Abstract
High blood urate levels (hyperuricemia) have been found to be a significant risk factor for cardiovascular diseases and inflammatory arthritis, such as hypertension and gout. Human glucose transporter 9 (hSLC2A9) is an essential protein that mainly regulates urate/hexose homeostasis in human kidney and liver. hSLC2A9 is a high affinity-low capacity hexose transporter and a high capacity urate transporter. Our previous studies identified a single hydrophobic residue in trans-membrane domain 7 of class II glucose transporters as a determinant of fructose transport. A mutation of isoleucine 335 to valine (I355V) in hSLC2A9 can reduce fructose transport while not affecting glucose fluxes. This current study demonstrates that the I335V mutant transports urate similarly to the wild type hSLC2A9; however, Ile-335 is necessary for urate/fructose trans-acceleration exchange to occur. Furthermore, Trp-110 is a critical site for urate transport. Two structural models of the class II glucose transporters, hSLC2A9 and hSLC2A5, based on the crystal structure of hSLC2A1 (GLUT1), reveal that Ile-335 (or the homologous Ile-296 in hSLC2A5) is a key component for protein conformational changes when the protein translocates substrates. The hSLC2A9 model also predicted that Trp-110 is a crucial site that could directly interact with urate during transport. Together, these studies confirm that hSLC2A9 transports both urate and fructose, but it interacts with them in different ways. Therefore, this study advances our understanding of how hSLC2A9 mediates urate and fructose transport, providing further information for developing pharmacological agents to treat hyperuricemia and related diseases, such as gout, hypertension, and diabetes.
Highlights
A hydrophobic residue in TM7 of the hSLC2A9 was found to affect hexose transport
We found that the mutation isoleucine 335 to valine (I335V) has urate transport kinetics similar to the wild type (WT) protein, whereas W110A has a lower capacity and higher affinity for urate transport compared with WT hSLC2A9
Flux Studies—After determining that urate transport mediated by WT hSLC2A9 and its I335V, W110A, and W110F mutants were similar at 0.1 mM substrate concentration, the kinetics for both mutants were fully characterized
Summary
A hydrophobic residue in TM7 of the hSLC2A9 was found to affect hexose transport. Results: Both Ile-335 and Trp-110 affect fructose trans-acceleration of urate, whereas only Trp-110 directly affects urate transport. A mutation of isoleucine 335 to valine (I355V) in hSLC2A9 can reduce fructose transport while not affecting glucose fluxes This current study demonstrates that the I335V mutant transports urate to the wild type hSLC2A9; Ile-335 is necessary for urate/fructose trans-acceleration exchange to occur. Substitution of isoleucine 335 with valine (I335V) in hSLC2A9 strongly decreased fructose transport with glucose transport remaining unaffected This current study examined the importance of the hydrophobic residues Ile-335 and Trp-110 of hSLC2A9 for urate transport and urate/hexose trans-acceleration exchange. For this we constructed three point mutations of hSLC2A9: isoleucine 335 to valine (I335V) and tryptophan 110 to alanine (W110A) and phenylalanine (W110F). Together they confirmed that urate and fructose are both mediated by hSLC2A9 but that they interact with the transporter protein differently
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