Ciclosporin
Ciclosporin, also spelled cyclosporine and cyclosporin, is a calcineurin inhibitor, used as an immunosuppressant medication. It is taken orally or intravenously for rheumatoid arthritis, psoriasis, Crohn's disease, nephrotic syndrome, eczema, and in organ transplants to prevent rejection. It is also used as eye drops for keratoconjunctivitis sicca.
Common side effects include high blood pressure, headache, kidney problems, increased hair growth, and vomiting. Other severe side effects include an increased risk of infection, liver problems, and an increased risk of lymphoma. Blood levels of the medication should be checked to decrease the risk of side effects. Use during pregnancy may result in preterm birth; however, ciclosporin does not appear to cause birth defects.
Ciclosporin is believed to work by decreasing the function of lymphocytes. It does this by forming a complex with cyclophilin to block the phosphatase activity of calcineurin, which in turn decreases the production of inflammatory cytokines by T-lymphocytes.
Ciclosporin was isolated in 1971 from the fungus Tolypocladium inflatum and came into medical use in 1983. It is on the World Health Organization's List of Essential Medicines. In 2023, it was the 179th most commonly prescribed medication in the United States, with more than 2million prescriptions. It is available as a generic medication.
Medical uses
Ciclosporin is indicated to treat and prevent graft-versus-host disease in bone marrow transplantation and to prevent rejection of kidney, heart, and liver transplants. It is also approved in the US for treating of rheumatoid arthritis and psoriasis, persistent nummular keratitis following adenoviral keratoconjunctivitis, and as eye drops for treating dry eyes caused by Sjögren's syndrome and meibomian gland dysfunction.In addition to these indications, ciclosporin is also used in severe atopic dermatitis, It has been used in severe rheumatoid arthritis and related diseases.
Ciclosporin has also been used in people with acute severe ulcerative colitis and hives that do not respond to treatment with steroids.
Side effects
Side effects of ciclosporin can include gum enlargement, increased hair growth, convulsions, peptic ulcers, pancreatitis, fever, vomiting, diarrhea, confusion, increased cholesterol, trouble breathing, numbness and tingling, itchiness, high blood pressure, potassium retention, kidney and liver dysfunction, burning sensations at finger tips, and an increased vulnerability to opportunistic fungal and viral infections. Ciclosporin causes hypertension by inducing vasoconstriction in the kidneys and increasing sodium reabsorption. The increase in blood pressure can cause cardiovascular events; it is thus recommended that the lowest effective dose for people requiring long-term treatment be used.Ciclosporin use after a kidney transplantation is associated with increased levels of uric acid in the blood and, in some cases, gout.
Ciclosporin is listed as an IARC Group 1 carcinogen, specifically leading to squamous cell skin cancer and non-Hodgkin lymphoma.
Pharmacology
Mechanism of action
Ciclosporin's main effect is to lower the activity of T-cells; it does so by inhibiting calcineurin in the calcineurin–phosphatase pathway and preventing the mitochondrial permeability transition pore from opening. Ciclosporin binds to the cytosolic protein cyclophilin of lymphocytes, especially of T cells. This cyclosporin—cyclophilin complex inhibits calcineurin, which is normally responsible for activating the transcription of interleukin 2. In T-cells, activation of the T-cell receptor normally increases intracellular calcium, which acts via calmodulin to activate calcineurin. Calcineurin then dephosphorylates the transcription factor NF-AT, which moves to the T-cell nucleus and increases the transcription of genes for IL-2 and related cytokines. Ciclosporin, by preventing the dephosphorylation of NF-AT, leads to reduced effector T-cell function; it does not affect cytostatic activity.Ciclosporin also binds to the cyclophilin D protein that constitutes part of the mitochondrial permeability transition pore, thus preventing MPTP opening. The MPTP is found in the mitochondrial membrane of cardiac muscle cells. MPTP opening signifies a sudden change in the inner mitochondrial membrane permeability, allowing protons and other ions and solutes of a size up to ~1.5 kDa to go through the inner membrane. This change of permeability is considered a cellular catastrophe, leading to cell death. However, brief mitochondrial permeability transition pore openings play an essential physiological role in maintaining healthy mitochondrial homeostasis.
Ciclosporin can induce a remission of proteinuria caused by such diseases as MCD and FSGS. Ciclosporin blocks the calcineurin-mediated dephosphorylation of synaptopodin, a regulator of Rho GTPases in podocytes, thereby preserving the phosphorylation-dependent synaptopodin-14-3-3 beta interaction. Preservation of this interaction, in turn, protects synaptopodin from cathepsin L-mediated degradation. Altogether, the antiproteinuric effect of Ciclosporin results, at least in part, from the maintenance of synaptopodin protein abundance in podocytes, which, in turn, is sufficient to maintain the integrity of the glomerular filtration barrier and to safeguard against proteinuria.
Pharmacokinetics
Ciclosporin is a cyclic peptide of 11 amino acids with notable molecular weight —achieves oral bioavailability up to ~30% due to its N-methylated cyclic structure, which confers both metabolic stability and a pronounced chameleonic properties. It contains a single D-amino acid, which is rarely encountered in nature. Unlike most peptides, ciclosporin is not synthesized by ribosomes.Ciclosporin is highly metabolized by the CYP3A4 enzyme in humans and animals after ingestion. The metabolites, which include cyclosporin B, C, D, E, H, and L, have less than 10% of ciclosporin's immunosuppressant activity and are associated with higher kidney toxicity.
Biosynthesis
Cyclosporin is synthesized by a nonribosomal peptide synthetase, cyclosporin synthetase. The enzyme contains an adenylation domain, a thiolation domain, a condensation domain, and an N-methyltransferase domain. The adenylation domain is responsible for substrate recognition and activation, whereas the thiolation domain covalently binds the adenylated amino acids to phosphopantetheine, and the condensation domain elongates the peptide chain. Cyclosporin synthetase substrates include L-valine, L-leucine, L-alanine, glycine, 2-aminobutyric acid, 4-methylthreonine, and D-alanine, which is the starting amino acid in the biosynthetic process. With the adenylation domain, cyclosporin synthetase generates the acyl-adenylated amino acids, then covalently binds the amino acid to phosphopantetheine through a thioester linkage. Some of the amino acid substrates become N-methylated by S-adenosyl methionine. The cyclization step releases cyclosporin from the enzyme. Amino acids such as D-Ala and butenyl-methyl-L-threonine indicate cyclosporin synthetase requires the action of other enzymes. The racemization of L-Ala to D-Ala by alanine racemase is pyridoxal phosphate-dependent. The formation of butenyl-methyl-L-threonine is performed by a Bmt polyketide synthase that uses acetate/malonate as its starting material.Gene cluster
Tolypocladium inflatum, the species currently used for mass production of Cyclosporin, has the biosynthetic genes arranged into a 12-gene cluster. Of these 12 genes, SimA is the cyclosporin synthetase, SimB is the alanine racemase, and SimG is the polyketide synthase. These genes are associated with an active retrotransposon. Although these sequences are poorly-annotated on GenBank and other databases, 90% similar sequences can be found for the Cyclosporin-producing Beauveria felina. SimB has two paralogs in the same organism with different but overlapping functions thanks to their low specificity.History
In 1970, new strains of fungi were isolated from soil samples taken from Norway and from Wisconsin in the US by employees of Sandoz in Basel, Switzerland. Both strains produced a family of natural products called cyclosporins. Two related components that had antifungal activity were isolated from extracts from these fungi. The Norwegian strain, Tolypocladium inflatum Gams, was later used for the large scale fermentation of ciclosporin.The immunosuppressive effect of the natural product ciclosporin was discovered on 31 January 1972 in a screening test on immune suppression designed and implemented by Hartmann F. Stähelin at Sandoz. The chemical structure of cyclosporin was determined in 1976, also at Sandoz. The success of the drug candidate ciclosporin in preventing organ rejection was shown in kidney transplants by R.Y. Calne and colleagues at the University of Cambridge, and in liver transplants performed by Thomas Starzl at the Children's Hospital of Pittsburgh. The first patient, on 9 March 1980, was a 28-year-old woman. In the United States, the Food and Drug Administration approved ciclosporin for clinical use in 1983.
Thomas Starzl's 1992 memoir explains through the eyes of a transplant surgeon that ciclosporin was an epoch-making drug for solid organ allotransplantation. It greatly expanded the clinical applicability of such transplantation by substantially advancing the antirejection pharmacotherapy component. Put simply, the biggest limits of applying such transplantation more widely were not cost or surgical skill but rather the problem of allograft rejection and the scarcity of donor organs. Ciclosporin was a major advancement against the rejection part of the challenge.