Brassinolide
Brassinolide is a plant hormone. The first isolated brassinosteroid, it was discovered when it was shown that pollen from rapeseed could promote stem elongation and cell division. The biologically active component was isolated and named brassinolide.
Biosynthesis
The production of brassinolide begins with a closely related sterol called campesterol, which is found in the cell membrane. Initially, it is reduced by an enzyme called DET2. This is followed by a series of oxidation reactions, facilitated by cytochrome P-450 enzymes, which add hydroxyl groups to the molecule. The most biologically significant of these reactions is the C6 oxidation, where a ketone is formed at the C6 carbon position. This single reaction increases the biological activity of the molecule by a factor of 200. Depending on when this C6 oxidation occurs, it is referred to as either the early or late C6 oxidation pathway. Both of these synthetic pathways have been observed in Arabidopsis seedlings. It appears that the late C6 oxidation pathway predominates when the seedlings are exposed to light, while the early pathway is active in the absence of light. If the plant cannot perform C6 oxidation, it results in the "Dwarf phenotype," characterized by severe growth deficits.Finally, in Arabidopsis, the Baeyer-Villiger lactonization process occurs through the action of the two homologous enzymes CYP85A1 and CYP85A2, leading to the formation of brassinolide. Alternatively, there is a suggested synthetic pathway that starts from cholesterol, giving rise to C27 brassinosteroids.
Mechanism of Action
Signal Transduction
Brassinosteroids, particularly the potent brassinolide, play a crucial role in controlling various plant processes such as germination, aging, and the ability to withstand environmental and biological stresses. Because of this, researchers from around the world have extensively studied model organisms like Catharanthus roseus and Arabidopsis since they were first isolated in 1979. These organisms have been thoroughly examined, from how they receive brassinolide signals to how these signals affect gene expression.In Arabidopsis, the process begins with the BRI1 receptor. This receptor is a type of protein called a leucine-rich receptor kinase and allows brassinolide to attach to it from outside the cell. This binding causes a change in the receptor's shape, and it then interacts with another protein called BRI1 associated receptor kinase 1. This interaction results in both proteins being chemically modified by the addition of phosphate groups in a process called phosphorylation. This, in turn, sets off a chain reaction within the cell, activating some proteins and inhibiting others, including various kinases, phosphatases, and transcription factors. Among the activated proteins are the BR signaling kinases. Their activation, in turn, activates the phosphatase BRI1 suppressor1, which removes a phosphate group from another protein called brassinosteroid insensitive 2. Removing this phosphate group inactivates BIN2, an important enzyme. As a result, protein phosphotase 2A can remove phosphate groups from two transcription factors, brassinazole-resistant-1 and BRI1-EMS-suppressor-1, allowing them to accumulate within the cell's nucleus. There, they control the expression of specific target genes, which are involved in various cellular processes. However, when there's no brassinolide around, a regulator called BRI1 kinase inhibitor prevents the BRI1 receptor from interacting with the BAK1 co-receptor. This prevents the activation of BIN2, causing BZR1 and BES1 to be chemically modified by adding phosphate groups. These modified transcription factors then interact with a protein called 14-3-3 and accumulate in the cell's cytoplasm. Eventually, they are broken down and degraded by a 26S proteasome. In this way, BIN2 kinase serves as an essential negative regulator, dampening the activity of the central transcription factors BES1 and BZR1.