Platelet-activating factor, also known as PAF, PAF-acether or AGEPC (acetyl-glyceryl-ether-phosphorylcholine), is a potent phospholipid activator and mediator of many leukocyte functions, platelet aggregation and degranulation, inflammation, and anaphylaxis. It is also involved in changes to vascular permeability, the oxidative burst, chemotaxis of leukocytes, as well as augmentation of arachidonic acid metabolism in phagocytes.
PAF is produced by a variety of cells, but especially those involved in host defense, such as platelets, endothelial cells, neutrophils, monocytes, and macrophages. PAF is continuously produced by these cells but in low quantities and production is controlled by the activity of PAF acetylhydrolases. It is produced in larger quantities by inflammatory cells in response to specific stimuli.[1]
PAF was discovered by French immunologist Jacques Benveniste in the early 1970s.[2] [3] PAF was the first phospholipid known to have messenger functions. Benveniste made significant contributions in the role and characteristics of PAF and its importance in inflammatory response and mediation. Using lab rats and mice, he found that ionophore A23187 (a mobile ion carrier that allows the passage of Mn2+, Ca2+ and Mg2+ and has antibiotic properties against bacteria and fungi) caused the release of PAF. These developments led to the finding that macrophages produce PAF and that macrophages play an important function in aggregation of platelets and liberation of their inflammatory and vasoactive substances.
Further studies on PAF were conducted by Constantinos A. Demopoulos in 1979.[4] Demopoulos found that PAF plays a crucial role in heart disease and strokes. His experiment’s data found that atherosclerosis (the accumulation of lipid-rich lesions in the endothelium of the arteries) can be attributed to PAF and PAF-like lipids, and identified biologically active compounds in the polar lipid fractions of olive oil, honey, milk and yoghurt, mackerel, and wine that have PAF-antagonistic properties and inhibit the development of atherosclerosis in animal models.[5] During the course of his studies, he also determined the chemical structure of the compound.
PAF can be found in protozoans, yeasts, plants, bacteria, and mammals. PAF has regulatory role in protozoans. The regulatory role is thought to diverge from that point and be maintained as living organisms started to evolve. During evolution, functions of PAF in the cell have been changing and enlarging.
PAF has been found in plants but its function has not yet been determined.
PAF is used to transmit signals between neighboring cells and acts as a hormone, cytokines, and other signaling molecules. The PAF signaling system can trigger inflammatory and thrombotic cascades, amplify these cascades when acting with other mediators, and mediate molecular and cellular interactions (cross talk) between inflammation and thrombosis.[6] Unregulated PAF signaling can cause pathological inflammation and has been found to be a cause in sepsis, shock, and traumatic injury. PAF can be used as a local signaling molecule and travel over very short distances or it can be circulated throughout the body and act via endocrine.
PAF initiates an inflammatory response in allergic reactions.[7] This has been demonstrated in the skin of humans and in the paws and skin of lab rabbits and rodents. The inflammatory response is enhanced by the use of vasodilators, including prostaglandin E1 (PGE,) and PGE2 and inhibited by vasoconstrictors.[8]
PAF also induces apoptosis in a different way that is independent of the PAF receptor. The pathway to apoptosis can be inhibited by negative feedback from PAF acetylhydrolase (PAF-AH), an enzyme that catabolizes platelet-activating factor.
It is an important mediator of bronchoconstriction.
It causes platelets to aggregate and blood vessels to dilate. Thus, it is important to the process of hemostasis. At a concentration of 10−12 mol/L, PAF causes life-threatening inflammation of the airways to induce asthma like symptoms.
Toxins such as fragments of destroyed bacteria induce the synthesis of PAF, which causes a drop in blood pressure and reduced volume of blood pumped by the heart, which leads to shock and possibly death.
Several molecular species of platelet-activating factor that vary in the length of the O-alkyl side-chain have been identified.
Studies found that PAF could not be modified without losing its biological activity. Thus, small changes in the structure of PAF could render its signaling abilities inert.[9] Investigation led to the understanding that platelet and blood pressure response were dependent on the sn-2 propionyl analog. If the sn-1 was removed then PAF lacked any sort of biological activity. Finally, the sn-3 position of PAF was experimented with by removing methyl groups sequentially. As more and more methyl groups were removed, biological activity diminished until it was eventually inactive.
PAF is produced by stimulated basophils, monocytes, polymorphonuclear neutrophils, platelets, and endothelial cells primarily through lipid remodeling. A variety of stimuli can initiate the synthesis of PAF. These stimuli could be macrophages going through phagocytosis or endothelium cells uptake of thrombin.
There are two different pathways in which PAF can be synthesized: de novo pathway and remodeling. The remodeling pathway is activated by inflammatory agents and it is thought to be the primary source of PAF under pathological conditions. The de novo pathway is used to maintain PAF levels during normal cellular function.
The most common pathway taken to produce PAF is remodeling. The precursor to the remodeling pathway is a phospholipid, which is typically phosphatidylcholine (PC). The fatty acid is removed from the sn-2 position of the three-carbon backbone of the phospholipid by phospholipase A2 (PLA2) to produce the intermediate lyso-PC (LPC). An acetyl group is then added by LPC acetyltransferase (LPCAT) to produce PAF.
Using the de novo pathway, PAF is produced from 1-O-alkyl-2-acetyl-sn-glycerol (AAG). Fatty acids are joined on the sn-1 position with 1-O-hexadecyl being the best for PAF activity. Phosphocholine is then added to the sn-3 site on AAG creating PAF.
The concentration of PAF is controlled by the synthesis of the compound and by the actions of PAF acetylhydrolases (PAF-AH). PAF-AH are a family of enzymes that have the ability to catabolize and degrade PAF and turn it into an inactive compound. The enzymes within this family are lipoprotein-associated phospholipase A2, cytoplasmic platelet-activating factor acetylhydrolase 2, and platelet-activating factor acetylhydrolase 1b.
Cations are one form of regulation in the production of PAF. Calcium plays a large role in the inhibition of enzymes that produce PAF in the denovo pathway of PAF biosynthesis.
The regulation of PAF is still not completely understood. Enzymes that are associated with the production of PAF are controlled by metal ions, thiol compounds, fatty acids, pH, compartmentalization, and phosphorylation and dephosphorylation. These controls on these PAF producing enzymes are believed to work in conjunction to control it, but the overall pathway and reasoning is not well understood.
PAF antagonists do not provoke an inflammatory response upon binding, but block or lessen the effect of PAF. Examples of PAF antagonists are:[10]
High PAF levels are associated with a variety of medical conditions. Some of these conditions include:
•Allergic reactions
•Stroke
•Sepsis
•Myocardial infarction
•Colitis, inflammation of the large intestine
•Multiple sclerosis
While the effects that PAF has on inflammatory response and cardiovascular conditions are well understood, PAF is still a subject for discussion. Over the past 23 years, papers written on PAF have almost doubled from approximately 7,500 in 1997 to 14,500 in 2020.Web site: Platelet-activating factor search results and historical activity metrics . PubMed . June 2020 . PubMed. Research into PAF is ongoing.