When a plant receives a signal, such as light, water, or an attack, this signal is first detected by specific receptors or sensors located on the surface of cells or within cells. Light is detected by photoreceptors, such as phytochromes and phototropins, which absorb specific wavelengths of light and undergo a structural change. This change activates the photoreceptor, triggering a cascade of intracellular events that often start with the photoreceptor phosphorylating itself or other proteins, initiating a signaling pathway.

For water detection, root cells have sensors that detect changes in soil water concentration. These sensors can be proteins that change conformation in response to moisture levels. When these sensors detect higher moisture levels, they often trigger ion channels to open or close, altering the flow of ions like calcium (Ca2+), potassium (K+), and chloride (Cl−) across the cell membrane.

In the case of herbivore attack, damage from herbivores is detected through mechanical stress sensors and chemical signals released from damaged cells. This leads to the production and release of signaling molecules like jasmonates, which then initiate defense responses.

Once a signal is received, it needs to be encoded into a form that can be transmitted and interpreted by the plant’s cells. Plants generate electrical signals through changes in membrane potential, similar to nerve impulses in animals. When a receptor is activated, it can cause ion channels to open, leading to an influx or efflux of ions. These electrical signals can travel along the plant’s vascular system, particularly the phloem, allowing rapid communication between distant parts of the plant.

Calcium signaling plays a significant role, with changes in calcium ion concentration (Ca2+ spikes) acting as a secondary messenger within cells. Specific patterns of calcium spikes encode different types of information. Proteins such as calmodulins bind to Ca2+ and change conformation, activating downstream signaling pathways that lead to specific cellular responses.

Hormonal signals also contribute to this process. Hormones like auxins, ABA, and jasmonates are synthesized in response to the initial signal. These hormones are then transported to target cells through the plant’s vascular system or via cell-to-cell transport. Target cells have specific receptors for these hormones. When a hormone binds to its receptor, it triggers a signal transduction pathway that often involves changes in gene expression, leading to the production of proteins that cause growth, stress responses, or defense mechanisms.

The final step is the integration and interpretation of these signals, leading to a coordinated response. The activation of signaling pathways often leads to the activation or repression of transcription factors, which are proteins that control the expression of specific genes. These genes might encode enzymes, structural proteins, or other factors that contribute to the plant’s response. For example, genes involved in cell wall loosening might be activated to allow cell elongation in response to auxin during phototropism.

Some responses require the activation of enzymes that modify other proteins or cellular structures. For instance, in response to herbivory, enzymes that produce defensive chemicals are activated. Proteins involved in the construction or modification of cellular structures, such as cell walls, might be activated to strengthen the plant’s defenses.

At the cellular and tissue levels, plants exhibit various changes. In phototropism, cells on the shaded side elongate more than those on the light-exposed side, causing the plant to bend towards the light. In response to herbivory, plants may produce toxic compounds or reinforce their cell walls to deter further attacks.

The decentralized nature of plant signaling means that each part of the plant can process information locally but also communicate with other parts to ensure a coordinated response. Individual cells or tissues respond to local signals, such as a leaf adjusting its angle to optimize light capture based on local light intensity. Hormones and electrical signals integrate these local responses into a cohesive action plan, ensuring that resources are allocated efficiently and the plant can respond to multiple stimuli simultaneously.