Cells receive information from their neighbors through a class of proteins known as
receptors. Receptors may bind with some molecules (
ligands) or may interact with physical agents like light, mechanical temperature, pressure, etc. Reception occurs when the target cell (any cell with a receptor protein specific to the signal molecule) detects a signal, usually in the form of a small, water-soluble molecule, via binding to a receptor protein on the cell surface, or once inside the cell, the signaling molecule can bind to
intracellular receptors, other elements, or stimulate
enzyme activity (e.g. gasses), as in intracrine signaling. Signaling molecules interact with a target cell as a ligand to
cell surface receptors, and/or by entering into the cell through its membrane or
endocytosis for intracrine signaling. This generally results in the activation of
second messengers, leading to various physiological effects. In many mammals, early
embryo cells exchange signals with cells of the
uterus. In the human
gastrointestinal tract,
bacteria exchange signals with each other and with human
epithelial and
immune system cells. For the yeast
Saccharomyces cerevisiae during
mating, some cells send a peptide signal (mating factor
pheromones) into their environment. The mating factor peptide may bind to a cell surface receptor on other yeast cells and induce them to prepare for mating.
Cell surface receptors Cell surface receptors play an essential role in the biological systems of single- and multi-cellular organisms and malfunction or damage to these proteins is associated with cancer, heart disease, and asthma. These
trans-membrane receptors are able to transmit information from outside the cell to the inside because they
change conformation when a specific ligand binds to it. There are three major types:
Ion channel linked receptors,
G protein–coupled receptors, and
enzyme-linked receptors.
Ion channel linked receptors bound to a glutamate antagonist showing the amino terminal, ligand binding, and transmembrane domain, Ion channel linked receptors are a group of
transmembrane ion-channel proteins which open to allow ions such as
Na+,
K+,
Ca2+, and/or
Cl− to pass through the membrane in response to the binding of a chemical messenger (i.e. a
ligand), such as a
neurotransmitter. When a
presynaptic neuron is excited, it releases a
neurotransmitter from vesicles into the
synaptic cleft. The neurotransmitter then binds to receptors located on the
postsynaptic neuron. If these receptors are
ligand-gated ion channels (LICs), a resulting conformational change opens the ion channels, which leads to a flow of ions across the cell membrane. This, in turn, results in either a
depolarization, for an excitatory receptor response, or a
hyperpolarization, for an inhibitory response. These receptor proteins are typically composed of at least two different domains: a transmembrane domain which includes the ion pore, and an extracellular domain which includes the ligand binding location (an
allosteric binding site). This modularity has enabled a 'divide and conquer' approach to finding the structure of the proteins (crystallising each domain separately). The function of such receptors located at
synapses is to convert the chemical signal of
presynaptically released neurotransmitter directly and very quickly into a
postsynaptic electrical signal. Many LICs are additionally modulated by
allosteric ligands, by
channel blockers,
ions, or the
membrane potential. LICs are classified into three superfamilies which lack evolutionary relationship:
cys-loop receptors,
ionotropic glutamate receptors and
ATP-gated channels.
G protein–coupled receptors within the
plasma membrane G protein-coupled receptors are a large group of
evolutionarily-related proteins that are
cell surface receptors that detect
molecules outside the
cell and activate cellular responses. Coupling with
G proteins, they are also called seven-transmembrane receptors because they pass through the
cell membrane seven times. The G-protein acts as a "middle man" transferring the signal from its activated receptor to its target and therefore indirectly regulates that target protein. Ligands can bind either to extracellular N-terminus and loops (e.g. glutamate receptors) or to the binding site within transmembrane helices (Rhodopsin-like family). They are all activated by
agonists although a spontaneous auto-activation of an empty receptor can also be observed. and animals. The
ligands that bind and activate these receptors include light-sensitive compounds,
odors,
pheromones,
hormones, and
neurotransmitters, and vary in size from small molecules to peptides to large
proteins. G protein-coupled receptors are involved in many diseases. There are two principal signal transduction pathways involving the G-protein coupled receptors:
cAMP signal pathway and
phosphatidylinositol signal pathway. When a ligand binds to the GPCR it causes a conformational change in the GPCR, which allows it to act as a
guanine nucleotide exchange factor (GEF). The GPCR can then activate an associated
G protein by exchanging the
GDP bound to the G protein for a
GTP. The G protein's α subunit, together with the bound GTP, can then dissociate from the β and γ subunits to further affect intracellular signaling proteins or target functional proteins directly depending on the α subunit type (
Gαs,
Gαi/o,
Gαq/11,
Gα12/13). G protein-coupled receptors are an important
drug target and approximately 34% of all Food and Drug Administration (FDA) approved drugs target 108 members of this family. The global sales volume for these drugs is estimated to be 180 billion US dollars . Hence a catalytic receptor is an
integral membrane protein possessing both
enzymatic,
catalytic, and
receptor functions. They have two important domains, an extra-cellular ligand binding domain and an intracellular domain, which has a catalytic function; and a single
transmembrane helix. The signaling molecule binds to the receptor on the outside of the cell and causes a conformational change on the catalytic function located on the receptor inside the cell. Examples of the enzymatic activity include: •
Receptor tyrosine kinase, as in
fibroblast growth factor receptor. Most enzyme-linked receptors are of this type. •
Receptor protein serine/threonine kinase, as in
bone morphogenetic protein •
Guanylate cyclase, as in
atrial natriuretic factor receptor Intracellular receptors Intracellular receptors exist freely in the cytoplasm, nucleus, or can be bound to
organelles or membranes. For example, the presence of
nuclear and mitochondrial receptors is well documented. The binding of a ligand to the intracellular receptor typically induces a response in the cell. Intracellular receptors often have a level of specificity, this allows the receptors to initiate certain responses when bound to a corresponding ligand. Intracellular receptors typically act on lipid soluble molecules. The receptors bind to a group of
DNA binding proteins. Upon binding, the receptor-ligand complex translocates to the nucleus where they can alter patterns of
gene expression.
Steroid hormone receptors are found in the
nucleus,
cytosol, and also on the
plasma membrane of target cells. They are generally
intracellular receptors (typically cytoplasmic or nuclear) and initiate
signal transduction for
steroid hormones which lead to changes in gene expression over a time period of hours to days. The best studied steroid hormone
receptors are members of the
nuclear receptor subfamily 3 (NR3) that include
receptors for estrogen (group NR3A) and 3-ketosteroids (group NR3C). In addition to nuclear receptors, several
G protein-coupled receptors and
ion channels act as
cell surface receptors for certain steroid hormones. == Mechanisms of Receptor Down-Regulation ==