Sigma receptors ( σ-receptors) are protein receptors that bind such as 4-PPBP (4-phenyl-1-(4-phenylbutyl) piperidine),
The fungal protein ERG2, a C-8 sterol isomerase, falls into the same protein family as sigma-1. Both localize to the ER membrane, although sigma-1 is also reported to be a cell surface receptor. Sigma-2 is an EXPERA domain protein
Classification
Because the σ-receptor was originally discovered to be agonized by
benzomorphan Opioid and antagonized by
naltrexone, σ-receptors were originally believed to be a type of opioid receptor.
When the σ
1 receptor was isolated and cloned, it was found to have no structural similarity to the opioid receptors, but rather showed similarity to fungal proteins involved in sterol synthesis.
At this point, they were designated as a separate class of proteins.
Putative sigma-3 receptor
In the early 1990s, a "sigma-3" binding site was proposed based on phenylaminotetralin (PAT) ligands and functional assays that linked PAT binding to stimulation of tyrosine hydroxylase and dopamine synthesis in rodent brain.
Subsequent pharmacological and radioligand-binding studies demonstrated that these so-called sigma-3 sites correspond to histamine H1 receptors rather than a distinct sigma receptor subtype.
As a result, contemporary classifications recognize only sigma-1 and sigma-2 receptors.
Function
The function of these receptors is poorly understood.
Drugs known to be σ-agonists include
cocaine,
morphine/
diacetylmorphine,
opipramol,
Phencyclidine,
fluvoxamine,
methamphetamine,
dextromethorphan, and
berberine. However, the exact role of σ-receptors is difficult to establish as many σ-agonists also bind to other targets such as the κ-opioid receptor and the
NMDA receptor. In animal experiments, σ-antagonists such as
rimcazole were able to block convulsions from cocaine overdose. σ-antagonists are also under investigation for use as
antipsychotic medications. Early rodent studies reported that σ-receptor ligands can functionally antagonize opioid analgesia: (+)-pentazocine and 1,3-di(2-tolyl)guanidine reduced morphine analgesia in a haloperidol-reversible, D2-independent manner, consistent with a tonically active anti-opioid σ1 system.
The abundant neurosteroid steroid hormone DHEA is an agonist at sigma receptors and along with pregnenolone could be endogenous agonist ligands; opposed by sigma antagonistic activity from progesterone.
Physiologic effects
Physiologic effects when the σ-receptor is activated include
hypertonia,
tachycardia,
tachypnea,
antitussive effects, and
mydriasis. Some σ-receptor agonists—such as cocaine, a weak σ-agonist—exert convulsant effects in animals.
In 2007, selective σ-receptor agonists were shown to produce antidepressant-like effects in mice.
σ-receptors were also shown to have a role in the regulation of iron/heme homeostasis.
In mice, σ1 activation attenuated μ-, κ-, and δ-opioid analgesia without altering morphine's effects on gastrointestinal transit or lethality, while σ blockade with haloperidol enhanced analgesia and eliminated strain differences in κ-agonist sensitivity.
Ligands
Agonists
Antagonists
External links
