Transporter Mediated Uptake of Montelukast

Asthma

Pharmacogenetics, Singulair, montelukast, Leukotriene Antagonists, Anti-Asthmatic Agents, Intestinal Absorption, pharmacokinetics, absorption, biochemical transport, Membrane Transport Proteins, Drug Interactions

Leukotriene receptor antagonists (LTRAs) are frequently prescribed to reduce the symptoms associated with asthma. Singulair, manufactured by Merck, is a popular LTRA, however its effectiveness varies greatly between individuals. We are interested in understanding why the effectiveness of Singulair varies so greatly. For an oral drug such as Singulair to be effective, the body must efficiently absorb it. We have found that blood levels of Singulair vary greatly between individuals, and we think that this variability is responsible for variability in response. Drug absorption occurs primarily in the intestine. Due to differences in the chemical properties of drugs, some drugs can be absorbed easily while other drugs require help from special proteins produced by the cells that line the intestine. These proteins, or transporters act like turnstiles to allow drugs to move from the intestine to the bloodstream and are known to be inhibited by components of citrus juice. The activity of a transporter can be influenced by individual genetic variability. We think that Singulair requires help from a transport protein to be absorbed and that genetic variability in this transporter leads to variability in the blood level of Singulair. In this proposal we will use citrus juice (grapefruit and orange) to inhibit intestinal membrane transport proteins and show that Singulair requires these transporters to be efficiently absorbed. Eventually, what we learn from this work will allow doctors to quickly test individuals with asthma to determine how well they will absorb Singulair and possibly other LTRAs. Knowing this will allow the doctor to adjust the drug treatment on an individual basis to maximize benefit in the treatment of asthma.

Montelukast (Merck brand name Singulair) is a selective Cys-LT1 receptor antagonist that is used to control asthma symptoms in children and adults. Although safe and effective, the inter-patient variability in response is substantial (25-60% response rate), which is due in part to genetic variability. For example, we recently reported that polymorphisms in candidate genes that encode proteins in the LT pathway influence responsiveness to the drug. The long-range goal of our studies is to determine the contribution of genetic variability to the inter-patient variability in montelukast blood levels and responsiveness. In preliminary studies, we found that the plasma concentration vs. time data in single and multiple dose-studies vary more than 10-fold, which could contribute to inter-patient variability in response. Montelukast is about 64% bioavailable, is cleared by CYP2C9 and CYP3A4 in the liver, and is nearly completely excreted into the bile. The physical properties of montelukast suggest that the drug undergoes transport by solute carrier transporters (SLC family transporters) and/or ATP-binding cassette transporters (ABC family transporters). Recent studies support the idea that genetic variation in genes encoding SLC and ABC transporters can influence the pharmacokinetics of drugs that are substrates for these transporters. In the present submission, we propose to determine if montelukast is a substrate for SLC and/or ABC transporters. To accomplish this we will coadminister Singulair with citrus juice which contains known inhibitors of membrane transport proteins. If transporters are involved in the absorption of montelukast, then citrus juice should decrease the absorption of montelukast relative to Gatorade. Our working hypothesis for this study is that montelukast is a substrate for SLC (OATP1B3, OATP1B1, OATP2B1, OATP1A2) and ABC (MRP1, MRP2, and MRP3, BCRP) transporters. If true, then the pharmacokinetics of montelukast will be determined by the genetics of the membrane transporters. This highly significant observation will have important implications for understanding the disposition of montelukast in patients, and ultimately will lead to individualization of montelukast therapy in asthma.

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