Cell-free synthesis and assembly of prolyl 4-hydroxylase: the role of the beta-subunit (PDI) in preventing misfolding and aggregation of the alpha-subunit.

Prolyl 4-hydroxylase (P4-H) catalyses a vital post-translational modification in the biosynthesis of collagen. The enzyme consists of two distinct polypeptides forming an alpha 2 beta 2 tetramer (alpha = 64 kDa, beta = 60 kDa), the beta-subunit being identical to the multifunctional enzyme protein disulfide isomerase (PDI). By studying the cell-free synthesis of the rat alpha-subunit of P4-H we have shown that the alpha-subunit can be translocated, glycosylated and the signal peptide cleaved by dog pancreatic microsomal membranes to yield both singly and doubly glycosylated forms. When translations were carried out under conditions which prevent disulfide bond formation, the product synthesized formed aggregates which were associated with the immunoglobulin heavy chain binding protein (BiP). Translations carried out under conditions that promote disulfide bond formation yielded a product that was not associated with BiP but formed a complex with the endogenous beta-subunit (PDI). Complex formation was detected by co-precipitation of the newly synthesized alpha-subunit with antibodies raised against PDI, by sucrose gradient centrifugation and by chemical cross-linking. When microsomal vesicles were depleted of PDI, BiP and other soluble endoplasmic reticulum proteins, no complex formation was observed and the alpha-subunit aggregated even under conditions that promote disulfide bond formation. We have therefore demonstrated that the enzyme P4-H can be assembled at synthesis in a cell-free system and that the solubility of the alpha-subunit is dependent upon its association with PDI.     

Interaction of FXYD10 (PLMS) with Na,K-ATPase from shark rectal glands. Close proximity of Cys74 of FXYD10 to Cys254 in the a domain of the alpha-subunit revealed by intermolecular thiol cross-linking

FXYD domain-containing proteins are tissue-specific regulators of the Na,K-ATPase that have been shown to have significant physiological implications. Information about the sites of interaction between some FXYD proteins and subunits of the Na,K-ATPase is beginning to emerge. We previously identified an FXYD protein in plasma membranes from shark rectal gland cells and demonstrated that this protein (FXYD10) modulates shark Na,K-ATPase activity. The present study was undertaken to identify the location of the C-terminal domain of FXYD10 on the alpha-subunit of Na,K-ATPase, using covalent cross-linking combined with proteolytic cleavage. Treatment of Na,K-ATPase-enriched membranes with the homobifunctional thiol cross-linker 1,4-bismaleimidyl-2,3-dihydroxybutane resulted in cross-linking of FXYD10 to the alpha-subunit. Cross-linking was not affected by preincubation with sodium or potassium but was significantly reduced after pre-incubation with the non-hydrolyzable ATP analog beta,gamma-methyleneadenosine 5'-triphosphate (AMP-PCP). A peptic assay was developed, in which pepsin treatment of Na,K-ATPase at low pH resulted in extensive cleavage of the alpha-subunit while FXYD10 was left intact. Proteolytic fragments of control and cross-linked preparations were isolated by immunoprecipitation and analyzed by gel electrophoresis. A proteolytic fragment containing FXYD10 cross-linked to a fragment from the alpha-subunit could be localized on SDS gels. Sequencing of this fragment showed the presence of FXYD10 as well as a fragment within the A domain of the alpha-subunit comprising 33 amino acids, including a single Cys residue, Cys254. Thus, regulation of Na,K-ATPase by FXYD10 occurs in part via cytoplasmic interaction of FXYD10 with the A domain of the shark alpha-subunit.     

Site-directed chemical labeling of extracellular loops in a membrane protein. The topology of the Na,K-ATPase alpha-subunit

We have mapped the membrane topology of the renal Na,K-ATPase alpha-subunit by using a combination of introduced cysteine mutants and surface labeling with a membrane impermeable Cys-directed reagent, N-biotinylaminoethyl methanethiosulfonate. To begin our investigation, two cysteine residues (Cys(911) and Cys(964)) in the wild-type alpha-subunit were substituted to create a background mutant devoid of exposed cysteines (Lutsenko, S., Daoud, S., and Kaplan, J. H. (1997) J. Biol. Chem. 272, 5249-5255). Into this background construct were then introduced single cysteines in each of the five putative extracellular loops (P118C, T309C, L793C, L876C, and M973C) and the resulting alpha-subunit mutants were co-expressed with the beta-subunit in baculovirus-infected insect cells. All of our expressed Na,K-ATPase mutants were functionally active. Their ATPase, phosphorylation, and ouabain binding activities were measured, and the turnover of the phosphoenzyme intermediate was close to the wild-type enzyme, suggesting that they are folded properly in the infected cells. Incubation of the insect cells with the cysteine-selective reagent revealed essentially no labeling of the alpha-subunit of the background construct and labeling of all five mutants with single cysteine residues in putative extracellular loops. Two additional mutants, V969C and L976C, were created to further define the M9M10 loop. The lack of labeling for these two mutants showed that although Met(973) is apparently exposed, Val(969) and Leu(976) are not, demonstrating that this method may also be utilized to define membrane aqueous boundaries of membrane proteins. Our labeling studies are consistent with a specific 10-transmembrane segment model of the Na,K-ATPase alpha-subunit. This strategy utilized only functional Na,K-ATPase mutants to establish the membrane topology of the entire alpha-subunit, in contrast to most previously applied methods.     

Association of Renal Na,K-ATPase α-Subunit with the β- and γ-Subunits Based on Cryoelectron Microscopy

Na,K-ATPase transports Na(+) and K(+) across cell membranes and consists of alpha- and beta-subunits. Na,K-ATPase also associates with small FXYD proteins that regulate the activity of the pump. We have used cryoelectron microscopy of two-dimensional crystals including data to 8 A resolution to determine the three-dimensional (3-D) structure of renal Na,K-ATPase containing FXYD2, the gamma-subunit. A homology model for the alpha-subunit was calculated from a Ca(2+)-ATPase structure and used to locate the additional beta- and gamma-subunits present in the 3-D map of Na,K-ATPase. Based on the 3-D map, the beta-subunit is located close to transmembrane helices M8 and M10 and the gamma-subunit is adjacent to helices M2 and M9 of the alpha-subunit.     

Disulfide bonds Cys(9)-Cys(57), Cys(34)-Cys(88) and Cys(38)-Cys(90) of the beta-subunit of human chorionic gonadotropin are crucial for heterodimer formation with the alpha-subunit: experimental evidence for the conclusions from the crystal structure of hCG

Human chorionic gonadotropin (hCG) is a heterodimeric glycoprotein hormone essential for the establishment and maintenance of pregnancy. The alpha- and beta-subunits of hCG are highly cross-linked internally by disulfide bonds that seem to stabilize the tertiary structures required for the noncovalent association of the subunits to generate hormonal activity. This paper describes the results of our studies on the role of the disulfide bonds of hCG-beta in heterodimer formation with the alpha-subunit. Six disulfide peptides incorporating each of the six disulfide bonds of hCG-beta were screened, along with their linear counterparts, for their ability to competitively inhibit the recombination of alpha- and beta-subunits. The disulfide peptides Cys (9-57), Cys (34-88) and Cys (38-90) were found to inhibit the alpha/beta recombination whereas the remaining three disulfide peptides viz. Cys (23-72), Cys (26-110) and Cys (93-100) did not exhibit any inhibition activity. Interestingly, none of the linear peptides could inhibit the alpha/beta recombination. Results clearly demonstrate that the disulfide bonds Cys(9)-Cys(57), Cys(34)-Cys(88) and Cys(38)-Cys(90) of the beta-subunit of hCG are crucial for heterodimer formation with the alpha-subunit thus providing experimental confirmation of the conclusions from the crystal structure of the hormone.     

Chimeric domain analysis of the compatibility between H(+), K(+)-ATPase and Na(+),K(+)-ATPase beta-subunits for the functional expression of gastric H(+),K(+)-ATPase.

Gastric H(+),K(+)-ATPase consists of alpha-subunit with 10 transmembrane domains and beta-subunit with a single transmembrane domain. We constructed cDNAs encoding chimeric beta-subunits between the gastric H(+),K(+)-ATPase and Na(+),K(+)-ATPase beta-subunits and co-transfected them with the H(+),K(+)-ATPase alpha-subunit cDNA in HEK-293 cells. A chimeric beta-subunit that consists of the cytoplasmic plus transmembrane domains of Na(+),K(+)-ATPase beta-subunit and the ectodomain of H(+),K(+)-ATPase beta-subunit assembled with the H(+),K(+)-ATPase alpha-subunit and expressed the K(+)-ATPase activity. Therefore, the whole cytoplasmic and transmembrane domains of H(+),K(+)-ATPase beta-subunit were replaced by those of Na(+),K(+)-ATPase beta-subunit without losing the enzyme activity. However, most parts of the ectodomain of H(+),K(+)-ATPase beta-subunit were not replaced by the corresponding domains of Na(+), K(+)-ATPase beta-subunit. Interestingly, the extracellular segment between Cys(152) and Cys(178), which contains the second disulfide bond, was exchangeable between H(+),K(+)-ATPase and Na(+), K(+)-ATPase, preserving the K(+)-ATPase activity intact. Furthermore, the K(+)-ATPase activity was preserved when the N-terminal first 4 amino acids ((67)DPYT(70)) in the ectodomain of H(+),K(+)-ATPase beta-subunit were replaced by the corresponding amino acids ((63)SDFE(66)) of Na(+),K(+)-ATPase beta-subunit. The ATPase activity was abolished, however, when 4 amino acids ((76)QLKS(79)) in the ectodomain of H(+),K(+)-ATPase beta-subunit were replaced by the counterpart ((72)RVAP(75)) of Na(+),K(+)-ATPase beta-subunit, indicating that this region is the most N-terminal one that discriminates the H(+),K(+)-ATPase beta-subunit from that of Na(+), K(+)-ATPase.     

Cross-linking of the erythrocyte (Na+,K+)-ATPase. Chemical cross-linkers induce alpha-subunit-band 3 heterodimers and do not induce alpha-subunit homodimers.

Earlier studies (Periyasamy, S. M., Huang, W.-H., and Askari, A. (1983) J. Biol. Chem. 258, 9878-9885) suggested that Cu2+ and o-phenanthroline induced the formation of cross-linked homodimers between alpha-subunits of the erythrocyte (Na+,K+)-ATPase. This was interpreted as indicating that alpha-subunits existed in close proximity in native erythrocyte membranes. The alpha-subunit and band 3 monomers have similar molecular weights (M(r) approximately 100,000) and exist in the membrane in molar ratios of approximately 1:3000 alpha-subunit:band 3. We explored the possibility that alpha-subunit and band 3 could be induced to form heterodimeric structures in the presence of cross-linking reagents. Using methods similar to those employed in the above-cited reference we demonstrated that cross-linked dimers containing phosphorylated alpha-subunits had proteolytic sensitivity that was inconsistent with the formation of alpha-subunit homodimers and fully consistent with heterodimer formation between alpha-subunit and band 3. The data also indicated that alpha-subunit-band 3 heterodimer formation is dependent on the conformational state of the (Na+,K+)-ATPase. Using the appropriate reagents we obtained cross-linked products which were consistent with heterodimer formation between alpha- and beta-subunits of the (Na+,K+)-ATPase. Our data argue against a close association between pairs of (Na+,K+)-ATPase alpha-subunits in the human red cell membrane.     

Furin cleavage potentiates the membrane fusion-controlling intersubunit disulfide bond isomerization activity of leukemia virus Env

The membrane fusion protein of murine leukemia virus is a trimer of a disulfide-linked peripheral-transmembrane (SU-TM) subunit complex. The intersubunit disulfide bond is in SU linked to a disulfide bond isomerization motif, CXXC, with which the virus controls its fusion reaction (M. Wallin, M. Ekstr?m, and H. Garoff, EMBO J. 23:54-65, 2004). Upon receptor binding the isomerase rearranges the intersubunit disulfide bond into a disulfide bond isomer within the motif. This facilitates SU dissociation and fusion activation in the TM subunit. In the present study we have asked whether furin cleavage of the Env precursor potentiates the isomerase to be triggered. To this end we accumulated the late form of the precursor, gp90, in the cell by incubation in the presence of a furin-inhibiting peptide. The isomerization was done by NP-40 incubation or by a heat pulse under alkylation-free conditions. The cells were lysed in the presence of alkylator, and the precursor was immunoprecipitated, gel isolated, deglycosylated, and subjected to complete trypsin digestion. Disulfide-linked peptide complexes were separated by sodium dodecyl sulfate-tricine-polyacrylamide gel electrophoresis under nonreducing conditions. This assay revealed the size of the characteristic major disulfide-linked peptide complex that differentiates the two isomers of the disulfide bond between Cys336 (or Cys339) and Cys563, i.e., the bond corresponding to the intersubunit disulfide bond. The analyses showed that the isomerase was five- to eightfold more resistant to triggering in the precursor than in the mature, cleaved form. This suggests that the isomerase becomes potentiated for triggering by a structural change in Env that is induced by furin cleavage in the cell.     

Attempt to map the receptor binding sites of human follicle-stimulating hormone using disulfide peptides of its beta-subunit indicates major involvement of the regions around disulfide bonds Cys28-Cys82 and Cys32-Cys84 in receptor binding of the hormone.

Follicle-stimulating hormone (FSH) is a heterodimeric glycoprotein hormone secreted by the anterior pituitary. It plays a very important role in folliculogenesis in females and is responsible for spermatogenesis in males. The alpha-subunit which is common within a species and the beta-subunit which is hormone-specific are held together by noncovalent association. This association is very essential for the biological activity of the hormone. Each of these subunits are highly cross-linked by disulfide bonds which appear to stabilize the tertiary structures required for the noncovalent association of the subunits to generate hormonal activity. This study was initiated to delineate the role of the disulfide bonds of hFSH beta in receptor binding of the hormone. Five intermolecular and one intramolecular disulfide peptides corresponding to the disulfide bonds found in hFSH beta were synthesized and screened along with their linear counterparts, for their ability to competitively inhibit the radiolabelled [125I]hFSH from binding to the FSH receptor containing membranes from the testis of immature rats. The disulfide peptides Cys28-Cys82 and Cys32-Cys84 were found to be the most potent in inhibiting radiolabelled hFSH from binding to its receptor. The results suggest the involvement of the regions around disulfide bonds Cys28-Cys82 and Cys32-Cys84 in receptor binding of the hormone. The studies also suggest the involvement of beta L2 and beta L3 loop regions in receptor binding of the hormone. This study is the first of its kind to use disulfide peptides rather than linear peptides to map the receptor binding regions of hFSH.     

Alternatively folded choriogonadotropin analogs. Implications for hormone folding and biological activity

Most heterodimeric proteins are stabilized by intersubunit contacts or disulfide bonds. In contrast, human chorionic gonadotropin (hCG) and other glycoprotein hormones are secured by a strand of their beta-subunits that is wrapped around alpha-subunit loop 2 "like a seatbelt." During studies of hCG synthesis in COS-7 cells, we found that, when the seatbelt was prevented from forming the disulfide that normally "latches" it to the beta-subunit, its carboxyl-terminal end can "scan" the surface of the heterodimer and become latched by a disulfide to cysteines substituted for residues in the alpha-subunit. Analogs in which the seatbelt was latched to residues 35, 37, 41-43, and 56 of alpha-subunit loop 2 had similar lutropin activities to those of hCG; that in which it was latched to residue 92 at the carboxyl terminus had 10-20% the activity of hCG. Attachment of the seatbelt to alpha-subunit residues 45-51, 86, 88, 90, and 91 reduced lutropin activity substantially. These findings show that the heterodimer can form before the beta-subunit has folded completely and support the notions that the carboxyl-terminal end of the seatbelt, portions of alpha-subunit loop 2, and the end of the alpha-subunit carboxyl terminus do not participate in lutropin receptor interactions. They suggest also that several different architectures could have been sampled without disrupting hormone activity as the glycoprotein hormones diverged from other cysteine knot proteins.     

The carboxyl-terminal 161 amino acids of the Na,K-ATPase alpha-subunit are sufficient for assembly with the beta-subunit.

Chimeric cDNAs encoding regions of the Na,K-ATPase alpha-subunit and a sarcoplasmic reticulum Ca(2+)-ATPase were constructed and expressed together with the avian Na,K-ATPase beta-subunit cDNA in COS-1 cells to determine which regions of the alpha-subunit are required for assembly with the beta-subunit. Assembly was assayed by immune precipitation of the chimeric subunit with a monoclonal antibody to the avian beta-subunit. A chimera composed of the amino-terminal two-thirds of the Na,K-ATPase and carboxyl-terminal one-third of the Ca(2+)-ATPase did not assemble with the avian beta-subunit. In contrast, the reciprocal chimera, containing the carboxyl-terminal one-third of the Na,K-ATPase, assembled with the beta-subunit. A third chimera, in which 161 amino acids of the Na,K-ATPase carboxyl terminus replaced the corresponding amino acids of the Ca(2+)-ATPase carboxyl terminus, also assembled with the beta-subunit. These results suggest that the aminoacyl residues of the Na,K-ATPase alpha-subunit critical for subunit assembly lie within the carboxyl-terminal 16% of the sequence.     

Threading of a glycosylated protein loop through a protein hole: implications for combination of human chorionic gonadotropin subunits

Chorionic gonadotropin (hCG) is a heterodimeric placental glycoprotein hormone essential for human reproduction. Twenty hCG beta-subunit residues, termed the seatbelt, are wrapped around alpha-subunit loop 2 (alpha 2) and their positions "latched" by a disulfide formed by cysteines at the end of the seatbelt (Cys 110) and in the beta-subunit core (Cys 26). This unique arrangement explains the stability of the heterodimer but raises questions as to how the two subunits combine. The seatbelt is latched in the free beta-subunit. If the seatbelt remained latched during the process of subunit combination, formation of the heterodimer would require alpha 2 and its attached oligosaccharide to be threaded through a small beta-subunit hole. The subunits are known to combine during oxidizing conditions in vitro, and studies described here tested the idea that this requires transient disruption of the latch disulfide, possibly as a consequence of the thioredoxin activity reported in hCG. We observed that alkylating agents did not modify either cysteine in the latch disulfide (Cys 26 or Cys 110) during heterodimer formation in several oxidizing conditions and had minimal influence on these cysteines during combination in the presence of mild reductants (1--3 mM beta-mercaptoethanol). Reducing agents appeared to accelerate subunit combination by disrupting a disulfide (Cys 93--Cys 100) that forms a loop within the seatbelt, thereby increasing the size of the beta-subunit hole. We propose a mechanism for hCG assembly in vitro that depends on movements of alpha 2 and the seatbelt and suggest that the process of glycoprotein hormone subunit combination may be useful for studying the movements of loops during protein folding.     

Mutational study on the roles of disulfide bonds in the beta-subunit of gastric H+,K+-ATPase

The gastric proton pump, H(+),K(+)-ATPase, consists of the catalytic alpha-subunit and the non-catalytic beta-subunit. Correct assembly between the alpha- and beta-subunits is essential for the functional expression of H(+),K(+)-ATPase. The beta-subunit contains nine conserved cysteine residues; two are in the cytoplasmic domain, one in the transmembrane domain, and six in the ectodomain. The six cysteine residues in the ectodomain form three disulfide bonds. In this study, we replaced each of the cysteine residues of the beta-subunit with serine individually and in several combinations. The mutant beta-subunits were co-expressed with the alpha-subunit in human embryonic kidney 293 cells, and the role of each cysteine residue or disulfide bond in the alpha/beta assembly, stability, and cell surface delivery of the alpha- and beta-subunits and H(+),K(+)-ATPase activity was studied. Mutant beta-subunits with a replacement of the cytoplasmic and transmembrane cysteines preserved H(+),K(+)-ATPase activity. All the mutant beta-subunits with replacement(s) of the extracellular cysteines did not assemble with the alpha-subunit, resulting in loss of H(+),K(+)-ATPase activity. These mutants did not permit delivery of the alpha-subunit to the cell surface. Therefore, each of these disulfide bonds of the beta-subunit is essential for assembly with the alpha-subunit and expression of H(+),K(+)-ATPase activity as well as for cell surface delivery of the alpha-subunit.     

Conformational changes in the alpha- and beta-subunits of the insulin receptor identified by anti-peptide antibodies

The structure of the insulin receptor was studied with polyclonal antibodies obtained from rabbits which were immunized with synthetic peptides having a sequence identity to three regions of the alpha-subunit and five regions of the beta-subunit. None of the alpha-subunit antibodies including alpha-Pep8 (residues 40-49 (Ullrich, A., Bell, J.R., Chen, E.Y., Herrera, R., Petruzzelli, L.M., Dull, T.J., Gray, A., Coussens, L., Liao, Y.-C., Tsubokawa, M., Mason, A., Seeburg, P.H., Grunfeld, C., Rosen, O.M., and Ramachandran, J. (1985) Nature 313, 756-761), alpha-Pep7 (12 amino acid C-terminal extension (Ebina, Y., Ellis, L., Jarnagin, K., Ederly, M., Graf, L., Clauser, E., Ou, J.-H., Masiar, F., Kan, Y.W., Goldfine, I.D., Roth, R.A., and Rutter, W.J. (1985) Cell 313, 747-758], or alpha-Pep6 (residues 1-7, 9) immunoprecipitated the human insulin receptor solubilized from IM-9 lymphocytes; however, alpha-Pep8 immunoprecipitated the dithiothreitol-reduced receptor. Antibodies prepared against the N terminus of the beta-subunit (alpha-Pep5, residues 780-790) and the ATP binding site (alpha-Pep3, residues 1013-1022) did not react with the intact receptor under any conditions; however, antibodies to the C terminus of the beta-subunit (alpha-Pep1, residues 1314-1324) and to the juxta-membrane region (alpha-Pep3, residues 952-962) immunoprecipitated the solubilized receptor in both its phosphorylated and nonphosphorylated forms. In contrast, the antibody reactive with the regulatory region of the beta-subunit which contains the major autophosphorylation sites (alpha-Pep2, residues 1143-1154) only precipitated the phosphorylated form. Thus the conformation of the extracellular domain of the receptor is rigid and stabilized by disulfide bonds, whereas several regions of the intracellular domain are accessible to antibodies and undergo conformational changes during autophosphorylation.     

Disulfide bond rearrangement during formation of the chorionic gonadotropin beta-subunit cystine knot in vivo

The intracellular kinetic folding pathway of the human chorionic gonadotropin beta-subunit (hCG-beta) reveals the presence of a disulfide between Cys residues 38-57 that is not detected by X-ray analysis of secreted hCG-beta. This led us to propose that disulfide rearrangement is an essential feature of cystine knot formation during CG-beta folding. To test this, we used disulfide bond formation to monitor progression of intracellular folding intermediates of a previously uncharacterized protein, the CG-beta subunit of cynomolgous macaque (Macaca fascicularis). Like its human counterpart hCG-beta with which it shares 81% identity, macaque (m)CG-beta is a cystine knot-containing subunit that assembles with an alpha-subunit common to all glycoprotein hormone members of its species to form a biologically active heterodimer, mCG, which, like hCG, is required for pregnancy maintenance. An early mCG-beta folding intermediate, mpbeta1, contained two disulfide bonds, one between Cys34 and Cys88 and the other between Cys38 and Cys57. The subsequent folding intermediate, mpbeta2-early, was represented by an ensemble of folding forms that, in addition to the two disulfides mentioned above, included disulfide linkages between Cys9 and Cys57 and between Cys38 and Cys90. These latter two disulfides are those contained within the beta-subunit cystine knot and reveal that a disulfide exchange occurred during the mpbeta2-early folding step leading to formation of the mCG-beta knot. Thus, while defining the intracellular kinetic protein folding pathway of a monkey homologue of CG-beta, we detected the previously predicted disulfide exchange event crucial for CG-beta cystine knot formation and attainment of CG-beta assembly competence.     

cDNA cloning of the beta-subunit of the rat gastric H,K-ATPase

A cDNA encoding the beta-subunit of the rat gastric H,K-ATPase has been identified using oligonucleotide probes based on the amino acid sequences of two peptides from the pig H,K-ATPase beta-subunit (Hall, K., Perez, G., Anderson, D., Gutierrez, C., Munson, K., Hersey, S. J., Kaplan, J. H., and Sachs, G. (1990) Biochemistry 29, 701-706). The nucleotide sequence of the 1.3-kilobase cDNA has been determined and the primary structure of the protein deduced. The protein consists of 294 amino acids and has an Mr of 33,625. The amino acid sequence of the H,K-ATPase beta-subunit is similar to those of the beta 1 (29% identity) and beta 2 (37% identity) subunits of the Na,K-ATPase. Based on the hydropathy profile it seems to have the same transmembrane organization as the Na,K-ATPase beta-subunit, with a single membrane-spanning domain near the amino terminus. Seven potential N-linked glycosylation sites are located in the putative extracellular regions of the protein. Northern blot analyses of poly(A)+ RNAs from 13 tissues demonstrate that the H,K-ATPase beta-subunit mRNA is expressed at high level in stomach and is not expressed in any of the other tissues.     

Proteolytic processing of the beta-subunit of the lysosomal enzyme, beta-hexosaminidase, in normal human fibroblasts

We have characterized the proteolytic processing of the beta-subunit of beta-hexosaminidase by identifying the amino termini of the various forms synthesized in cell-free translation and in cultured human fibroblasts. The procedures used had been developed for similar studies of the alpha-subunit (Little, L. E., Lau, M. M. H., Quon, D. V. K., Fowler, A. V., and Neufeld, E. F. (1988) J. Biol. Chem. 263, 4288-4292). Radioactive amino acids were incorporated biosynthetically into the different forms of the beta-subunit, which were isolated by immunoprecipitation, gel electrophoresis, and electroelution, and analyzed by automated Edman degradation. Translation by reticulocyte lysate in the presence of canine pancreas microsomes gave a product with alanine 43 at the amino terminus. The lysate could initiate translation at methionine 1 or methionine 13, depending on the SP6 mRNA provided. The product of signal peptidase action, the precursor form of the beta-subunit with amino-terminal alanine 43, was found in NH4+-induced secretions of cultured fibroblasts; intracellularly, this form was trimmed of two additional amino acids. The mature form was found to consist of three polypeptides joined by disulfide bonds; the amino termini were found to be valine 48, threonine 122, and lysine 315. Thus, in contrast to the alpha-subunit, the mature form of the beta-subunit of beta-hexosaminidase is derived from the precursor by internal proteolytic nicking rather than by removal of a large amino-terminal peptide segment.     

Extracellular domains,transmembrane segments,and intracellular domains interact to determine the cation selectivity of Na,K- and gastric H,K-ATPase

We have previously reported that three residues of the fourth transmembrane segment (TM4) of the Na,K- and gastric H,K-ATPase alpha-subunits appear to play a major role in the distinct cation selectivities of these pumps [Mense, M., et al. (2000) J. Biol. Chem. 275, 1749-1756]. Substituting these three residues in the Na,K-ATPase sequence with their H,K-ATPase counterparts (L319F, N326Y, T340S) and replacing the TM3-TM4 ectodomain sequence with that of the H,K-ATPase alpha-subunit result in a pump that exhibits 50% of its maximal ATPase activity in the absence of Na(+) when the assay is performed at pH 6.0. This effect is not seen when the ectodomain alone is replaced. To gain more insight into the contributions of the three residues to establishing the selectivity of these pumps for Na(+) ions versus protons, we generated Na,K-ATPase constructs in which these residues are replaced by their H,K-ATPase counterparts either singly or in combinations. Surprisingly, none of the point mutants nor even the triple mutant was able to hydrolyze ATP at pH 6.0 at a rate greater than 20% of their respective V(max)s. For the point mutants L319F and N326Y, protons seem to competitively inhibit ATP hydrolysis at pH 6.0, based on the low apparent affinity for Na(+) ions at pH 6.0 compared to pH 7.5. It would appear, therefore, that the cation selectivity of Na,K- and H,K-ATPase is generated through a cooperative effort between residues of transmembrane segments and the flanking loops that connect these transmembrane domains. This view is further supported by homology modeling of the Na,K-ATPase based on the crystal structure of the SERCA pump.     

Glycoprotein hormone assembly in the endoplasmic reticulum: I. The glycosylated end of human alpha-subunit loop 2 is threaded through a beta-subunit hole

Glycoprotein hormone heterodimers are stabilized by their unusual structures in which a glycosylated loop of the alpha-subunit straddles a hole in the beta-subunit. This hole is formed when a cysteine at the end of a beta-subunit strand known as the "seatbelt" becomes "latched" by a disulfide to a cysteine in the beta-subunit core. The heterodimer is stabilized in part by the difficulty of threading the glycosylated end of the alpha-subunit loop 2 through this hole, a phenomenon required for subunit dissociation. Subunit combination in vitro, which occurs by the reverse process, can be accelerated by removing the alpha-subunit oligosaccharide. In cells, heterodimer assembly was thought to occur primarily by a mechanism in which the seatbelt is wrapped around the alpha-subunit after the subunits dock. Here we show that this "wraparound" process can be used to assemble disulfide cross-linked human choriogonadotropin analogs that contain an additional alpha-subunit cysteine, but only if the normal beta-subunit latch site has been removed. Normally, the seatbelt is latched before the subunits dock and assembly is completed when the glycosylated end of alpha-subunit loop 2 is threaded beneath the seatbelt. The unexpected finding that most assembly of human choriogonadotropin, human follitropin, and human thyrotropin heterodimers occurs in this fashion, indicates that threading may be an important phenomenon during protein folding and macromolecule assembly in the endoplasmic reticulum. We suggest that the unusual structures of the glycoprotein hormones makes them useful for identifying factors that influence this process in living cells.     

beta-subunit assembly is essential for the correct packing and the stable membrane insertion of the H,K-ATPase alpha-subunit

The alpha-subunits of H,K-ATPase (HKAalpha) and Na,K-ATPase require a beta-subunit for maturation. We investigated the role of the beta-subunit in the membrane insertion and stability of the HKAalpha expressed in Xenopus oocytes. Individual membrane segments M1, M2, M3, M4, and M9 linked to a glycosylation reporter act as signal anchor (SA) motifs, and M10 acts as a partial stop transfer motif. In combined HKAalpha constructs, M2 acts as an efficient stop transfer sequence, and M3 acts as a SA sequence. However, M5 and M9 have only partial SA function, and M7 has no SA function. Consistent with the membrane insertion properties of segments in combined alpha constructs, M1-3 alpha-proteins are resistant to cellular degradation, and M1-5 up to M1-10 alpha-proteins are not resistant to cellular degradation. However, co-expression with beta-subunits increases the membrane insertion of M9 in a M1-9 alpha-protein and completely protects M1-10 alpha-proteins against cellular degradation. Our results indicate that HKAalpha N-terminal (M1-M4) membrane insertion and stabilization are mediated by intrinsic molecular characteristics; however, the C-terminal (M5-M10) membrane insertion and thus the stabilization of the entire alpha-subunit depend on intramolecular and intermolecular beta-subunit interactions that are similar but not identical to data obtained for the Na,K-ATPase alpha-subunit.