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nanoparticles are being explored for targeted delivery via OCTN2 for other cancer drugs like paclitaxel.

      2.9.2 Regulation

      Transcriptional regulation of OCTN2 is mediated in part by the peroxisome proliferator‐activated receptor α (PPARα). PPARα plays an important role in the regulation of genes involved in lipid metabolism and energy homeostasis and is highly expressed in tissues that use fatty acid oxidation as a primary energy source, including heart muscle, skeletal muscle, and kidney [82]. Notably, OCTN2 is expressed highly in these tissues as well. Tentative PPAR response elements (PPREs) are found in the promoter and intronic regions of SLC22A5 in several species. In rats, treatment with the PPARα agonist clofibrate leads to increased transcription of OCTN2 in the liver and small intestine, but not the kidney or muscle tissue. Aligned with the upregulation of OCTN2 in rat liver, hepatic concentrations of carnitine are also increased by PPARα activation. These findings are supported by the downregulation of OCTN2 and overall reduction in systemic carnitine levels in PPARα‐null mice. Upregulation of OCTN2 by PPARα has also been demonstrated in pigs. In addition to fibrates, PPARα‐mediated regulation of OCTN2 is affected by cisplatin. Cisplatin is hypothesized to inhibit DNA binding to the PPARα/RXR complex, resulting in an overall downregulation of OCTN2 and an increase in urinary carnitine wasting in mice [91]. The PPARγ/RXRα complex also modulates OCTN2 expression in the large intestine. Human colonocytes and mouse colon exhibit altered expression of OCTN2 in response to PPARγ, but not PPARα [92]. In a mouse model of IBD, proinflammatory cytokines interact with the PPARγ/RXRα complex to reduce OCTN2 expression, contributing to disease pathology. Treatment with the PPARγ agonist luteolin to rescue OCTN2 expression results in the reduction of colonic inflammation [93].

      OCTN2 is upregulated by the estrogen receptor (ER) in breast cancer cells and tumor tissue, an effect attributed to the identification of a novel estrogen‐responsive element (ERE) in an intronic region of SLC22A5 [2].

      OCTN2 is further regulated by PDZ domain‐containing proteins [83]. PDZK1 colocalizes with OCTN2 at the apical membrane of renal tubule cells. PDZK1 stimulates carnitine uptake via OCTN2 by increasing the V max of the transporter, although cell‐surface expression of OCTN2 is unchanged suggesting PDZK1 stimulates translocation of carnitine. The four terminal amino acids at the carboxyl end of OCTN2 serve as a PDZ binding motif, and deletion or substitution of these residues eliminates PDZK1 stimulation of OCTN2. PDZK2 also increases the transport capacity of OCTN2, but through a different mechanism, increasing localization of OCTN2 to the plasma membrane [83].

      Lastly, OCTN2 expression is regulated by heat shock transcription factor 1 (HSF1) [2]. The promoter variant −207G>C disrupts a consensus sequence for an HSF binding element. Cells with the −207G wild‐type promoter containing the intact HSF1 binding site have higher expression of OCTN2 after heat‐shock compared to cells with the −207C variant, which results in disrupted HSF1 binding.

      2.9.3 Animal Models

      Octn2 −/− knockout mice have been characterized as a model of carnitine deficiency, resulting from a point mutation that causes a change from the amino acid leucine to arginine at residue 352. This substitution causes complete OCTN2 loss‐of‐function in vitro and in vivo. The mice, deemed juvenile visceral steatosis (jvs) mice, present with growth retardation and enlarged abdomen due to hepatic steatosis, as well as hyperammonia and hypoglycemia [94]. Pharmacokinetics in jvs mice reveal drastically altered carnitine parameters, including reduced bioavailability, decreased volume of distribution, decreased tissue‐to‐plasma concentration ratios, and increased clearance of carnitine compared with wild‐type mice [95]. Furthermore, jvs mice display spontaneous intestinal apoptotic phenotypes including ulceration and gut perforation, and an immune response involving macrophage and lymphocyte infiltration [96]. Inflammation and intestinal apoptosis are reduced when mice are treated with carnitine supplementation.

      2.9.4 Human Genetic Studies

      Biallelic loss‐of‐function mutations in OCTN2 result in a Mendelian disease known as carnitine transporter deficiency (CTD, also referred to as primary carnitine deficiency, systemic carnitine deficiency, or carnitine uptake defect; OMIM #212140) [67]. Almost 200 OCTN2 mutations have been identified among patients, the majority of which are missense, followed in frequency by nonsense, frameshift, and noncoding mutations that affect splice sites or regulatory regions [88]. Systemically, patients display extremely low plasma carnitine levels caused by reduced dietary carnitine absorption and excessive carnitine wasting in the urine due to loss of reabsorption by OCTN2 [97]. The disorder varies in time to onset and disease severity and/or presentation, with common symptoms including cardiomyopathy, cardiac arrhythmias, hepatic encephalopathy, and hypoglycemia. Missed diagnosis can be fatal in infants, thus many developed countries screen infants for CTD, among other disorders, at birth. Diagnosis in individuals with less severe disease can be delayed well into adulthood, exemplified by the identification of maternal carnitine deficiency from low carnitine levels in the newborn during screening. CTD is treated with supplemental carnitine at high doses, up to 200 mg/kg multiple times per day, with decent outcomes. Lack of adherence to treatment has resulted in sudden death in at least one report. Incidence of CTD varies globally, affecting 1:120,000 individuals in Australia, 1:75,000 in the United States, 1:40,000 in Japan, 1:27,000 in China, and up to 1:300 individuals in the Faroe Islands [97]. In at least one case, CTD has manifested as intellectual disability and autism spectrum disorder [98].

      Extensive functional genomic studies have been conducted for OCTN2. The common promoter variant −207G>C is well characterized, known to decrease transcription of OCTN2 due to disruption of HSF1 transcription factor binding. Another variant in the 5′‐UTR of the gene (−149G>A) creates an early ATG translation start site, reducing the translation of wild‐type OCTN2 and decreasing carnitine transport [99]. This variant has been found repeatedly in CTD patients for whom no or only one known deleterious variant is detected. Many studies have functionally characterized OCTN2 variants associated with CTD. Loss‐of‐function results from multiple mechanisms, including altered kinetic parameters decreasing carnitine affinity or capacity for transport, decreased affinity for sodium, and reduced plasma membrane localization.

      In GWAS, genetic polymorphisms in the OCTN2 locus have strong associations with blood metabolite levels (carnitine, acetylcarnitine, LDL cholesterol, and fatty acids), fat‐free mass, and autoimmune disease (e.g., Crohn’s disease). Forming a haplotype with OCTN1 at the IBD5 locus, OCTN2 is associated with Type 1 diabetes and Crohn’s disease [2]. See Section 2.8.4 for details.

      2.10.1 Introduction

      SLC22A15 was identified in 2002 through phylogenetic analyses and the use of basic alignment for peptides at a protein sequence similarity threshold of 35–40% [77]. This gene is homologous to the drosophila transporter, Orct, and was dubbed “Fly‐like putative transporter” (FLIPT1). To date, SLC22A15 has only been studied in vitro and no mouse models exist.

      2.10.2 Substrate and Inhibitor Selectivity

      Efforts to de‐orphan SLC22A15 have elucidated its function as a transporter. SLC22A15 preferentially transports the zwitterions ergothioneine and carnosine, two potent antioxidants found in the brain and other tissues [79]. Compared with the other zwitterion transporters in the SLC22A family, SLC22A15 exhibits a higher K m (lower affinity) for its substrates, including ergothioneine, carnosine, and creatine. The trend also holds for carnitine, which is transported by SLC22A15 with a much higher K m (99 μM) compared with other OCTN subclade family members. This transporter shows a weak interaction with organic cations TEA, MPP+, and cimetidine. SLC22A15 is therefore thought to be a determinant of its substrate levels at high substrate concentrations and may be co‐expressed with other SLC transporters that have higher affinity for the same substrates.

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