Functional reassembly of the anion transport domain of human red cell band 3 (AE1) from multiple and non-complementary fragments.

We constructed cDNA clones encoding N-terminal, C-terminal and internal polypeptide fragments of the human red cell anion exchanger (band 3; AE1). The internal fragments comprised between one and seven putative transmembrane spans with two or more spans deleted from both termini of the membrane domain of band 3. Sets of three, four or five complementary fragments, which together represented the complete amino acid sequence of the membrane domain, were co-expressed in Xenopus oocytes. Stilbene disulphonate-sensitive chloride uptake assays revealed that all six of the three-fragment combinations and two of the four-fragment combinations reassembled functionally in vivo. Unexpectedly, co-expression of a non-complementary pair of fragments comprising the first five and last seven putative transmembrane spans (i.e. entirely lacking spans six and seven) was also found to be sufficient to generate stilbene disulphonate-sensitive chloride uptake.

The expression of the abnormal human red cell anion transporter from South-East Asian ovalocytes (band 3 SAO) in Xenopus oocytes.

South-East Asian ovalocytosis (SAO) is caused by the heterozygous presence of a variant form of the human erythrocyte anion transporter (band 3; AE1). The expression of band 3 SAO has been studied in Xenopus oocytes. Band 3 SAO is not functional as an anion transporter but is inserted stably into the plasma membrane of oocytes. Band 3 SAO translocation to the cell surface does not require co-expression of normal band 3. Co-expression of glycophorin A (GPA) increases the rate of translocation of band 3 SAO to the oocyte membrane but is not essential for this process. We suggest that the increased tendency of band 3 SAO to form oligomers may facilitate its translocation to the cell surface.

Treatment with crystalline ultra-pure urea reduces the aggregation of integral membrane proteins without inhibiting N-terminal sequencing.

We have demonstrated that N-terminal sequencing can be performed successfully despite boiling protein samples in the presence of urea under precise conditions, before loading them onto SDS-PAGE and transfer to polyvinylidene difluoride membrane. Using myoglobin as a test protein, we found that its ability to undergo N-terminal sequencing was not affected by the presence of urea provided "ultra-pure" urea was used. Consistent with this result, we verified that urea did not carbamylate myoglobin since its molecular mass was measured by mass spectrometry after electroelution of the protein band from the gel. These observations are useful for the study of integral membrane proteins, in particular to study their topology from proteolysis experiments, since heating in the presence of urea before SDS-PAGE reduces membrane protein aggregation [Soulié, S., Mo/ller, J.V., Falson, P., and le Maire, M. (1996) Anal. Biochem. 236, 363-364]. We show that the sequencing yield of a hydrophobic peptide from reticulum Ca2+-ATPase was more than doubled in the presence of urea in accord with the quantification of the Coomassie Blue staining of the gel and of the amount present on the polyvinylidene difluoride membrane. For three peptides of the gastric H+K+-ATPase, the sequencing yield after urea treatment increased almost threefold.

Treatment of Argulus sp. infestation of river frogs.

Ten river frog tadpoles (Rana hecksheri) were collected from Pointsett State Park in South Carolina in April 1995. They were housed together in a tank at the North Carolina Zoological Park. Although no skin lesions were evident at collection, skin scrapings performed 4 weeks later revealed numerous immature and adult Argulus sp. on the tails and dorsal trunks of many of the tadpoles. The adult parasites were removed manually, and the tadpoles were treated with lufenuron (15 mg/l; Program, Novartis Animal Health, Greensboro, N.C.) and sodium chloride (3 g/l) in the tank water for 3 weeks. A single immature Argulus was found on a skin scraping on day 2 of treatment, and no parasites were seen thereafter on skin scrapings obtained through day 28 after the initiation of treatment. Metamorphosis occurred in all tadpoles within 4 weeks of initiating treatment. No deleterious effects of the treatment were noted.

Collecting from third-party payers.

Self-pay collections and insurance collections are similar. Phone the insurance company, obtain a firm payment date, and follow up when payment is not received. Be organized and persistent. Don't hesitate to contact the patient for help. This is the patient's bill that you are trying to collect. You are working on his behalf but the patient is ultimately responsible for payment. The bottom line in third-party collection is phone contact and persistence.

The effects of glycophorin A on the expression of the human red cell anion transporter (band 3) in Xenopus oocytes.

The effects of human red cell glycophorin A (GPA) on the translocation to the plasma membrane and anion transport activity of the human erythrocyte anion transporter (band 3; AE1) have been examined using the Xenopus oocyte expression system. We show that band 3 accumulates steadily at the oocyte surface with time in the presence or absence of GPA, but this occurs more quickly when GPA is coexpressed. The amount of band 3 at the surface is determined by the concentrations of band 3 and GPA cRNA that are injected, with a higher proportion of total band 3 being translocated to the surface in the presence of GPA cRNA. The increased expression of DNDS-sensitive chloride transport is highly specific to GPA, and is not observed when the cRNA to the putative glycophorin E or a very high concentration of the cRNA to glycophorin C are coexpressed with band 3 in oocytes.

Role of N-glycosylation in the expression of human band 3-mediated anion transport.

The human erythrocyte anion transporter (band 3; AE1) has a single N-linked glycosylation site at amino residue Asn-642. To investigate the functional role of the N-glycan in band 3 (b3) we have constructed mutant b3 cDNAs in which this residue has been replaced by Gly, Ser or Thr, and the expression of these mutants was examined in Xenopus oocytes. Chymotrypsin treatment of intact oocytes was used to assess surface b3. Similar amounts of cleavage were observed with both glycosylated and unglycosylated b3. Greater cleavage of b3 was obtained when human red cell glycophorin A (GPA) was co-expressed with either glycosylated or unglycosylated b3. The co-expression of GPA with either glycosylated or unglycosylated b3 increased the stilbene disulphonate-sensitive chloride transport into oocytes at low cRNA concentrations. In both the presence or absence of GPA, a higher b3-mediated chloride influx into oocytes was observed on expression of glycosylated b3 cRNA compared with similar amounts of unglycosylated b3 cRNA. We suggest that glycosylation is not essential for the expression of functional b3 in oocytes, but may play a role in enabling the protein to acquire its correct folding with the highest anion transport activity.

Glycophorin A facilitates the expression of human band 3-mediated anion transport in Xenopus oocytes.

The effects of human red cell glycophorin A (GPA) on the expression of the human erythrocyte anion transporter (band 3, AE1) has been examined in Xenopus oocytes. The coexpression of GPA with band 3 increased stilbene disulfonate-sensitive chloride transport into the oocytes. The effect of GPA was particularly noticeable at low band 3 concentrations and less marked at high band 3 cRNA concentrations. The enhancement of chloride transport was specific to GPA and was not observed when either glycophorin B or glycophorin C was coexpressed with band 3. Immunoprecipitations of whole oocyte homogenates showed the amount of band 3 synthesized was not affected by GPA at subsaturating cRNA concentrations. More band 3 was detected at the oocyte surface by immunoprecipitation when GPA was also expressed. Chymotrypsin treatment of intact oocytes was also used to assess surface band 3 and greater cleavage of band 3 by chymotrypsin was observed when GPA was present. Band 3 synthesis and assembly into canine pancreatic microsomes in the reticulocyte cell-free translation system was not altered by cotranslation of GPA. We suggest that GPA facilitates the translocation of band 3 to the plasma membrane at some point during band 3 biosynthesis in Xenopus oocytes. However, GPA is not essential for the expression of band 3 in red cells, since GPA-deficient individuals have apparently normal levels of band 3. Other GPA-independent mechanisms must also allow translocation of band 3 to the surface membrane in erythroid cells and oocytes. GPA may affect the rate of accumulation of band 3 at the cell surface, rather than the final level in the plasma membrane.

Co-expressed complementary fragments of the human red cell anion exchanger (band 3, AE1) generate stilbene disulfonate-sensitive anion transport.

We have constructed cDNA clones encoding various portions of the human red cell anion transporter (band 3), a well characterized integral membrane protein with up to 14 transmembrane segments. The biosynthesis, stability, cell surface expression, and functionality of these band 3 fragments were investigated by expression from the cRNAs into microsomal membranes using the reticulocyte cell-free translation system and in Xenopus oocytes. Co-expression of the pairs of recombinants encoding the first 8 and last 6 transmembrane spans (8 + 6) or the first 12 and last 2 spans (12 + 2) of band 3 generated stilbene disulfonate-sensitive anion transport in oocytes. When the pairs of fragments 8 + 6 or 12 + 2 were co-expressed with glycophorin A (GPA), translocation to the plasma membrane of the fragment corresponding to the first 12 or the first 8 transmembrane spans was greater than in the absence of GPA. Only the fragment encoding the first 12 transmembrane spans showed GPA-dependent translocation when expressed in the absence of its complementary fragment. A truncated form of band 3 encoding all 14 transmembrane spans but lacking the carboxyl-terminal 30 amino acids of the cytoplasmic tail did not induce anion transport activity in oocytes and was not translocated to the plasma membrane but appeared to be degraded in oocytes. Our results suggest that there is no single signal for the insertion of the different transmembrane spans of band 3 into membranes and that the integrity of the loops between transmembrane spans 8-9 or 12-13 is not essential for anion transport function. Our data also suggest that a region of transmembrane spans 9-12 of band 3 is involved in the process by which GPA facilitates the translocation of band 3 to the surface.

Topology studies with biosynthetic fragments identify interacting transmembrane regions of the human red-cell anion exchanger (band 3; AE1).

The red-cell anion exchanger (band 3; AE1) is a multispanning membrane protein that traverses the bilayer up to 14 times and is N-glycosylated at Asn-642. We have shown that the integrity of six different loops are not essential for stilbene disulphonate-sensitive chloride uptake in Xenopus oocytes. We used an N-glycosylation mutagenesis approach to examine the orientation of the N-terminus and the endogenous glycosylation site of each C-terminal fragment by cell-free translation. The fragments initiating in the loops preceding spans 2, 9 and 11 did not insert into the membrane with the expected orientation. Furthermore, N-glycosylation of Asn-642 might facilitate the membrane integration of span 7. The correct integration of spans 2-3 required the presence of the region containing span 4 and that the luminal exposure of the C-terminus of span 7 is increased in the presence of the region including span 6 or span 8. The results suggest the span 8 region is required for the correct folding of spans 9-10, at least in the presence of the span 11-12 region. Our results suggest that there are intramolecular interactions between the regions of transmembrane spans 1 and 2, 2 and 4, 4 and 5, 7 and 8, 8 and 9-10, and 9-10 and 11-12. Spans 1, 4, 5, 6 and 8 might act as a scaffold for the assembly of spans 2-3, 7 and 9-10. This approach might provide a general method for dissecting the interactions between membrane-spanning regions of polytopic membrane proteins.

Structural model for the organization of the transmembrane spans of the human red-cell anion exchanger (band 3; AE1).

We have examined the functional co-assembly of non-complementary pairs of N- and C-terminal polypeptide fragments of the anion transport domain (b3mem) of human red-cell band 3. cDNA clones encoding non-contiguous pairs of fragments with one transmembrane (TM) region omitted, or overlapping pairs of fragments with between one and ten TM regions duplicated, were co-expressed in Xenopus oocytes and a cell-free translation system. Stilbene disulphonate-sensitive chloride uptake assays in oocytes revealed that the omission of any single TM region of b3mem except spans 6 and 7 caused a complete loss of functional expression. In contrast, co-expressed pairs of fragments overlapping a single TM region 5, 6, 7, 8, 9-10 or 11-12 retained a high level of functionality, whereas fragments overlapping the clusters of TM regions 2-5, 4-5, 5-8 and 8-10 also mediated some stilbene disulphonate-sensitive uptake. The co-assembly of N- or C-terminal fragments with intact band 3, b3mem or other fragments was examined by co-immunoprecipitation in non-denaturing detergent solutions by using monoclonal antibodies against the termini of b3mem. All the fragments, except for TM spans 13-14, co-immunoprecipitated with b3mem. The medium-sized N-terminal fragments comprising spans 1-6, 1-7 or 1-8 co-immunoprecipitated particularly strongly with the C-terminal fragments containing spans 8-14 or 9-14. The fragments comprising spans 1-4 or 1-12 co-immunoprecipitated less extensively than the other N-terminal fragments with either b3mem or C-terminal fragments. There is sufficient flexibility in the structure of b3mem to allow the inclusion of at least one duplicated TM span without a loss of function. We propose a working model for the organization of TM spans of dimeric band 3 based on current evidence.

Complementation studies with co-expressed fragments of human red cell band 3 (AE1): the assembly of the anion-transport domain in xenopus oocytes and a cell-free translation system.

We examined the assembly of the membrane domain of the human red cell anion transporter (band 3; AE1) by co-expression of recombinant N- and C-terminal fragments in Xenopus oocytes and in cell-free translation with canine pancreatic microsomes. Co-immunoprecipitation was performed in non-denaturing detergent solutions using antibodies directed against the N- and C-termini of the membrane domain. Eleven of the twelve fragments were expressed stably in oocytes in the presence or absence of their respective partners. However, the fragment containing from putative span nine to the C-terminus could be detected in oocytes only when co-expressed with its complementary partner containing the first eight spans. Co-expression of pairs of fragments divided in the first, second, third and fourth exofacial loops and in the fourth cytoplasmic loop resulted in a concentration-dependent association, but a pair of fragments divided in the sixth cytoplasmic loop did not co-immunoprecipitate. When two complementary fragments were translated separately in the cell-free system and the purified microsomes were then mixed, co-immunoprecipitation was observed only if the membranes were first fused using polyethylene glycol. This shows that co-immunoprecipitation results from specific interactions within the membrane and is not an artefact of detergent solubilization or immunoprecipitation. We demonstrate that band 3 assembly can occur within the membrane after translation, insertion and initial folding of the individual fragments have been completed. We conclude that most band 3 fragments contain the necessary information to fold in the membrane and adopt a structure that is sufficiently similar to the native protein that it permits correct assembly with its complementary partner.

Altered band 3 structure and function in glycophorin A- and B-deficient (MkMk) red blood cells.

The anion transport activity of the human erythrocyte anion transporter (band 3; AE1) has been examined in both normal and glycophorin A (GPA)-deficient (MkMk) human red blood cells (RBCs). The sulfate transport activity of MkMk cells (from two ethnically diverse sources) was approximately 60% that of normal erythrocytes under the transport assay conditions used. However, MkMk and normal RBCs contained similar amounts of band 3. The reduction in sulfate transport activity was shown to be caused by an increase in the apparent Km for sulfate in MkMk RBCs, suggesting the band 3 in the MkMk RBCs has a lowered binding affinity for sulfate anions. The size of the N-glycan chain on band 3 of the MkMk cells was larger than that on band 3 from normal RBCs. In contrast, the size of the N-glycan chain on the glucose transporter (GLUT1) from MkMk cells was smaller than that on GLUT1 from normal cells. The possible role of GPA in the biosynthesis and anion transport activity of band 3 in normal RBCs is discussed.

Complementation studies with Co-expressed fragments of the human red cell anion transporter (Band 3; AE1). The role of some exofacial loops in anion transport.

We constructed cDNA clones encoding fragments of band 3 in which the membrane domain was truncated from either the N or the C terminus within each of the first four exofacial loops. The truncations containing the C terminus of the protein were fused with the cleavable N-terminal signal sequence of glycophorin A to facilitate the correct orientation of the most N-terminal band 3 membrane span. Cleavage of the glycophorin A signal sequence was observed, except when the truncation was in the first exofacial loop where the signal peptidase cleavage site was probably too close to the membrane. The anion transport activity of co-expressed complementary pairs of truncations which together contained the entire band 3 membrane domain was examined. The pairs of fragments divided in the third and fourth exofacial loops yielded transport activity, but the pair separated within the second exofacial loop was not active. We conclude that the integrity of the second exofacial loop, but not the third and fourth exofacial loops, is necessary for transport activity. The unusually stable association between the fragments divided in the second exofacial loop suggests that interactions may occur between polar surfaces on amphiphilic portions of the third and fifth transmembrane spans.

Functional cell surface expression of the anion transport domain of human red cell band 3 (AE1) in the yeast Saccharomyces cerevisiae.

We expressed the 52-kDa integral membrane domain (B3mem) of the human erythrocyte anion transporter (band 3; AE1) in a protease-deficient strain of the yeast Saccharomyces cerevisiae under the control of the inducible GAL10-CYC1 promoter. Immunoblots of total protein from transformed yeast cells confirmed that the B3mem polypeptide was overexpressed shortly after induction with galactose. Cell surface expression of the functional anion transporter was detected by using a simple transport assay to measure stilbene disulfonate-inhibitable chloride influx into intact yeast cells. The B3mem polypeptide was recycled and degraded by the cells with a half-life of approximately 1-3 hr, which led to a steady-state level of expression in exponentially growing cultures. Our data suggest that 5-10% of total B3mem is functionally active at the cell surface at any one time and that overexpression of this anion transport protein does not interfere with cell growth or survival. This is one of only a few reports of the functional expression of a plasma membrane transport protein in the plasma membrane of yeast cells and to our knowledge is the first report of red cell band 3-mediated anion transport at the plasma membrane of cDNA-transformed cells. The cell surface expression system we describe will provide a simple means for future study of the functional properties of band 3 by using site-directed mutagenesis.

Spectroscopic studies of the interaction of Ca2+-ATPase-peptides with dodecyl maltoside and its brominated analog.

The transmembrane sector of sarcoplasmic reticulum Ca2+-ATPase comprises ten putative transmembrane spans (M1-M10) in current topology models. We report here the structure and properties of three synthetic peptides with a single Trp representing the M6 and M7 regions implicated in Ca2+ binding: peptide M6 (amino acid residues 785-810), peptide M7-L (amino acid residues 808-847) corresponding to loop 6-7 and the majority of span M7, and peptide M7-S (amino acid residues 818-847) which contains a shorter version of loop 6-7 than M7-L. After uptake of the peptides in the hydrophobic environment of dodecyl maltoside micelles, the peptides gain a significant amount of secondary structure, as indicated by their CD spectra. However, the alpha-helical content of M6 is lower than would be expected for a classical transmembrane segment. For M7-L peptide, the L6-7 loop is subject to specific proteolytic cleavage by proteinase K, as in intact Ca2+-ATPase. The formation of the peptide-detergent complexes was followed from the resulting fluorescence intensity changes, either enhancement using n-dodecyl beta-D-maltoside or quenching using the recently introduced brominated analog of n-dodecyl beta-D-maltoside: 7,8-dibromododecyl beta-maltoside [de Foresta, B., Legros, N., Plusquellec, D., le Maire, M. & Champeil, P. (1996) Eur J. Biochem. 241, 343-354]. Our results indicate that M7-L and M7-S are completely taken up by the detergent micelles. In contrast, the M6 peptide, which is highly water soluble, is more loosely associated with the detergent, as is also demonstrated by size-exclusion chromatography. The location of Trp in micelles was evaluated from the quenching observed in mixed micelles of n-dodecyl beta-D-maltoside/7,8-dibromododecyl beta-maltoside, using tryptophan octyl ester and solubilized Ca2+-ATPase as reference compounds. We conclude that W832 in M7 appears to be located near the surface of the micelle, in agreement with its membrane interfacial localization predicted in most Ca2+-ATPase topology models. In contrast, our data suggest that W794 in M6 has a deeper insertion in the micelle although not to the extent predicted by current models of Ca2+-ATPase and the rather short alpha-helix span of M6 may lead to exposure of a significant part of the C-terminal of this peptide to the micelle surface. The results are discussed in relation to the proposed roles of these membrane segments in active transport of Ca2+ ions, in particular, the demonstration that M6 does not behave as a classical transmembrane helix may be correlated with the evidence, from site-directed mutagenesis, that this transmembrane segment should be essential in Ca2+ binding.