Protease-activated receptor explained

coagulation factor II thrombin receptor
Hgncid:3537
Symbol:F2R
Altsymbols:TR; HTR; CF2R; PAR1; PAR-1
Entrezgene:2149
Omim:187930
Refseq:NM_001992
Uniprot:P25116
Pdb:3BEF
Chromosome:5
Arm:q
Band:13.3
F2R like trypsin receptor 1
Hgncid:3538
Symbol:F2RL1
Altsymbols:PAR2, GPR11
Entrezgene:2150
Omim:600933
Refseq:NM_005242
Uniprot:P55085
Pdb:5NDD
Chromosome:5
Arm:q
Band:13.3
coagulation factor II thrombin receptor like 2
Hgncid:3539
Symbol:F2RL2
Altsymbols:PAR3; PAR-3
Entrezgene:2151
Omim:601919
Refseq:NM_004101
Uniprot:O00254
Pdb:2PUX
Chromosome:5
Arm:q
Band:13.3
F2R like thrombin or trypsin receptor 3
Hgncid:3540
Symbol:F2RL3
Altsymbols:PAR4
Entrezgene:9002
Omim:602779
Refseq:NM_003950
Uniprot:Q96RI0
Pdb:2PV9
Chromosome:19
Arm:p
Band:13.11

Protease-activated receptors (PAR) are a subfamily of related G protein-coupled receptors that are activated by cleavage of part of their extracellular domain. They are highly expressed in platelets, and also on endothelial cells, fibroblasts, immune cells, myocytes, neurons, and tissues that line the gastrointestinal tract.[1]

Protease-activated receptors, or PARs, are not to be mistaken with PAR proteins, a group of regulators of cellular polarity[2] named after their associated partitioning phenotype.[3]

Classification

There are four mammalian members of the protease-activated receptor (PAR) family: PAR1 – encoded by the gene F2R, PAR2F2RL1, PAR3F2RL2 and PAR4 – F2RL3, each of these genes has its locus on chromosome 5 except that of PAR4, which is on chromosome 19. The protease specificities, expression patterns, and functions of each PAR vary across a range of tissues and cell types. They are also members of the seven-transmembrane G-protein-coupled receptor superfamily, and are expressed throughout the body.[4]

History

When scientists were researching the process of blood clotting in the late 1980s, they made the discovery of protease-activated receptors (PARs). A novel protein that was activated by thrombin, a crucial part of the clotting cascade, was discovered by a research team at the University of California, San Francisco in 1991. The team was directed by Shaun Coughlin. This protein, which was eventually given the designation protease-activated receptor 1 (PAR1), was the first to be recognized as a member of the PAR family.

A second thrombin-activated protein, later known as PAR3, was identified in 1994. Later research revealed that PAR3 works as a cofactor for PAR4 but lacks a useful intracellular domain. A third member of the PAR family, known as PAR2, was discovered as a protein triggered by in 1996.

Activation

Protease activated receptors are integral membrane proteins that are coupled to G-proteins and are activated by proteolytic cleavage of the amino terminal sequence that exposes a new N-terminal sequence functions as a tethered ligand, which bind a conserved region on extracellular loop 2 (ECL2). Such binding causes activation of intracellular pathways and the specific change in conformation of the PAR. The most effective activator of PAR4 is thrombin. However, trypsin and factor Xa activate PAR4 by cleaving the receptor at various places in its N-terminal domain. Four types of PAR receptors have been identified by molecular cloning, and classified according to the main enzyme that is able to activate it. It has been determined that a large group of proteases cleave and activate PARs receptors, including various endogenous proteases from: a) the coagulation cascade, b) inflammatory cells, and c) the digestive tract. On the other hand, PARs can be specifically cleaved and irreversibly activated even by exogenous proteases originated from insects, bacteria or plants and fungi. The wide distribution of PARs in a variety of cells supports the idea that they are involved in many process related with the gastrointestinal physiology and cardiovascular physiology.[5] Although the proteolysis is the main mechanism for PAR activation, it is well known that a synthetic peptide (SLIGKV) that mimics the new N-terminal sequence produced after the cleavage, activates PAR-2 receptors without its proteolytic processing. In this sense, here we report that TFF3 isolated from human breast milk activates PAR-2 receptors of intestinal epithelial cells HT-29. These findings suggest that TFF3 activates intestinal epithelial cells through G-protein-coupled PAR-2, and could actively participate in the immune system of breastfed babies inducing the production of peptides related to innate defense, such as defensins and cytokines.

PARs are activated by the action of serine proteases such as thrombin (acts on PARs 1, 3 and 4) and trypsin (PAR 2).[6] These enzymes cleave the N-terminus of the receptor, which in turn acts as a tethered ligand. In the cleaved state, part of the receptor itself acts as the agonist, causing a physiological response.

Most of the PAR family act through the actions of G-proteins i (cAMP inhibitory), 12/13 (Rho and Ras activation) and q (calcium signalling) to cause cellular actions.

Function

PARs play a role in a multitude of physiological processes such as hemostasis, thrombosis, inflammation, and pain sensation. The cellular effects of thrombin are mediated by protease-activated receptors (PARs). Endothelial PARs participate in the regulation of vascular tone and permeability while in vascular smooth muscle they mediate contraction, proliferation, and hypertrophy. In endothelial cells PARs play a key role in promotion vascular barrier function as they provide a positive signals for endothelial adhesion molecules (vascular cell adhesion molecule-1 or VCAM-1, intercellular adhesion molecule-1 or ICAM-1, and E-selectin).[7] PARs contribute to the pro-inflammatory response. For example PAR4 induces leukocyte migration and PAR2 helps macrophages to produce cytokines such as interleukin-8 (IL-8). Recent research has also implicated these novel receptors in muscle growth and bone cell differentiation and proliferation.

See also

Further reading

External links

Notes and References

  1. Macfarlane SR, Seatter MJ, Kanke T, Hunter GD, Plevin R . Proteinase-activated receptors . Pharmacological Reviews . 53 . 2 . 245–282 . June 2001 . 11356985 . abstract .
  2. Munro EM . PAR proteins and the cytoskeleton: a marriage of equals . Current Opinion in Cell Biology . 18 . 1 . 86–94 . February 2006 . 16364625 . 10.1016/j.ceb.2005.12.007 .
  3. Goldstein B, Macara IG . The PAR proteins: fundamental players in animal cell polarization . Developmental Cell . 13 . 5 . 609–622 . November 2007 . 17981131 . 2964935 . 10.1016/j.devcel.2007.10.007 .
  4. Heuberger DM, Schuepbach RA . Protease-activated receptors (PARs): mechanisms of action and potential therapeutic modulators in PAR-driven inflammatory diseases . Thrombosis Journal . 17 . 1 . 4 . December 2019 . 30976204 . 6440139 . 10.1186/s12959-019-0194-8 . free .
  5. Barrera GJ, Tortolero GS . Trefoil factor 3 (TFF3) from human breast milk activates PAR-2 receptors, of the intestinal epithelial cells HT-29, regulating cytokines and defensins . Bratislavske Lekarske Listy . 117 . 6 . 332–339 . 2016 . 27546365 . 10.4149/bll_2016_066 . free .
  6. Pawar NR, Buzza MS, Antalis TM . Membrane-Anchored Serine Proteases and Protease-Activated Receptor-2-Mediated Signaling: Co-Conspirators in Cancer Progression . Cancer Research . 79 . 2 . 301–310 . January 2019 . 30610085 . 6335149 . 10.1158/0008-5472.CAN-18-1745 .
  7. Bae JS, Rezaie AR . Thrombin inhibits nuclear factor kappaB and RhoA pathways in cytokine-stimulated vascular endothelial cells when EPCR is occupied by protein C . Thrombosis and Haemostasis . 101 . 3 . 513–520 . March 2009 . 19277413 . 2688729 . 10.1160/th08-09-0568 .