Reinhart A. F. Reithmeier

Characterization and modeling of membrane proteins using sequence analysis

The current libraries of amino acid sequences of membrane proteins are a valuable resource for the analysis of elements common to these proteins. Multiple-sequence alignment techniques and the identification of conserved features of transmembrane segments have improved the prediction of membrane protein topology. Molecular modeling in combination with structural studies or site-directed mutagenesis is proving to be a powerful link between theory and experiment. Unfortunately, the number of high-resolution structures of intrinsic membrane proteins, although increased recently, presents a restricted and perhaps biased view of membrane protein structure.

A Call for Systematic Research on Solute Carriers

Solute carrier (SLC) membrane transport proteins control essential physiological functions, including nutrient uptake, ion transport, and waste removal. SLCs interact with several important drugs, and a quarter of the more than 400 SLC genes are associated with human diseases. Yet, compared to other gene families of similar stature, SLCs are relatively understudied. The time is right for a systematic attack on SLC structure, specificity, and function, taking into account kinship and expression, as well as the dependencies that arise from the common metabolic space.

Interaction of ruthenium red with Ca2+-binding proteins

The interaction of ruthenium red, [(NH3)5Ru-O-Ru(NH3)4-O-Ru(NH3)5]Cl6.4H2O, with various Ca2(+)-binding proteins was studied. Ruthenium red inhibited Ca2+ binding to the sarcoplasmic reticulum protein, calsequestrin, immobilized on Sepharose 4B. Furthermore, ruthenium red bound to calsequestrin with high affinity (Kd = 0.7 microM; Bmax = 218 nmol/mg protein). The dye stained calsequestrin in sodium dodecyl sulfate-polyacrylamide gels or on nitrocellulose paper and was displaced by Ca2+ (Ki = 1.4 mM). The specificity of ruthenium red staining of several Ca2(+)-binding proteins was investigated by comparison with two other detection methods, 45Ca2+ autoradiography and the Stains-all reaction. Ruthenium red bound to the same proteins detected by the 45Ca2+ overlay technique. Ruthenium red stained both the erythrocyte Band 3 anion transporter and the Ca2(+)-ATPase of skeletal muscle sarcoplasmic reticulum. Ruthenium red also stained the EF hand conformation Ca2(+)-binding proteins, calmodulin, troponin C, and S-100. This inorganic dye provides a simple, rapid method for detecting various types of Ca2(+)-binding proteins following electrophoresis.

Dominant and Recessive Distal Renal Tubular Acidosis Mutations of Kidney Anion Exchanger 1 Induce Distinct Trafficking Defects in MDCK Cells

Distal renal tubular acidosis (dRTA), a kidney disease resulting in defective urinary acidification, can be caused by dominant or recessive mutations in the kidney Cl–/HCO3– anion exchanger (kAE1), a glycoprotein expressed in the basolateral membrane of α‐intercalated cells. We compared the effect of two dominant (R589H and S613F) and two recessive (S773P and G701D) dRTA point mutations on kAE1 trafficking in Madin‐Darby canine kidney (MDCK) epithelial cells. In contrast to wild‐type (WT) kAE1 that was localized to the basolateral membrane, the dominant mutants (kAE1 R589H and S613F) were retained in the endoplasmic reticulum (ER) in MDCK cells, with a few cells showing in addition some apical localization. The recessive mutant kAE1 S773P, while misfolded and largely retained in the ER in non‐polarized MDCK cells, was targeted to the basolateral membrane after polarization. The other recessive mutants, kAE1 G701D and designed G701E, G701R but not G701A or G701L mutants, were localized to the Golgi in both non‐polarized and polarized cells. The results suggest that introduction of a polar mutation into a transmembrane segment resulted in Golgi retention of the recessive G701D mutant. When coexpressed, the dominant mutants retained kAE1 WT intracellularly, while the recessive mutants did not. Coexpression of recessive G701D and S773P mutants in polarized cells showed that these proteins could interact, yet no G701D mutant was detected at the basolateral membrane. Therefore, compound heterozygous patients expressing both recessive mutants (G701D/S773P) likely developed dRTA due to the lack of a functional kAE1 at the basolateral surface of α‐intercalated cells.

The erythrocyte anion transporter (band 3): Current Opinion in Structural Biology 1993, 3:515–523

Abstract Band 3 is the best characterized member of a multi-gene anion exchanger family. Multiple promoters within each gene produce a variety of tissue-specific transcripts. The cell-surface expression of band 3 in oocytes is promoted by glycophorin A, which might act as a molecular chaperone. Several band 3 variants have been characterized, including a transport-defective form found in ovalocytic erythrocytes that contains a nine-amino-acid deletion bordering the membrane domain. The roles of the various oligomeric forms of band 3 and interactions between band 3 subunits and between the cytosolic and membrane domains continue to draw the attention of many researchers. The recent production of two-dimensional crystalline arrays of band 3 provides hope that the vast amount of kinetic, biophysical and chemical information available on this transport system will soon be put on a firm structural footing.

Topology of transmembrane segments 1–4 in the human chloride/bicarbonate anion exchanger 1 (AE1) by scanning N-glycosylation mutagenesis

Human AE1 (anion exchanger 1), or Band 3, is an abundant membrane glycoprotein found in the plasma membrane of erythrocytes. The physiological role of the protein is to carry out chloride/bicarbonate exchange across the plasma membrane, a process that increases the carbon-dioxide-carrying capacity of blood. To study the topology of TMs (transmembrane segments) 1-4, a series of scanning N-glycosylation mutants were created spanning the region from EC (extracellular loop) 1 to EC2 in full-length AE1. These constructs were expressed in HEK-293 (human embryonic kidney) cells, and their N-glycosylation efficiencies were determined. Unexpectedly, positions within putative TMs 2 and 3 could be efficiently glycosylated. In contrast, the same positions were very poorly glycosylated when present in mutant AE1 with the SAO (Southeast Asian ovalocytosis) deletion (DeltaA400-A408) in TM1. These results suggest that the TM2-3 region of AE1 may become transiently exposed to the endoplasmic reticulum lumen during biosynthesis, and that there is a competition between proper folding of the region into the membrane and N-glycosylation at introduced sites. The SAO deletion disrupts the proper integration of TMs 1-2, probably leaving the region exposed to the cytosol. As a result, engineered N-glycosylation acceptor sites in TM2-3 could not be utilized by the oligosaccharyltransferase in this mutant form of AE1. The properties of TM2-3 suggest that these segments form a re-entrant loop in human AE1.

Trafficking and Folding Defects in Hereditary Spherocytosis Mutants of the Human Red Cell Anion Exchanger

Hereditary spherocytosis (HS) is a common inherited hemolytic anemia caused by mutations in erythrocyte proteins including the anion exchanger, AE1 (band 3). This study examined seven missense mutations (L707P, R760Q, R760W, R808C, H834P, T837M, and R870W) located in the membrane domain of the human AE1 that are associated with this disease. The HS mutants, constructed in full‐length AE1 cDNA, could be transiently expressed to similar levels in HEK 293 cells. Immunofluorescence, cell surface biotinylation, and pulse chase labeling showed that the HS mutants all exhibited defective cellular trafficking from the endoplasmic reticulum to the plasma membrane. Impaired binding to an inhibitor affinity matrix indicated that the mutant proteins had non‐native structures and may be misfolded. Further characterization of the HS R760Q mutant showed no change in its oligomeric structure or turnover (half‐life=15 h) compared to wild‐type AE1, suggesting the mutant was not aggregated or targeted for rapid degradation via the proteasome. Intracellular retention of HS mutant AE1 would lead to destruction of the protein during erythroid development and would account for the lack of HS mutant AE1 in the plasma membrane of the mature red cell.

Importance of detergent and phospholipid in the crystallization of the human erythrocyte anion-exchanger membrane domain

Three-dimensional crystals were obtained for the membrane domain of the human erythrocyte anion exchanger (AE1, Band 3). Protein homogeneity and stability and the delicate balance between the detergent used and the amount of phospholipids copurifying are critical to the formation of three-dimensional crystals of the AE1 membrane domain. While deglycosylation improved the protein homogeneity, its stability was significantly increased by inhibitor binding. Size-exclusion chromatography showed that the protein was monodisperse in detergents with acyl chains of 10-12 carbons over a pH range of 5.5-10.0. This pH range and the detergents that retained the proteins monodispersity were used for crystallization screening. Crystals were obtained with the protein purified in C(12)E(8), dodecylmaltoside, decylthiomaltoside, and cyclohexyl-hexylmaltoside. Five to 13 lipid molecules per protein were required for the protein crystal formation. Those crystals grown in dodecylmaltoside diffracted X-rays to 14 A. With these factors taken into consideration, ways to further improve the crystal quality are suggested.

Impaired trafficking of human kidney anion exchanger (kAE1) caused by hetero-oligomer formation with a truncated mutant associated with distal renal tubular acidosis.

Autosomal dominant distal renal tubular acidosis (dRTA) has been associated with several mutations in the anion exchanger AE1 gene. The effect of an 11-amino-acid C-terminal dRTA truncation mutation (901 stop) on the expression of kidney AE1 (kAE1) and erythroid AE1 was examined in transiently transfected HEK-293 cells. Unlike the wild-type proteins, kAE1 901 stop and AE1 901 stop mutants exhibited impaired trafficking from the endoplasmic reticulum to the plasma membrane as determined by immunolocalization, cell-surface biotinylation, oligosaccharide processing and pulse-chase experiments. The 901 stop mutants were able to bind to an inhibitor affinity resin, suggesting that these mutant membrane proteins were not grossly misfolded. Co-expression of wild-type and mutant kAE1 or AE1 resulted in intracellular retention of the wild-type proteins in a pre-medial Golgi compartment. This dominant negative effect was due to hetero-oligomer formation of the mutant and wild-type proteins. Intracellular retention of kAE1 in the alpha-intercalated cells of the kidney would account for the impaired acid secretion into the urine characteristic of dRTA.

Structure of a SLC26 Anion Transporter STAS Domain in Complex with Acyl Carrier Protein: Implications for E. coli YchM in Fatty Acid Metabolism

Escherichia coli YchM is a member of the SLC26 (SulP) family of anion transporters with an N-terminal membrane domain and a C-terminal cytoplasmic STAS domain. Mutations in human members of the SLC26 family, including their STAS domain, are linked to a number of inherited diseases. Herein, we describe the high-resolution crystal structure of the STAS domain from E. coli YchM isolated in complex with acyl-carrier protein (ACP), an essential component of the fatty acid biosynthesis (FAB) pathway. A genome-wide genetic interaction screen showed that a ychM null mutation is synthetically lethal with mutant alleles of genes (fabBDHGAI) involved in FAB. Endogenous YchM also copurified with proteins involved in fatty acid metabolism. Furthermore, a deletion strain lacking ychM showed altered cellular bicarbonate incorporation in the presence of NaCl and impaired growth at alkaline pH. Thus, identification of the STAS-ACP complex suggests that YchM sequesters ACP to the bacterial membrane linking bicarbonate transport with fatty acid metabolism.