Vasoactive intestinal peptide, also known as vasoactive intestinal polypeptide or VIP, is a peptide hormone that is vasoactive in the intestine. VIP is a peptide of 28 amino acid residues that belongs to a glucagon/secretin superfamily, the ligand of class II G protein–coupled receptors.

VIP is produced in many tissues of vertebrates including the gut, pancreas, neocortex, and suprachiasmatic nuclei of the hypothalamus in the brain. VIP stimulates contractility in the heart, causes vasodilation, increases glycogenolysis, lowers arterial blood pressure and relaxes the smooth muscle of trachea, stomach and gallbladder. In humans, the vasoactive intestinal peptide is encoded by the VIP gene.

VIP has a half-life (t<sub>½</sub>) in the blood of about two minutes.

Function

In the digestive system

In the digestive system, VIP seems to induce smooth muscle relaxation (lower esophageal sphincter, stomach, gallbladder), stimulate secretion of water into pancreatic juice and bile, and cause inhibition of gastric acid secretion and absorption from the intestinal lumen. Its role in the intestine is to greatly stimulate secretion of water and electrolytes, as well as relaxation of enteric smooth muscle, dilating peripheral blood vessels, stimulating pancreatic bicarbonate secretion, and inhibiting gastrin-stimulated gastric acid secretion. These effects work together to increase motility. It also has the function of stimulating pepsinogen secretion by chief cells. VIP seems to be an important neuropeptide during inflammatory bowel diseases since the communication between mast cells and VIP in colitis, as in Crohn's disease, is upregulated.

In the heart

It is also found in the heart and has significant effects on the cardiovascular system. It causes coronary vasodilation Additionally, the growth-hormone-releasing hormone (GH-RH) is a member of the VIP family and stimulates growth hormone secretion in the anterior pituitary gland.

VIP is also expressed in a subtype of inhibitory interneuron in various regions of the brain.

In other areas of the body

VIP provokes vaginal lubrication, doubling the total volume of lubrication produced.

Mechanisms

VIP binds to both VPAC1 and VPAC2 receptors. When VIP binds to VPAC2 receptors, a G-alpha-mediated signaling cascade is triggered. In a number of systems, VIP binding activates adenyl cyclase activity leading to increases in cAMP concentration and PKA activity. The PKA then activates other intracellular signaling pathways like the phosphorylation of CREB and other transcriptional factors. The mPer1 and mPer2 promoters have CRE domains and thus provides the mechanism for VIP to regulate the molecular clock itself. Then it will activate gene expression pathways such as Per1 and Per2 in circadian rhythm.

In addition, GABA levels are connected to VIP in that they are co-released. Sparse GABAergic connections are thought to decrease synchronized firing.

VIP acts as a major synchronizing agent among SCN neurons and plays a role in synchronizing the SCN with light cues. The high concentration of VIP and VIP receptor containing neurons are primarily found in the ventrolateral aspect of the SCN, which is also located above the optic chiasm. The neurons in this area receive retinal information from the retinohypothalamic tract and then relay the environmental information to the SCN.

VIP and vasopressin are both important for neurons to relay information to different targets and affect neuroendocrine function. They transmit information through such relay nuclei as the SPZ (subparaventricular zone), DMH (dorsomedial hypothalamic nucleus), MPOA (medial preoptic area) and PVN (paraventricular nucleus of hypothalamus). Once secreted from the pituitary gland, prolactin can increase many behaviors such as parental care and aggression. In certain species of birds with a knockout VIP gene there was an observable decrease in overall aggression over nesting territory.

Pathology

VIP is overproduced in VIPoma.

See also

  • Hypothalamic–pituitary–prolactin axis
  • Vasoactive intestinal peptide receptor
  • VPAC1
  • VPAC2

References

Further reading

  • Pathway at biocarta.com