05) Both Ugt1a6 and Sult1a1 mRNA expression was increased signif

05). Both Ugt1a6 and Sult1a1 mRNA expression was increased significantly in livers of male db/db mice as compared to C57BKS mice. Discussion The current study demonstrates that db/db mice, which are a widely used rodent model of diabetes with excessive weight gain and NAFLD, display profound alteration of transporter expression in both liver and kidney at the level of mRNA and protein expression. These observations are in agreement with [14] and [30]. Increased urine APAP-G

and –S levels were also observed, which consistent with enhanced APAP-G disposition observed in other rodent steatosis models [19]. Slco1a1 expression was markedly downregulated in livers and kidneys of db/db mice. As Slco1a1 mediates transport of wide variety of anionic, cationic, zwitterionic, MK-1775 cost as well as, neutral chemicals [31], a significant decrease in Slco1a1 expression in liver and kidney could cause marked changes

in pharmacokinetics and toxicity in the db/db mouse model. Along with Slco1a1, Slco1b2 protein expression was significantly decreased in livers of db/db female mice. In mice, selleck inhibitor Slco1a1, transports similar substrates as SLCO1A2, 1B1 and 1B3 in humans [32]. As Ppar-α has a central role in the down regulation of Slco1a1 in mouse liver [33, 34], and is upregulated in db/db liver, according to present study as well as previous findings [35], it is possible that the observed downregulation is via a Ppar-α mediated mechanism. Also, as Fxr has been observed to be decreased in NALFD [36], it is possible Fxr-dependent mechanisms regulate Slco expression. Fxr regulates mouse Slco1a1, 1a4 and 1a5 [37]. Pxr also regulates Slco1a4 expression in mice [38]. Similarly, human SLCO1B3 and 1A2 is regulated, in part, by FXR [39]. However, db/db mice did not demonstrate any significant differences in mRNA expression of Fxr and Pxr in liver, suggesting that in the observed Slco decrease in Db/Db mice may be due to Ppar-α activation, and not Pxr and Fxr alterations. These observed changes in Slco expression in db/db mice could be predicative of SLCO expression changes in livers

of diabetic humans. Further studies, which reveal nuclear receptor binding to specific response elements present in Slco promoters, will further elucidate how these transporters are regulated in leptin/leptin receptor deficient diabetes models. The regulation of renal pentoxifylline transporter expression in mouse models of diabetes and obesity remains limited. Data in this manuscript and Cheng et al. [14] indicate that a severe diabetes phenotype alters renal transporter expression. It is intriguing that kidney transporter expression was substantially altered in this model, but minimal changes in renal pathology were observed. In humans SLC22A6 and SLC22A7 are predominant transporters localized to the basolateral membrane of renal proximal tubule cells [40]. The SLCs transport certain antibiotics like benzylpenicillin, antivirals and NSAIDs (Non-steroidal anti-inflammatory drugs).

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