AFBauxinauxin receptorauxin signal transductionauxin-regulated gene expressionauxin-response factors (ARFs)proteasome

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Area of Science:

  • Plant Biology
  • Molecular Biology
  • Genetics

Background:

  • The plant hormone auxin (indole-3-acetic acid, IAA) is crucial for plant growth and development.
  • Auxin signal transduction involves nuclear responses like gene activation and protein degradation, mediated by nuclear auxin receptors.

Purpose of the Study:

  • To elucidate the complexity and diversity of nuclear auxin signaling pathways.
  • To identify interacting partners within multigene families and understand their molecular mechanisms.
  • To integrate nuclear auxin signaling with other pathways, including plasma membrane-initiated responses.

Main Methods:

  • Molecular approaches
  • Genetic approaches
  • Biochemical approaches

Main Results:

  • Key components of auxin signal transduction have been identified.
  • Nuclear auxin receptors are integral to protein degradation machinery.
  • Multigene families contribute to the complexity of auxin signaling.

Conclusions:

  • Nuclear auxin signaling, while appearing simple, exhibits significant diversity due to multigene families.
  • Ongoing research focuses on identifying protein interactions and regulatory mechanisms.
  • Future work aims to integrate various auxin signaling pathways for a comprehensive understanding.