Cellular receptors are proteins either inside a cell or on its surface, which receive a signal. In normal physiology, this is a chemical signal where a protein-ligand binds a protein receptor. The ligand is a chemical messenger released by one cell to signal either itself or a different cell. The binding results in a cellular effect, which manifests as any number of changes in that cell, including altering gene transcription or translation or changing cell morphology. Typically, a single ligand will have a single receptor to which it can bind and cause a cellular response. There are several different types of cellular signaling, all of which depend on different ligands and cellular receptors. The major categories of cellular signaling include autocrine, signal across a gap junction, paracrine, and endocrine. Autocrine signaling is when a cell releases a signal that then binds one of its receptors to change its functioning. Signaling across gap junctions is when small signaling molecules move directly across neighboring cells that are attached. Paracrine signaling is communication between cells that are nearby. Endocrine signaling is when cell signals travel to target cell receptors in a different part of the body through the bloodstream. Each type of signaling requires a ligand and a receptor. Cellular receptors can broadly categorize into internal receptors, cell-surface receptors, ion channel receptors, G-protein-coupled receptors (GPCRs), and enzyme-linked receptors. While most cell receptor binding is by a chemical ligand, two notable exceptions are viruses which are pathogenic cells that can bind host cellular receptors to infect a cell and bacterial components that can bind receptors on immune cells to cause an immune response.

Types of Ligands: Ligands are the signaling molecule used by the body for various cells to communicate with other cells. The adrenal gland can release a hormone such as cortisol, which will communicate with a large variety of different cells of different organs to have a significant effect or one inhibitory neuron can release a neurotransmitter like GABA to exert a very direct effect on another cell. The effect of the ligand is dependent on both the ligand itself and the receptor it targets. For example, small and hydrophobic ligands such as steroids like cortisol often target internal receptors as they are capable of passing through the plasma membrane without help. On the other hand, large or hydrophilic ligands such as GABA are unable to pass through the cell membrane and must target cell surface receptors. 

Internal Receptors: These receptors are also known as either intracellular or cytoplasmic. They are found in the cytoplasm of a cell and are often targeted by hydrophobic ligands that can cross the lipid bilayer of the animal plasma cell membrane. Often these receptors act to modify mRNA synthesis and thus protein synthesis within the cell. They accomplish this by the ligand-receptor complex being able to travel to the nucleus and bind DNA at a gene regulatory site, something that the receptor and ligand on their own would be unable to do. Testosterone, estrogen, cortisol, and aldosterone are examples of steroid hormones that are hydrophobic and pass through the plasma membrane to target internal receptors. Internal receptors often work without needing second messengers to relay the signal before mRNA synthesis, and protein synthesis is affected, a process unique to internal receptors as other types work through a cellular cascade that results in alteration of protein synthesis.

Cell-Surface Receptors: These receptors are also known as transmembrane receptors. These are proteins that are found on the surface of cells and span the plasma membrane. They bind to ligands that can’t themselves pass through the plasma membrane. These are often hydrophilic ligands or ones too large to make it through. These receptors don’t bind DNA to modify gene transcription and translation themselves but rather perform signal transduction; an extracellular signal triggers an intracellular signal, which will usually go to the nucleus to affect cell functioning. Often a cell surface receptor will be specific for that cell type so that the ligand can only affect the functioning of its target cells. The components of a cell surface receptor can break down into an external ligand-binding domain, a hydrophobic region that spans the membrane, and an intracellular domain that is responsible for starting a second messenger cascade. Cell-surface receptors come in three main types: ion channel receptors, GPCRs, and enzyme-linked receptors.

Ion channel receptors: When a ligand binds an ion channel receptor, a channel through the plasma membrane opens that allows specific ions to pass through. This process requires a specialized membrane-spanning region of the receptor. Ligand binding creates a change in the shape of the receptor that allows specific ions to pass, usually sodium, magnesium, calcium, or hydrogen. Chemically-gated ion channels are on dendrites and cell bodies of neurons.

GPCRs: GPCRs are a subtype of cell surface receptors that act through a G-protein to start a second messenger cascade, which modulates cellular function. The receptor has the ligand-binding site on the outside of the plasma membrane and has a transmembrane portion which can bind to a G-protein in the intracellular space. A G-protein is a heterotrimeric protein with three subunits, alpha, beta, and gamma. The beta and gamma subunits are attached to the membrane by a lipid anchor.  When no ligand is bound to the receptor, the alpha subunit and a GDP is bound to the transmembrane receptor and the beta and gamma subunits. When the ligand binds the receptor, a conformational change activates the G protein, and a GTP molecule replaces the GDP molecule on the alpha subunit. The G-protein dissociates with the beta and gamma subunits remaining attached by their anchor, and the activated alpha subunit, now bound to a GTP molecule, is freed from the intracellular wall of the plasma membrane. Both the beta-gamma dimer and the alpha-GTP can act to propagate the signal cascade. Some common enzymes and second messengers activated by this cascade include adenylate cyclase, cyclic AMP, diacylglycerol, inositol 1, 4, 5-triphosphate, and phospholipase C. GPCRs can be both activating and inhibiting. GPCRs are involved in many functions of the multicellular organism, including but not limited to growth, endocrine signaling, sensation, and clotting.

Enzyme-Linked Receptors: This subtype of transmembrane receptors have a catalytic site on the cytoplasmic domain. Often, when the ligand binds these receptors, they dimerize, which activates the receptor’s catalytic site and results in the enzymatic activity. There are several types of enzyme-linked receptors; the most common type is the receptor tyrosine kinase. Other examples include receptor serine/threonine kinase, receptor guanylyl cyclase, and receptor tyrosine phosphatases. Receptor tyrosine and receptor serine and threonine kinases dimerize, which causes autophosphorylation to happen at the tyrosine, serine, or threonine sites, respectively. This phosphorylation is what activates the enzymatic activity of the receptor. Many growth signals, such as epidermal growth factor and platelet-derived growth factor, work with a receptor tyrosine kinase.

The process of a single cell becoming a complex multicellular organism requires careful regulation of cellular activities, including differentiation, migration, and proliferation. All of these actions must happen at the correct time and place. This high level of coordination requires extensive, coordinated, and fast-acting cellular communication. There are several key signaling pathways, identified in human and animal studies, required for proper development, including FGF, hedgehog, Wnt, TGF beta, and notch. One ligand can bind several different receptors on different cells to cause different downstream effects. For example, in the Wnt pathway, the ligand can bind multiple receptor complexes and trigger several downstream signaling cascades resulting in diverse cellular responses. This is one example of how cellular receptors can turn the same signal into several different effects. Through the complex interaction of ligand and receptor, at the correct time relative to other cellular processes, a single cell develops into a complex multicellular organism.

Every organ system in the body requires cellular communication and, thus, cellular receptors, including cell-cell interactions like macrophages activating plasma cells of the immune system and the acetylcholine release at the neuromuscular junction of the nervous system. This activity also includes body-wide interactions like the hypothalamic release of ACTH, causing the adrenal release of cortisol, which then affects almost every organ system. Ultimately, the ability of any organism to become multi-cellular relies on the ability to use cellular receptors for communication.