Hetero-oligomerization of neuronal glutamate transporters.

Excitatory amino acid transporters (EAATs) mediate the uptake of glutamate into neuronal and glial cells of the mammalian central nervous system. Two transporters expressed primarily in glia, EAAT1 and EAAT2, are crucial for glutamate homeostasis in the adult mammalian brain. Three neuronal transporters (EAAT3, EAAT4, and EAAT5) appear to have additional functions in regulating and processing cellular excitability. EAATs are assembled as trimers, and the existence of multiple isoforms raises the question of whether certain isoforms can form hetero-oligomers. Co-expression and pulldown experiments of various glutamate transporters showed that EAAT3 and EAAT4, but neither EAAT1 and EAAT2, nor EAAT2 and EAAT3 are capable of co-assembling into heterotrimers. To study the functional consequences of hetero-oligomerization, we co-expressed EAAT3 and the serine-dependent mutant R501C EAAT4 in HEK293 cells and Xenopus laevis oocytes and studied glutamate/serine transport and anion conduction using electrophysiological methods. Individual subunits transport glutamate independently of each other. Apparent substrate affinities are not affected by hetero-oligomerization. However, polarized localization in Madin-Darby canine kidney cells was different for homo- and hetero-oligomers. EAAT3 inserts exclusively into apical membranes of Madin-Darby canine kidney cells when expressed alone. Co-expression with EAAT4 results in additional appearance of basolateral EAAT3. Our results demonstrate the existence of heterotrimeric glutamate transporters and provide novel information about the physiological impact of EAAT oligomerization.

Disease-causing dysfunctions of barttin in Bartter syndrome type IV.

Bartter syndrome type IV is an inherited human condition characterized by severe renal salt wasting and sensorineural deafness. The causal gene, BSND, encodes barttin, an accessory subunit of chloride channels located in the kidney and inner ear. Barttin modulates the stability, cell surface localization, and function of ClC-K channels; distinct mutations cause phenotypes of varying severity. For definition of the molecular basis of this diversity, the functional consequences of six disease-causing mutations (R8L, R8W, G10S, Q32X, G47R, and E88X) on ClC-K channel properties were studied by heterologous expression in renal cell lines, electrophysiology, confocal imaging, and biochemical analysis. Three missense mutations (R8L, R8W, and G10S) eliminated the function of ClC-K/barttin channels but did not prevent the insertion of the channels into the surface membrane. Another mutant that produces a mild renal phenotype (G47R) was capable of performing all functions of wild-type barttin but bound to ClC-K channels less effectively. The nonsense mutation E88X affected epithelial sorting, leading to equal amounts of barttin inserting into the basolateral and apical membranes, contrasting with the preferential apical insertion of wild-type barttin. Last, the nonsense mutation Q32X allowed barttin to associate with ClC-K channels but prevented surface membrane insertion and channel activation. These results demonstrate that Bartter syndrome type IV can be caused by various derangements in the function of barttin, likely contributing to the diversity of observed phenotypes.

The guanylate kinase domain of the beta-subunit of voltage-gated calcium channels suffices to modulate gating.

Inactivation of voltage-gated calcium channels is crucial for the spatiotemporal coordination of calcium signals and prevention of toxic calcium buildup. Only one member of the highly conserved family of calcium channel beta-subunits--Ca(V)beta--inhibits inactivation. This unique property has been attributed to short variable regions of the protein; however, here we report that this inhibition actually is conferred by a conserved guanylate kinase (GK) domain and, moreover, that this domain alone recapitulates Ca(V)beta-mediated modulation of channel activation. We expressed and refolded the GK domain of Ca(V)beta(2a), the unique variant that inhibits inactivation, and of Ca(V)beta(1b), an isoform that facilitates it. The refolded domains of both Ca(V)beta variants were found to inhibit inactivation of Ca(V)2.3 channels expressed in Xenopus laevis oocytes. These findings suggest that the GK domain endows calcium channels with a brake restraining voltage-dependent inactivation, and thus facilitation of inactivation by full-length Ca(V)beta requires additional structural determinants to antagonize the GK effect. We found that Ca(V)beta can switch the inactivation phenotype conferred to Ca(V)2.3 from slow to fast after posttranslational modifications during channel biogenesis. Our findings provide a framework within which to understand the modulation of inactivation and a new functional map of Ca(V)beta in which the GK domain regulates channel gating and the other conserved domain (Src homology 3) may couple calcium channels to other signaling pathways.

Conserved dimeric subunit stoichiometry of SLC26 multifunctional anion exchangers.

The SLC26 gene family encodes multifunctional transport proteins in numerous tissues and organs. Some paralogs function as anion exchangers, others as anion channels, and one, prestin (SLC26A5), represents a membrane-bound motor protein in outer hair cells of the inner ear. At present, little is known about the molecular basis of this functional diversity. We studied the subunit stoichiometry of one bacterial, one teleost, and two mammalian SLC26 isoforms expressed in Xenopus laevis oocytes or in mammalian cells using blue native PAGE and chemical cross-linking. All tested SLC26s are assembled as dimers composed of two identical subunits. Co-expression of two mutant prestins with distinct voltage-dependent capacitances results in motor proteins with novel electrical properties, indicating that the two subunits do not function independently. Our results indicate that an evolutionarily conserved dimeric quaternary structure represents the native and functional state of SLC26 transporters.

Design and biological evaluation of linear and cyclic phosphopeptide ligands of the N-terminal SH2 domain of protein tyrosine phosphatase SHP-1.

In an effort to gain further insight into the conformational and topographical requirements for recognition by the N-terminal SH2 domain of protein tyrosine phosphatase SHP-1, we synthesized a series of linear and cyclic peptides derived from the sequence surrounding phosphotyrosine 2267 in the receptor tyrosine kinase Ros (EGLNpYMVL). A molecular modeling approach was used to suggest peptide modifications sterically compatible with the N-SH2-peptide binding groove and possibly enhanced binding affinities compared to the parent peptide. The potencies of the synthesized compounds were evaluated by assaying their ability to stimulate phosphatase activity as well as by their binding affinities to the GST-fused N-SH2 domain of SHP-1. In the series of linear peptides, structural modifications of Ros pY2267 in positions pY + 1 to pY + 3 by amino acid residues structurally related to Phe, for example l-erythro/threo-Abu(betaPh) (5a, 5b), yielded ligands with increased binding affinity. The incorporation of d-amino acid residues at pY + 1 and pY + 3 led to inactive peptides. The replacement of Phe in both pY + 1 and pY + 3 by Tic (1,2,3,4-tetrahydroisoquinoline-3-carboxylic acid) was also not tolerated due to steric hindrance. Cyclic peptides (13, 14) that were linked via residues in positions pY - 1 (Lys) and pY + 2 (Asp/Glu) and contained a Gly residue in the bridging unit displayed much lower potencies for the stimulation of SHP-1 activity but increased binding affinities compared to Ros pY2267. They partially competed with Ros pY2267 in the activation assay. Such cyclic structures may serve as scaffolds for competitive SHP-1 inhibitor design targeting N-SH2 domain-protein interactions that block SHP-1 activation.

Synthesis of linear and cyclic phosphopeptides as ligands for the N-terminal SH2-domain of protein tyrosine phosphatase SHP-1.

Linear and cyclic phosphopeptides related to the pY2267 binding site of the epithelial receptor tyrosine kinase Ros have been synthesized as ligands for the amino-terminal SH2 (src homology) domain of protein tyrosine phosphatase SHP-1. The synthesis was accomplished by Fmoc-based solid-phase methodology using side-chain unprotected phosphotyrosine for the linear and mono-benzyl protected phosphotyrosine for the cyclic peptides. According to molecular modelling, the incorporation of a glycine residue between Lys (position pY-1 relative to phosphotyrosine) and Asp or Glu (position pY+2) was recommended for the cyclic candidates. The preparation of these peptides was successfully performed by the incorporation of a Fmoc-Xxx(Gly-OAll)-OH (Xxx = Asp, Glu) dipeptide building block that was prepared in solution prior to SPPS. The cyclization was achieved with PyBOP following Alloc/OAll-deprotection. This study demonstrates the usefulness of allyl-type protecting groups for the generation of side-chain cyclized phosphopeptides. Alloc/OAll-deprotection and cyclization are compatible with phosphorylated tyrosine.