We previously described the structural organization of P25, a member of the major-intrinsic-protein family found in the digestive tract of homopteran sap-sucking insects [Beuron, F., Le Cahérec, F., Guillam, M. T., Cavalier, A., Garret, A., Tassan, J. P., Delamarche, C., Schultz, P., Mallouh, V., Rolland, J. P., Hubert, J.F., Gouranton, J. & Thomas, D. (1995) J. Biol. Chem. 270, 17414-17422]. We demonstrated, by means of introducing P25 tetramers into the membranes of Xenopus oocytes, that this protein exhibits functional properties similar to those of aquaporin 1, the archetypal water channel [Le Cahérec, F., Bron, P., Verbavatz, J. M., Garret, A., Morel, G., Cavalier, A., Bonnec, G., Thomas, D., Gouranton, J. & Hubert, J.F. (1996) J. Cell Sci. 109, 1285-1295]. In the present work, we cloned a full-length cDNA from a Cicadella viridis library with an open reading frame of 765 bp that encoded a 26-kDa protein whose sequence was 43, 40, 36 and 36% identical to aquaporins 1, 2, z and tonoplast intrinsic protein gamma, respectively. Translation of the corresponding RNA in Xenopus oocytes generated a polypeptide that was specifically recognized by polyclonal antibodies raised against native P25. Expression of the protein in Xenopus oocyte membranes was assessed by immunocytochemistry and led to a 15-fold increase of osmotic membrane water permeability. This increase was inhibited by HgCl2. The permeability had an Arrhenius activation energy of 11.7 kJ/mol. We called this protein Cicadella aquaporin (AQPcic). The oocytes expressing Cicadella aquaporin were less sensitive to HgCl2 than oocytes expressing aquaporin 1. In the Xenopus oocyte system, Cicadella aquaporin failed to transport glycerol, urea and ions. It exhibited permeabilities to ethylene glycol and formamide similar to those measured for aquaporin 1 under the same conditions.
In-frame exon deletions of the Duchenne muscular dystrophy (DMD) gene produce internally truncated proteins that typically lead to Becker muscular dystrophy (BMD), a milder allelic disorder of DMD. We hypothesized that differences in the structure of mutant dystrophin may be responsible for the clinical heterogeneity observed in Becker patients and we studied four prevalent in-frame exon deletions, i.e. Δ45-47, Δ45-48, Δ45-49 and Δ45-51. Molecular homology modelling revealed that the proteins corresponding to deletions Δ45-48 and Δ45-51 displayed a similar structure (hybrid repeat) than the wild-type dystrophin, whereas deletions Δ45-47 and Δ45-49 lead to proteins with an unrelated structure (fractional repeat). All four proteins in vitro expressed in a fragment encoding repeats 16-21 were folded in α-helices and remained highly stable. Refolding dynamics were slowed and molecular surface hydrophobicity were higher in fractional repeat containing Δ45-47 and Δ45-49 deletions compared with hybrid repeat containing Δ45-48 and Δ45-51 deletions. By retrospectively collecting data for a series of French BMD patients, we showed that the age of dilated cardiomyopathy (DCM) onset was delayed by 11 and 14 years in Δ45-48 and Δ45-49 compared with Δ45-47 patients, respectively. A clear trend toward earlier wheelchair dependency (minimum of 11 years) was also observed in Δ45-47 and Δ45-49 patients compared with Δ45-48 patients. Muscle dystrophin levels were moderately reduced in most patients without clear correlation with the deletion type. Disease progression in BMD patients appears to be dependent on the deletion itself and associated with a specific structure of dystrophin at the deletion site.
The MIP (major intrinsic protein) proteins constitute a channel family of currently 150 members that have been identified in cell membranes of organisms ranging from bacteria to man. Among these proteins, two functionally distinct subgroups are characterized: aquaporins that allow specific water transfer and glycerol channels that are involved in glycerol and small neutral solutes transport. Since the flow of small molecules across cell membranes is vital for every living organism, the study of such proteins is of particular interest. For instance, aquaporins located in kidney cell membranes are responsible for reabsorption of 150 liters of water/ day in adult human. To understand the molecular mechanisms of solute transport specificity, we analyzed mutant aquaporins in which highly conserved residues have been substituted by amino acids located at the same positions in glycerol channels. Here, we show that substitution of a tyrosine and a tryptophan by a proline and a leucine, respectively, in the sixth transmembrane helix of an aquaporin leads to a switch in the selectivity of the channel, from water to glycerol.Based on amino acid sequence, members of the MIP 1 family are predicted to share a common topology consisting in 6 transmembrane domains connected by 5 loops (A-E). From biochemical and biophysical data, a model representing these proteins as "hourglasses" has been proposed (1) (Fig. 1A). In this model, the channel pore is constituted by the junction of loops B and E that overlap midway between the leaflets of the membrane. Recently, the three-dimensional structure of the first identified aquaporin, AQP1 (2), has been obtained and has defined that the protein complex is constituted by four monomers (3-5). Each monomer is formed by six tilted ␣ helices spanning the membrane bilayer and surrounding a central density zone. This zone represents likely the narrowest segment of the water pore and may be constituted by loops B and E according to the hourglass model. As opposed to the increasing amount of data aiming to determine aquaporins structure, no study concerning glycerol channels has been reported, but considering their high level of identity, it was assumed that they had the same structural organization. Using a biochemical approach, we showed recently that an insect aquaporin, AQPcic (6), is tetrameric in cell membrane, like AQP1, whereas the glycerol channel of Escherichia coli (GlpF) is a monomer (7). These results suggest that oligomerization of MIP proteins could be involved in transport selectivity. In order to elucidate molecular mechanisms that are accountable of the channel selectivity, we have developed a strategy consisting in a systematic comparison of the physico-chemical properties of amino acids at each position in multiple sequence alignments (8). We have identified five positions (P1-P5) corresponding to amino acid residues conserved in aquaporins and glycerol channels but with highly different physico-chemical properties in the two subgroups. Interestingly, four positions (P2, P3, P...
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