P-type ATPases in Caenorhabditis and Drosophila: implications for evolution of the P-type ATPase subunit families with special reference to the Na,K-ATPase and H,K-ATPase subgroup.

Here we show a complete list of the P-type ATPase genes in Caenorhabditis elegans and Drosophila melanogaster. A detailed comparison of the deduced amino-acid sequences in combination with phylogenetic and chromosomal analyses has revealed the following: (1) The diversity of this gene family has been achieved by two major evolutionary steps; the establishment of the major P-type ATPase subgroups with distinct substrate (ion) specificities in a common ancestor of vertebrate and invertebrate, followed by the evolution of multiple isoforms occurring independently in vertebrate and invertebrate phyla. (2) Pairs of genes that have intimate phylogenetic relationship are frequently found in proximity on the same chromosome. (3) Some of the Na,K- and H,K-ATPase isoforms in D. melanogaster and C. elegans lack motifs shown to be important for alpha/beta-subunit assembly, suggesting that such alpha- and beta-subunits might exist by themselves (lonely subunits). The mutation rates for these subunits are much faster than those for the subunits with recognizable assembly domains. (4) The lonely alpha-subunits also lack the major site for ouabain binding that apparently arose before the separation of vertebrates and invertebrates and thus well before the separation of vertebrate Na,K-ATPases and H,K-ATPases. These findings support the idea that a relaxation of functional constraints would increase the rate of evolution and provide clues for identifying the origins of inhibitor sensitivity, subunit assembly, and separation of Na,K- and H,K-ATPases.

Identification and molecular-genetic characterization of a LAMP/CD68-like protein from Caenorhabditis elegans.

Lysosome associated membrane proteins (LAMPs) constitute a family of vertebrate proteins located predominantly in lysosomes, with lesser amounts present in endosomes and at the cell surface. Macrosialin/CD68s are similar to LAMPs in their subcellular distribution and amino acid sequence and presumed structure across the carboxyl terminal two thirds of their length. The functions of LAMPs and CD68s are not known. In the present study, a bioinformatics approach was used to identify a Caenorhabditis elegans protein (LMP-1) with sequence and presumed structural similarity to LAMPs and CD68s. LMP-1 appears to be the only membrane protein in C. elegans that carries a GYXX(phi) vertebrate lysosomal targeting sequence at its C terminus (where (phi) is a large, hydrophobic residue). LMP-1 was found to be present from early embryonic stages through adulthood and to be predominantly localized at the periphery of a population of large, membrane-bound organelles, called granules, that are seen throughout the early embryo but in later stages are restricted to the cells of the intestine. Analysis of an LMP-1 deficient C. elegans mutant revealed that LMP-1 is not required for viability under laboratory conditions, but the absence of LMP-1 leads to an alteration in intestinal granule populations, with apparent loss of one type of granule.

Utilization of the indirect lysosome targeting pathway by lysosome-associated membrane proteins (LAMPs) is influenced largely by the C-terminal residue of their GYXXphi targeting signals.

A systematic study was conducted on the requirements at the C-terminal position for the targeting of LAMPs to lysosomes, examining the hypothesis that a bulky hydrophobic residue is required. Mutations deleting or replacing the C-terminal valine with G, A, C, L, I, M, K, F, Y, or W were constructed in a reporter protein consisting of the lumenal/extracellular domain of avian LAMP-1 fused to the transmembrane and cytoplasmic domains of LAMP-2b. The steady-state distribution of each mutant form in mouse L-cells was assessed by quantitative antibody binding assays and immunofluorescence microscopy; efficiency of internalization from the plasma membrane and delivery to the lysosome were also estimated. It is found that (a) only C-terminal V, L, I, M, and F mediated efficient targeting to lysosomes, demonstrating the importance hydrophobicity and an optimal size of the C-terminal residue in targeting; (b) efficiency of lysosomal targeting generally correlated with efficiency of internalization; and (c) mutant forms that did not target well to lysosomes showed unique distributions in cells rather than simply default accumulation in the plasma membrane. Interactions of the targeting signals with adaptor subunits were measured using a yeast two-hybrid assay. The results are consistent with the hypothesis that trafficking of LAMP forms in cells through the indirect pathway is determined by the affinities of their targeting signals, predominantly for the mu2 and mu3 adaptors involved at plasma membrane and endosomal cellular sorting sites, respectively.

Expression of the avian Na,K-ATPase subunits in Dictyostelium discoideum.

This study explored whether Dictyostelium discoideum can be used to express the avian Na,K-ATPase, a heterodimeric membrane protein. Dictyostelium was able to express mRNAs encoding the avian Na, K-ATPase subunits. However, Dictyostelium expressed avian Na, K-ATPase protein when only when a Dictyostelium consensus ribosomal binding sequence, AAAATAAA, was inserted in front of the open reading frames of the alpha1- and beta1-subunit cDNAs and the first eight codons following the start-translation codons were changed to Dictyostelium preferred codons. These modified mRNAs appeared to be much less stable than the forms that were not readily translated. Dictyostelium could express the avian beta-subunit alone but only expressed the alpha1-subunit when the beta1-subunit was co-expressed. Subunit assembly occurred in cells expressing both alpha1- and beta1-subunits. The bulk of the exogenously expressed sodium pump subunits remained in an intracellular compartment, presumed to be the endoplasmic reticulum. Dictyostelium exported little or no Na, K-ATPase or free beta-subunit to the plasma membrane.

Different steady state subcellular distributions of the three splice variants of lysosome-associated membrane protein LAMP-2 are determined largely by the COOH-terminal amino acid residue.

The extensively glycosylated lysosome-associated membrane proteins (LAMP)-2a, b, and c are derived from a single gene by alternative splicing that produces proteins with differences in the transmembrane and cytosolic domains. The lysosomal targeting signals reside in the cytosolic domain of these proteins. LAMPs are not restricted to lysosomes but can also be found in endosomes and at the cell surface. We investigated the subcellular distribution of chimeras comprised of the lumenal domain of avian LAMP-1 and the alternatively spliced domains of avian LAMP-2. Chimeras with the LAMP-2c cytosolic domain showed predominantly lysosomal distribution, while higher levels of chimeras with the LAMP-2a or b cytosolic domain were present at the cell surface. The increase in cell surface expression was due to differences in the recognition of the targeting signals and not saturation of intracellular trafficking machinery. Site-directed mutagenesis defined the COOH-terminal residue of the cytosolic tail as critical in governing the distributions of LAMP-2a, b, and c between intracellular compartments and the cell surface.

Subunit interactions in the Na,K-ATPase explored with the yeast two-hybrid system.

Subunit interactions of the alpha1- and beta1-subunits of the chicken Na,K-ATPase were explored with the yeast two-hybrid system. Gal4-fusion proteins containing domains of the alpha1- and beta1-subunits were designed for examining both intersubunit and intrasubunit protein-protein interactions. Regions of the alpha- and beta-subunits known to be involved in alpha-beta-subunit assembly were positive in two-hybrid assay, supporting the validity of the assays. A library of beta-subunit ectodomains with C-terminal truncations was screened to find the maximal truncation retaining an interaction with the alpha-subunit extracellular H7H8 loop (where H7 refers to the seventh membrane span, and so on). The maximal truncation removed all the cysteines involved in disulfide bridges, leaving only 63 amino acids of the beta-subunit ectodomain. Scanning alanine mutagenesis led to identification of an evolutionarily conserved sequence of four amino acids (SYGQ) in the extracellular H7H8 loop of the alpha-subunit that is crucial to alpha-beta-intersubunit interactions. Oligomerization studies with single domains failed to detect self-association of either of the two large cytosolic loops (H2H3 and H4H5) within the alpha-subunit. However, evidence was found for an interaction between these two cytoplasmic loops.

The Drosophila Na,K-ATPase alpha-subunit gene: gene structure, promoter function and analysis of a cold-sensitive recessive-lethal mutation.

The Drosophila Na,K-ATPase (or sodium pump) alpha-subunit gene was found to contain 10 exons and span approx. 25 kb. Two nearly adjacent transcriptional initiation sites were identified, and the 2085-nucleotide sequence upstream of the first transcriptional start was analysed for promoter activity in transfected Drosophila SL2 cells. This region was found to contain many cis-acting elements that influence promoter activity, including elements that confer 2- to 3-fold higher activity in SL2 cells cultured at 30 degrees C versus 22 degrees C. Temperature-sensitive transcriptional regulation of the Na,K-ATPase alpha-subunit in Drosophila is a plausible mechanistic candidate for the factor driving temperature-dependent up-regulation of the Na,K-ATPase alpha-subunit described here for fly strains homozygous for single P-element insertions in the alpha-subunit gene. Four new P-element insertion strains were identified in this study, each insertion site lying within the first intron of the Na,K-ATPase alpha-subunit gene. The insertion in strain 0462 resulted in cold-sensitive recessive lethality; flies homozygous for the 0462 mutation could be rescued by growth at 29-30 degrees C, a condition that partially corrected a deficiency in the level of Na,K-ATPase alpha-subunit. The high-temperature rescue of homozygous 0462 flies appeared to result primarily from improved Na,K-ATPase expression rather than an increase in the rate of ion transport per Na,K-ATPase molecule. These observations point to a role for sodium-pump activity in determining the range of temperature tolerance in Drosophila and demonstrate that relatively subtle changes in sodium-pump expression can have major consequences in whole organisms.

Carboxy-terminal regions of the sarcoplasmic/endoplasmic reticulum Ca(2+)- and the Na+/K(+)-ATPases control their K+ sensitivity.

The Na+,K(+)-ATPase and the sarcoplasmic/endoplasmic reticulum Ca(2+)-(SERCA-) ATPase belong to a family of P-type ATPases that undergo a cycle of conformational changes between the phosphorylated and dephosphorylated stages in an ion-specific manner. The ouabain-inhibitable Na+,K(+)-ATPase activity requires Na+ and K+. On the other hand, the Ca(2+)-dependent and thapsigargin-inhibitable activity of the SERCA-ATPase does not depend upon Na+ and K+ for its basal activity. However, the SERCA-ATPase and Ca(2+)-transport activities can be further activated either by K+ in a two-step fashion with high (ED50 approximately 20 mM) and low affinity (ED50 approximately 70 mM) or by Na+ in a one-step fashion with an ED50 value of approximately 50 mM. A chimera, in which the carboxy-terminal region (Leu861-COOH) of the Na+,K(+)-ATPase alpha 1 subunit replaced the corresponding region (Ser830-COOH) of the SERCA1-ATPase, lacked the low-affinity K+ activation of the SERCA-ATPase but displayed a higher-affinity (ED50 < 10 mM) activation by K+, similar to that of the Na+,K(+)-ATPase, whereas activation by Na+ was not affected. The replacement of the large cytosolic loop (Gly354-Lys712) and the amino-terminal regions (Met1-Asp162) of the SERCA1-ATPase with the corresponding portions of the Na+,K(+)-ATPase alpha 1 subunit did not affect the sensitivity of the SERCA-ATPase activity to K+. Thus, the carboxy-terminal regions of both the SERCA1 and the Na+,K(+)-ATPase alpha 1 subunit are critical for K+ sensitivity. Analysis of additional (Ca2+/Na+,K+)-ATPase chimeras demonstrated that the carboxy-terminal 102 amino acids (Phe920-Tyr1021) of the Na+/K(+)-ATPase alpha 1 subunit are sufficient to shift the K+ affinity for activation of the SERCA-ATPase without the beta subunit. No change in the two-step activation of SERCA-ATPase by K+ was seen when residues Thr871-Thr898 of the SERCA1-ATPase were replaced with residues Asn894-Ala919 of the Na+,K(+)-ATPase alpha 1 subunit, a region known to bind the Na+,K(+)-ATPase beta subunit [Lemas, M. V., et al. (1994) J. Biol. Chem. 269, 8255-8259]. Thus, the Na+,K(+)-ATPase subunit-assembly domain and the K(+)-sensitive region are distinct within the carboxy-terminal 161 amino acids of the Na+,K(+)-ATPase.

Negative transcriptional regulation of the chicken Na+/K(+)-ATPase alpha 1-subunit gene.

Although the Na+/K(+)-ATPase alpha 1-subunit gene is ubiquitously expressed in vertebrates, its level of expression varies among tissue and cell types. In spite of similar mRNA distribution in tissues of mammals and birds, the 5'-flanking regions of alpha 1-subunit genes exhibit remarkable diversity; i.e., the core promoter activity of the TATA-less chicken alpha 1 gene strongly depends upon multiple Sp1-based regulation (six Sp1 sites), whereas the promoter activity of the TATA-like rat alpha 1-subunit gene relies on the two Sp1 and additional positive regulatory factors. Further analysis of the regulatory regions of the Na+/K(+)-ATPase alpha 1-subunit genes revealed that the vertebrate alpha 1-subunit genes may share common inhibitory mechanisms for subtle transcriptional regulation; the core promoter activities can be either enhanced or repressed depending on the availability of inhibitory factors. Two potential candidates for such inhibitory elements in both avian and mammalian Na+/K(+)-ATPase alpha 1-subunit genes are (1) a newly identified element, GCCCTC, and (2) a GCF-binding sequence, NN[G/c]CG[G/c][G/c][G/c]CN, or its reverse complement. Gel retardation assays using the inhibitory region of the chicken gene and crude nuclear extracts from tissue-cultured chicken and mouse cells showed the existence of a set of proteins that bind to this region. The amounts of individual regulatory proteins in different cell types seem to vary, resulting in differential formation of DNA/protein complexes in different cell types. Thus, the regulation of Na+/K(+)-ATPase alpha 1-subunit gene expression under different cellular environment as well as in different cell types can be achieved by a shared mechanism; modulation of the ratio of the abundance of individual inhibitory factors.

Movement of Ca(2+)-ATPase molecules within the sarcoplasmic/endoplasmic reticulum in skeletal muscle.

The endoplasmic reticulum undergoes rapid, microscopic changes in its structure, including extension and anastomosis of tubular elements. Such dynamism is expected to manifest itself also as rapid intermixing of membrane components, at least within subdomains of the endoplasmic reticulum. Here we present evidence of a similar dynamism in the sarcoplasmic reticulum of developing skeletal muscle. The sarcoplasmic reticulum is sometimes considered a specialized type of endoplasmic reticulum, but it appears to be a rather static set of membrane-bound elements, repetitively arranged to enwrap each sarcomere of each myofibril. Both endoplasmic reticulum and sarcoplasmic reticulum contain P-type Ca(2+)-ATPases that transport calcium from the cytosol into their lumen. In the experiments reported here, chicken and mouse cells were fused by polyethylene glycol, natural myogenic cell fusion, or Sendai virus. The redistribution of Ca(2+)-ATPase molecules between chick and mouse endoplasmic reticulum/sarcoplasmic reticulum was followed by immunofluorescence microscopy in which species-specific monoclonal antibodies to chick and mouse Ca(2+)-ATPases were used. Redistribution was time- and temperature-dependent but independent of protein synthesis as well as the method of cell fusion. Intermixing occurred on a time scale of tens of minutes at 37 degrees C. These results verify the dynamic nature of the sarcoplasmic reticulum and illustrate an aspect of the special relationship between endoplasmic reticulum and sarcoplasmic reticulum.

Mutations in the Caenorhabditis elegans Na,K-ATPase alpha-subunit gene, eat-6, disrupt excitable cell function.

We have cloned a Na,K-ATPase alpha-subunit gene from Caenorhabditis elegans and discovered that it is identical to the gene eat-6, eat-6 mutations cause feeble contractions and slow, delayed relaxations of pharyngeal muscle. The resting membrane potential of eat-6 mutant pharynxes is consistently depolarized compared to wild-type. The action potentials are smaller, and the return to resting potential is slower. To explain these abnormalities, we propose that a reduction of Na,K-ATPase activity in eat-6 mutants leads to a reduction of the ion concentration gradients that power membrane potential changes.

The family of LAMP-2 proteins arises by alternative splicing from a single gene: characterization of the avian LAMP-2 gene and identification of mammalian homologs of LAMP-2b and LAMP-2c.

The two lysosome-associated membrane proteins, LAMP-1 and LAMP-2, are major integral membrane proteins of the lysosomes. They also occur in the plasma membrane, where they have been discovered independently as principal lactosaminoglycan-bearing glycoproteins and as tumor antigens. Avian LAMP-2 has recently been shown to be encoded by at least three transcripts resulting in variant transmembrane and cytoplasmic domains (Hatem et al., 1995). We report isolation and characterization of chicken genomic clones indicating that the three transcripts are the result of alternative splicing of a single LAMP-2 gene. Only a single LAMP-2, homologous to chicken LAMP-2a, has been described in mammals. To ascertain whether multiple forms of LAMP-2 also occur in mammals, we cloned cDNAs encoding LAMP-2 variants homologous to avian LAMP-2b and LAMP-2c from mouse brain cDNA libraries. Thus, the family of LAMP-2 proteins is conserved from bird to mammals and the diversity is generated by alternative splicing of a single LAMP-2 gene.

Multiple mRNAs encode the avian lysosomal membrane protein LAMP-2, resulting in alternative transmembrane and cytoplasmic domains.

Lysosomal membranes are enriched in extensively glycosylated transmembrane proteins, LAMP-1 and LAMP-2. LAMP-1 proteins have been characterized from several mammalian species and from chickens, but no non-mammalian homologues of LAMP-2 have been described, and no splice variants of either protein have been reported. Here we report the characterization of three cDNA clones encoding chicken LAMP-2. The nucleotide sequences of the cDNAs diverge at their 3' ends within the open reading frame, resulting in sequences that code for three different transmembrane and cytoplasmic domains. Southern analysis suggests that a single gene encodes the common region of chicken LAMP-2. The position of the divergence and the identity of the common sequence are consistent with alternative splicing of 3' exons. Analysis of the mRNAs present in adult chicken tissues suggests tissue-specific expression of the three chicken LAMP-2 variants, with LAMP-2b expressed primarily in the brain. The cytoplasmic domain of LAMP-type proteins contains the targeting signal for directing these molecules to the lysosome. Using chimeras consisting of the lumenal domain of chicken LEP100 (a LAMP-1) and the transmembrane and cytoplasmic domains of the LAMP-2 variants, we demonstrate in transfected mouse L cells that all three LAMP-2 carboxyl-terminal regions are capable of targeting the chimeric proteins to lysosomes. Levels of expression, subcellular distribution, and glycosylation of the LAMP proteins have all been shown to change with differentiation in mammalian cells and to be correlated with metastatic potential in certain tumor cell lines. Alternative splicing of the LAMP-2 transcript may play a role in these changes.

Assembly of Na,K-ATPase alpha-subunit isoforms with Na,K-ATPase beta-subunit isoforms and H,K-ATPase beta-subunit.

cDNA encoding an epitope tag was joined to cDNAs encoding the chicken Na,K-ATPase beta 1 and beta 2 and H,K-ATPase beta-subunits to allow recognition of these beta-subunits with the same monoclonal antibody during assembly assays. cDNAs encoding chicken Na,K-ATPase alpha 1, alpha 2, or alpha 3 and Na,K-ATPase beta 1 or beta 2 or H,K-ATPase beta-subunits were transiently coexpressed in mammalian cells. Subunit assembly was assayed by immune precipitation of alpha-isoforms with a monoclonal antibody to the epitope-tagged beta-subunits. Each of the chicken alpha-isoforms assembled with each of the Na,K-ATPase beta-subunits and the H,K-ATPase beta-subunit. Each of the epitope-tagged beta-subunits also assembled with a Na,K-ATPase/Ca-ATPase chimera that retained only 26 amino acids of the Na,K-ATPase alpha-subunit, demonstrating that all three beta-subunits recognize this same alpha-subunit assembly site.

26 amino acids of an extracellular domain of the Na,K-ATPase alpha-subunit are sufficient for assembly with the Na,K-ATPase beta-subunit.

Chimeric cDNAs encoding a sarcoplasmic/endoplasmic reticulum Ca-ATPase (SERCA1) and regions of the Na,K-ATPase alpha-subunit were constructed to seek the minimal region of the alpha-subunit sufficient for assembly with the Na,K-ATPase beta-subunit. cDNAs encoding a chimera and the chicken beta-subunit were coexpressed in mammalian cells and assembly was assayed by immune precipitation of the chimeric subunit with a monoclonal antibody to the chicken beta-subunit. A chimera containing 26 amino acyl residues of the Na,K-ATPase alpha 1-subunit (NDVEDSYGQQWTFEQRKIVEFTCHTA) (Asn894 to Ala919) that replaced the corresponding avian SERCA1 Ca-ATPase amino acyl residues (Thr871 to Thr898) was able to assemble with the chicken beta-subunit. This alpha-subunit region is predicted to be extracellular, located between membrane-spanning domains 7 and 8 (H7-H8). Chimeras that assembled with full-length beta-subunit also assembled with a beta-subunit chimera that retained only the ectodomain of the chicken beta 1-subunit. These results suggest that the Na,K-ATPase alpha-subunit has the same topology in the membrane as the sarcoplasmic reticulum Ca-ATPase, probably with 10 membrane-spanning domains, and that the aminoacyl residues between membrane domains H7 and H8 are involved in assembly with the beta-subunit in the extracellular/lumenal space.

Analysis of subunit assembly of the Na-K-ATPase.

The Na-K-ATPase, or sodium pump, is comprised of two subunits, alpha and beta. Each subunit spans the lipid bilayer of the cell membrane. This review summarizes our efforts to determine how the two subunits interact to form the functional ion transporter. Our major approach has been to observe the potential for subunit assembly when one or both subunits are truncated or present as chimeras that retain only a limited region of the Na-K-ATPase. DNAs encoding these altered subunit forms of the avian Na-K-ATPase are expressed in mammalian cells. Monoclonal antibodies specific for the avian beta-subunit are then used to purify newly synthesized avian beta-subunits, and the presence of accompanying alpha-subunits indicates that subunit assembly has occurred. The ectodomain of the beta-subunit (approximately residues 62-304) is sufficient for assembly with the alpha-subunit, and a COOH-terminal truncation of the beta-subunit that lacks aminoacyl residues beyond 162 will assemble inefficiently. A maximum of 26 aminoacyl residues of the alpha-subunit are necessary for robust assembly with the beta-subunit, when this sequence replaces the COOH-terminal half of the loop between membrane spans 7 and 8 in the SERCA1 Ca-ATPase. This region of the Ca-ATPase faces the lumen of the endoplasmic reticulum. These findings encourage study of other related questions, including whether there is preferential assembly of certain subunit isoforms and how various P-type ATPases are targeted to their appropriate subcellular compartments.

A mutation of the Drosophila sodium pump alpha subunit gene results in bang-sensitive paralysis.

A bang-sensitive enhancer trap line was isolated in a behavioral screen. The flies show a weak bang-sensitive paralysis, recovering after about 7 s. The P element insert is localized at 93B1-2 on the salivary chromosomes, the site of the (Na+,K+)ATPase alpha subunit gene. Molecular characterization demonstrates that the transposon is inserted into the first intron of this gene. This insertion leads to normal-sized transcripts, but reduced levels of expression. This change is also reflected in lower amounts of a normal-sized alpha subunit protein. Mutant flies show a much greater sensitivity to ouabain, likewise indicating, on a functional level, a reduction in Na+ pump activity. Furthermore, the bang-sensitive behavior can also be mimicked by injecting sublethal doses of ouabain into wild-type flies. The molecular and functional evidence indicates that the insertion has produced a hypomorphic mutation of the (Na+,K+)ATPase alpha subunit gene, opening the way to future studies of the regulation of the Na+ pump.

Intramolecular fusion of Na pump subunits assures exclusive assembly of the fused alpha and beta subunit domains into a functional enzyme in cells also expressing endogenous Na pump subunits.

Experiments designed to identify Na pump structural features which tag the molecule for asymmetric cell-surface localization are inherently complex because either subunit, or both, may contain targeting information and because the cells which recognize those targeting signals and maintain asymmetric plasma membrane domains also express their own Na pumps, the subunits of which can assemble into hybrid pump molecules with pump subunits expressed from transfected cDNA clones. Cotransfecting cDNA for both subunits only complicates matters further by resulting in expression of four distinct dimeric molecular species. To eliminate the potential for cross-assembly in these and other experiments we have constructed cDNA encoding a "single-subunit" Na pump (called "alpha-beta") in which the alpha and beta subunits are joined by a linker of 17 amino acids. By all criteria tested alpha-beta functioned as a normal heterodimeric Na pump. It was expressed in a variety of mammalian cell lines as a single, high molecular weight polypeptide located primarily on the surface membrane, with the beta subunit exposed to the extracellular medium. Binding of the conformation-sensitive monoclonal antibody 24 to the beta subunit indicated that the fusion protein was folded as a properly "assembled" sodium pump. Expression of alpha-beta in ouabain-resistant mouse L cells resulted in high affinity ouabain binding and ouabain-sensitive, sodium-dependent rubidium transport. The enzyme was properly targeted to the basolateral plasma membrane in polarized epithelial cells. The functional integrity of the fusion protein renders it suitable for site-directed mutagenesis studies of targeting and enzymology where control of subunit assembly is desired. These results also support topological models in which the carboxyl terminus of the alpha subunit is cytoplasmic.

Assembly of the extracellular domain of the Na,K-ATPase beta subunit with the alpha subunit. Analysis of beta subunit chimeras and carboxyl-terminal deletions.

The role of the extracellular domain of the Na,K-ATPase beta subunit in assembly with the alpha subunit was investigated. A chimeric protein consisting of the extracellular domain of the beta subunit fused with the transmembrane and cytoplasmic domains of dipeptidyl peptidase IV assembles with the alpha subunit. An inverse chimera consisting of the cytoplasmic and transmembrane domains of the beta subunit fused with the extracellular domain of dipeptidyl peptidase IV does not assemble with the alpha subunit. The assembly data from these chimeras demonstrate that the extracellular domain of the beta subunit is both necessary and sufficient for assembly with the alpha subunit. Deletions of up to 146 extracellular amino acids from the carboxyl terminus of the beta subunit appear to result in misfolding of the subunit, but do allow reduced assembly with the alpha subunit. Together, the assembly data from chimeras and carboxyl-terminal deletions have identified a 96-residue extracellular domain which contains sequences involved in subunit assembly. While the chimeric subunits properly localize to the plasma membrane, deletion of as few as 4 amino acids from the carboxyl terminus impairs the ability of the beta subunit to be transported to the plasma membrane.