Role of receptors in the Endocannabinoid system
Reprint from What is CBD
The endocannabinoid system is known to contribute several homeostatic functions for the human body. But, there are dozens of receptors, some which have probably not even been discovered. So, how do cannabinoid receptors work?
What is the Endocannabinoid System(ECS)
A system of physiology that aids the body in maintaining homeostasis from the time that humans are born. Present in every person. Promoting general well being. The endocannabinoid system can help with neurological shortcomings, musculoskeletal problems, inflammatory and immune issues. The human body produces its own cannabinoids, such as 2-Arachidonoyl(2-AG) and Anandamide(AEA), and when they are produced within the body they are termed endocannabinoids.
The endocannabinoid system uses retrograde signaling to send endocannabinoids from the postsynaptic neuron( the neuron receiving a signal) to the presynaptic neuron(the one that sent the signal). To illustrate, let’s say a presynaptic neuron in the brain is secreting glutamate to a postsynaptic neuron. The glutamate will bind to the receptors in the postsynaptic neuron and cause calcium gated ion channels to open. The result is that calcium will begin to accumulate inside the neuron that received the signal, the postsynaptic neuron. This is normal during times of high activity. Now, because of the accumulation of substantial calcium in the postsynaptic neuron, endocannabinoids will be synthesized from lipids in the membrane of the postsynaptic neuron, they will be secreted, and then they will bind to the G Protein coupled receptors of the presynaptic neuron. The result follows.
How do the receptors of the ECS work
The receptors are of the endocannabinoid system that are most highly regarded are the CB1 and CB2 receptors. The CB1 receptor is primarily localized in the brain (i.e. Hippocampus, Cerebrum, Cerebellum). The CB2 receptor is primarily localized in the peripheral aspect of the body (i.e. GI tract, tonsils, spleen, immune cells). Now, both the CB1 & CB2 receptors are classified as G-Protein coupled receptors. They are receptors which have seven helices, seven protein columns that crosses the cellular membrane seven times like a snake. These receptors have three subunits, called the alpha, beta, and gamma subunits.
G-Protein coupled receptors are capable of binding all kinds of molecules such as light reactive ones, hormones, pheromones. G- Protein coupled receptors are capable of regulating a substantial array of mechanisms in the body such as taste, growth, and vision.
The body has an immense quantity of G-Protein Coupled Receptors, all of which bind different ligands. Those that bind exogenous or endogenous cannabinoids are called CB1 & CB2 receptors. The way that CB1 & CB2 receptors work is that once an endocannabinoid binds to the active site of the receptor, GDP is exchanged for it’s energetic superior, Guanosine Triphosphate. Making it unstable to hold. As a result, the alpha subunit, paired with the GTP, and the beta-gamma dimer no longer bound to the alpha subunit are both available to move laterally into the cell. Now, the subunits of the G-Protein will dissociate from the complex and embark on a journey within the cell to relay that specific signal. However, when this GTP is hydrolyzed back to GDP, the subunits once again assume the form of an inactive heterotrimer, and associate with the entire inactive GPCR. In this way, G proteins work like a switch — turned on or off by signal-receptor interactions on the cell’s surface.
What problems have occurred due to deficiency receptors
If there was a deficiency in the binding of the receptors on a G-Protein Coupled receptor such as in CB1 and CB2 there could be serious problems. The endocannabinoid system being responsible for retrograde inhibition of overactive neurons, immunoinflammatory regulation, and neurological problems, to name a few, would have serious issues if receptors were deficient in the body of a human. If endocannabinoids could not bind to the CB1 or CB2 receptors located on the presynaptic neuron then this means that a neuron could not be relaxed. A T-Lymphocyte that cannot be stopped from synthesizing chemokines that produce inflammation in an area of the body could end up producing severe inflammation that could damage organs. GPCR that have deficient receptors will simply not work to transduce signals within the cells, and in the case of CB1 and CB2 receptors, cause the body to have a much more difficult time in promoting balance and health.