Structure of Water ChannelsSince th

Structure of Water Channels

Since the initial discovery that a protein acts as a water channel in mammalian red blood cell membranes, additional water channels have been discovered in other tissues, with currently 10 (or 11) known mammalian water channels. CHIP28 [also known as aquaporin-1 (AQP1)] is now identified as a representative of this new class of transport proteins known as aquaporins. AQP1 has 269 amino acids forming two tandem repeats of three membrane-spanning -helices plus two short helical loops (B and E loops) within the lipid bilayer (31). Figure 2 shows the “hourglass” model of AQP1. The carboxy and amino termini are both cytoplasmic. The B loop connects helices 2 and 3 and the E loop connects helices 5 and 6. The connecting loops each contain an Asn-Pro-Ala (NPA) motif that appears to be the site of the channel for water. Sui et al. (26) conducted definitive analysis of AQP1 by X-ray crystallography down to a resolution of 2.2 Å and in so doing clarified the selectivity of the pore region for water molecules. The short helical B and E loops are two membrane-inserted non-membrane- spanning helices capped by Asn residues. The centrally located channel adjacent to these loops has a constriction of 2.8 Å (water molecules have a radius of 2.8 Å). Thus the pore itself consists of an extracellular and a cytoplasmic vestibule connected by an extended narrow pore with a long hydrophobic core and a minimal number of solute-binding sites. Residues in the region of the constriction (particularly histidine-182, which is conserved in the aquaporin family) are critical for the selectivity of the channel for water molecules. The hydrophilic face of the pore provides the chemical groups for displacing waters of hydration to establish a pathway for coordinating the transport of water molecules. It appears that the formation of hydrogen bonds between water molecules and the pore residues causes the specificity of the channel for water. Water molecules permeate the channel single file and break hydrogen bonds with each other to form one and then the other hydrogen bonds with residues of the B and E loops within the channel

Structure of Water Channels

Since the initial discovery that a protein acts as a water channel in mammalian red blood cell membranes, additional water channels have been discovered in other tissues, with currently 10 (or 11) known mammalian water channels. CHIP28 [also known as aquaporin-1 (AQP1)] is now identified as a representative of this new class of transport proteins known as aquaporins. AQP1 has 269 amino acids forming two tandem repeats of three membrane-spanning -helices plus two short helical loops (B and E loops) within the lipid bilayer (31). Figure 2 shows the “hourglass” model of AQP1. The carboxy and amino termini are both cytoplasmic. The B loop connects helices 2 and 3 and the E loop connects helices 5 and 6. The connecting loops each contain an Asn-Pro-Ala (NPA) motif that appears to be the site of the channel for water. Sui et al. (26) conducted definitive analysis of AQP1 by X-ray crystallography down to a resolution of 2.2 Å and in so doing clarified the selectivity of the pore region for water molecules. The short helical B and E loops are two membrane-inserted non-membrane- spanning helices capped by Asn residues. The centrally located channel adjacent to these loops has a constriction of 2.8 Å (water molecules have a radius of 2.8 Å). Thus the pore itself consists of an extracellular and a cytoplasmic vestibule connected by an extended narrow pore with a long hydrophobic core and a minimal number of solute-binding sites. Residues in the region of the constriction (particularly histidine-182, which is conserved in the aquaporin family) are critical for the selectivity of the channel for water molecules. The hydrophilic face of the pore provides the chemical groups for displacing waters of hydration to establish a pathway for coordinating the transport of water molecules. It appears that the formation of hydrogen bonds between water molecules and the pore residues causes the specificity of the channel for water. Water molecules permeate the channel single file and break hydrogen bonds with each other to form one and then the other hydrogen bonds with residues of the B and E loops within the channel

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Struktur saluran airSejak penemuan awal yang protein yang bertindak sebagai saluran air di membran sel darah merah Mamalia, saluran air tambahan telah ditemukan di jaringan lainnya, dengan saluran air mamalia yang diketahui saat ini 10 (atau 11). CHIP28 [juga dikenal sebagai aquaporin-1 (AQP1)] sekarang diidentifikasi sebagai wakil dari kelas baru protein transpor yang dikenal sebagai aquaporins. AQP1 telah 269 asam amino yang membentuk mengulangi tandem dua tiga membran-mencakup - helices ditambah dua pendek heliks loop (B dan E loop) dalam lipid bilayer (31). Gambar 2 menunjukkan model "pasir" AQP1. Karboksi dan amino termini keduanya sitoplasma. B loop menghubungkan helices 2 dan 3 dan E loop terhubung helices 5 dan 6. Loop yang menghubungkan masing-masing berisi motif Asn-Pro-Ala (NPA) yang muncul untuk menjadi situs saluran air. Sui et al. (26) dilakukan analisis definitif AQP1 oleh kristalografi sinar-x ke resolusi 2.2 Å dan dengan demikian diklarifikasi selektivitas wilayah pori-pori untuk molekul air. Loop pendek heliks B dan E adalah dua dimasukkan membran non-membran - mencakup helices capped oleh Asn residu. Saluran terletak berdekatan dengan loop ini memiliki penyempitan 2.8 Å (molekul air memiliki radius 2.8 Å). Sehingga pori-pori itu sendiri terdiri dari ekstraseluler dan balai sitoplasma dihubungkan dengan pori-pori sempit diperluas dengan inti yang lama hidrofobik dan sejumlah minimal situs mengikat zat terlarut. Residu di wilayah penyempitan (terutama histidine-182, yang kekal dalam keluarga aquaporin) sangat penting untuk selektivitas saluran untuk molekul air. Wajah hidrofil pori-pori menyediakan kelompok kimia untuk bobot mati waters of hidrasi untuk membangun jalur untuk koordinasi transportasi molekul air. Tampaknya bahwa pembentukan ikatan hidrogen antara molekul air dan residu pori-pori menyebabkan kekhasan saluran air. Molekul air meresap saluran file tunggal dan mematahkan ikatan hidrogen dengan satu sama lain untuk membentuk satu dan kemudian ikatan hidrogen lain dengan residu loop B dan E dalam saluran

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