Palmitylation, sulfation, and glycosylation of the alpha subunit of the sodium channel. Role of post-translational modifications in channel assembly

Antibodies to the alpha and beta 2 subunits and site-directed antibodies that distinguish alpha subunits of the RI and RII subtypes have been used to study the biosynthesis and assembly of sodium channels. The RII sodium channel subtype is preferentially expressed in rat brain neurons in primary cell culture. Post-translational processing of alpha subunits includes incorporation of palmityl residues in thioester linkage and sulfate residues attached to oligosaccharides. The incorporation of [3H] palmitate into alpha subunits is inhibited by tunicamycin, indicating that it occurs in the early stages of biosynthesis but after co-translational glycosylation. Mature alpha subunits are attached to beta 2 subunits through disulfide bonds within 1 h after synthesis and up to 30% can be specifically immunoprecipitated from the cell surface with antibodies against the beta 2 subunits by 4 h after synthesis. The remaining alpha subunits remain in an intracellular pool. The alpha subunits synthesized in the presence of castanospermine and swainsonine have reduced apparent size. Castanospermine prevents incorporation of approximately 81% of the sialic acid of the alpha subunit and inhibits sulfation but not palmitylation. Although inhibition of glycosylation with tunicamycin blocks assembly of functional sodium channels, castanospermine and swainsonine do not prevent the covalent assembly of alpha and beta 2 subunits or the transport of alpha beta 2 complexes to the cell surface, and sodium channels synthesized under these conditions have normal affinity for saxitoxin. Thus, the extensive processing and terminal sialylation of oligosaccharide chains during maturation of the alpha subunit is not essential. A kinetic model for biosynthesis, processing, and assembly of sodium channel subunits is presented.     

Type VI collagen is composed of a 200 kd subunit and two 140 kd subunits.

We have isolated type VI collagen, a transformation-sensitive glycoprotein of the extracellular matrix, in an intact, disulfide-bonded form. The protein contains a 200 kd subunit and two different 140 kd subunits in a stoichiometric ratio. Based on the amount of hydroxyproline and hydroxylysine, the sensitivity to bacterial collagenase and the cross-reactivity with antibodies to pepsin-extracted type VI collagen, we have identified the 200 kd subunit as the alpha 3(VI) chain and the two 140 kd subunits as the alpha 1(VI) and alpha 2(VI) chains. The alpha 3(VI) chain is synthesized by cells in culture as a precursor of 260 kd, while no precursor form of the other two chains could be detected.     

Intracellular processing of apolipoprotein J precursor to the mature heterodimer.

Circulating apolipoprotein J (apoJ) is a 70 kDa glycoprotein comprised of disulfide-linked alpha and beta subunits derived from a single precursor. Post-translational modifications that occur prior to apoJ secretion were assessed, with specific focus on carbohydrate type, the timing of proteolytic cleavage, and the importance of glycosylation on the cleavage and secretion processes. ApoJ was initially resolved as a single chain, intracellular precursor of 58 kDa which contained N-linked oligosaccharide but no O-linked oligosaccharide. The precursor was converted to an intracellular 70 kDa glycoprotein, which became the major intracellular form of apoJ prior to secretion. Maturation of the 58 kDa precursor involved conversion of high-mannose carbohydrate to complex-type carbohydrate containing sialic acid, as well as intracellular cleavage to yield alpha and beta subunits. This cleavage event occurred at a late stage of carbohydrate modification, most likely in the trans-Golgi or a post-Golgi compartment. The maturation and secretion of apoJ occurred rapidly, with a half-time of 30-35 min. Tunicamycin treatment of cells resulted in an unglycosylated doublet comprised of one single chain and one cleaved form of apoJ. The unglycosylated apoJ species were secreted rapidly with a half-time of 20 min. Both cleavage and secretion were independent of glycosylation.     

Location of the inter-chain disulfide bonds of the third component of human complement

Location of the disulfide bonds connecting three polypeptide chains (alpha 3, 27kd; 2, 43kd; beta, 75kd) of C3c has been investigated by partial reduction with cysteine followed by alkylation with 14C-monoiodoacetic acid. Treatment of C3c with cysteine produced a partially reduced fragment, composed of disulfide-linked beta and alpha 3 chains. A single thiol residue was detected on the alpha 3 chain but not on the beta chain of the fragment, suggesting that the alpha 2 chain in C3c is linked through a single disulfide bond to the alpha 3 chain but not to the beta chain.     

Beta 2 subunits of sodium channels from vertebrate brain. Studies with subunit-specific antibodies

The sodium channel purified from rat brain is composed of three subunits: alpha (Mr 260,000), beta 1 (Mr 36,000), and beta 2 (Mr 33,000). alpha and beta 2 subunits are linked through disulfide bonds. Procedures are described for preparative isolation of the beta 1 and beta 2 subunits under native conditions. Pure beta 2 subunits obtained by this procedure were used to prepare a specific anti-beta 2 subunit antiserum. Antibodies purified from this serum by antigen affinity chromatography recognize only disulfide-linked alpha beta 2 complexes and beta 2 subunits in immunoblots, and immunoprecipitate 32P-labeled alpha subunits of purified sodium channels having intact disulfide bonds, but not those of sodium channels from which beta 2 subunits have been detached by reduction of disulfide bonds. These antibodies also immunoprecipitate 89% of the high affinity saxitoxin-binding sites from rat brain membranes, indicating that nearly all sodium channels in rat brain have disulfide-linked alpha beta 2 subunits. Approximately 22% of beta 2 subunits in adult rat brain are not disulfide-linked to alpha subunits. Anti-beta 2 subunit antibodies are specific for sodium channels in the central nervous system and will not cross-react with sodium channels in skeletal muscle or sciatic nerve. The brains of a broad range of vertebrate species, including electric eel, are shown to express sodium channels with disulfide-linked alpha beta 2 subunits.     

Biosynthesis and processing of murine T-cell antigen receptor

The antigen-specific receptor of C6VL T-lymphoma cells is a disulfide-linked heterodimer composed of 39 kd alpha chain and a 41 kd beta chain, both of which exhibit charge microheterogeneity. Pulse-chase labeling experiments indicate that epitopes reactive with the anti-receptor xenoantiserum #8177 were detectable by 2 min, while the clonotypic epitope reactive with monoclonal antibody 124-40 was not detectable until 10 min. Digestion with endoglycosidases H and F revealed that both subunits have at least three N-linked oligosaccharide side chains. The deglycosylated alpha and beta subunits were 27 and 32 kd, respectively. These data suggest that the dimeric receptor is formed shortly after translation, followed by extensive glycosylation. Emergence of the C6VL clonotypic epitope, and perhaps the antigen binding site, may therefore be dependent on post-assembly events.     

Identification of the components of the murine T cell antigen receptor complex

In addition to the alpha and beta chains of the MHC class II restricted antigen receptor, monoclonal anti-receptor antibodies coprecipitate four polypeptides that appear to be noncovalently associated with the alpha-beta dimer of murine T cells. Included in the murine T cell antigen receptor complex are two glycoproteins of 25 kd (gamma) and 21 kd (delta) and two nonglycosylated polypeptides of 26 kd (epsilon) and 16 kd (zeta). The epsilon chain appears to possess an intrachain disulfide bond and zeta exists in the complex as a disulfide-linked homodimer. The delta chain is phosphorylated on a serine residue in response to T cell activation with antigen. In contrast, both delta and epsilon are phosphorylated in response to treatment of the T cells with phorbol 12-myristate 13-acetate. These polypeptides may play a role in the transduction of the signal(s) in T cell activation.     

The human T cell receptor: appearance in ontogeny and biochemical relationship of alpha and beta subunits on IL-2 dependent clones and T cell tumors

The human T cell receptor for antigen (Ti) has recently been identified on IL-2 dependent T cell clones as a 90 kd disulfide-linked heterodimer comprised of one 49-51 kd alpha (alpha) and one 43 kd beta (beta) chain. These subunits are noncovalently associated with a monomorphic 20-25 kd T3 molecule. Here, we produce monoclonal antibodies to a human tumor (REX) derived from an earlier stage of thymic differentiation in order to determine whether clonotypic structures are expressed and to define the ontogeny of Ti. The results of SDS-PAGE and peptide map analyses indicate that an homologous T3-associated heterodimer is synthesized and expressed by REX. This glycoprotein shares several peptides in common with clonotypic structures on an IL-2 dependent T cell clone. In addition, similar Ti related molecules appear during intrathymic ontogeny in parallel with surface T3 expression. The latter findings provide the structural basis for the immunological competence observed exclusively within the T3+ thymocyte compartment.     

Defective posttranslational processing activates the tyrosine kinase encoded by the MET proto-oncogene (hepatocyte growth factor receptor).

The MET proto-oncogene encodes a 190-kDa disulfide-linked heterodimeric receptor (p190 alpha beta) whose tyrosine kinase activity is triggered by the hepatocyte growth factor. The mature receptor is made of two subunits: an alpha chain of 50 kDa and a beta chain of 145 kDa, arising from proteolytic cleavage of a single-chain precursor of 170 kDa (pr170). In a colon carcinoma cell line (LoVo), the precursor is not cleaved and the Met protein is exposed at the cell surface as a single-chain polypeptide of 190 kDa (p190NC). The expression of the uncleaved Met protein is due to defective posttranslational processing, since in this cell line (i) the proteolytic cleavage site Lys-303-Arg-Lys-Lys-Arg-Ser-308 is present in the precursor, (ii) p190NC is sensitive to mild trypsin digestion of the cell surface, generating alpha and beta chains of the correct size, and (iii) the 205-kDa insulin receptor precursor is not cleaved as well. p190NC is a functional tyrosine kinase in vitro and is activated in vivo, as shown by constitutive autophosphorylation on tyrosine. The MET gene is neither amplified nor rearranged in LoVo cells. Overlapping cDNA clones selected from a library derived from LoVo mRNA were sequenced. No mutations were present in the MET-coding region. These data indicate that the tyrosine kinase encoded by the MET proto-oncogene can be activated as a consequence of a posttranslational defect.     

Hydrophobic properties of the beta 1 and beta 2 subunits of the rat brain sodium channel

Voltage-sensitive sodium channels purified from rat brain in functional form consist of a stoichiometric complex of three glycoprotein subunits, alpha of 260 kDa, beta 1 of 36 kDa, and beta 2 of 33 kDa. The alpha and beta 2 subunits are linked by disulfide bonds. The hydrophobic properties of these three subunits were examined by covalent labeling with the photoreactive hydrophobic probe 3-(trifluoromethyl)-3-(m-[125I]iodophenyl)diazirine [( 125I]TID) which labels transmembrane segments in integral membrane proteins. All three subunits of the sodium channel were labeled by [125I]TID when the purified protein was solubilized in mixed micelles of Triton X-100 and phosphatidylcholine (4:1). The half-time for photolabeling was approximately 7 min consistent with the half-time of 9 min for photolysis of TID under our conditions. Comparable amounts of TID per mg of protein were incorporated into each subunit. Purified sodium channels reconstituted in phosphatidylcholine vesicles were also labeled by TID with comparable incorporation per mg of protein into all three subunits. The efficiency of photolabeling of the three subunits was reduced from 39 to 44% by a 2-fold expansion of the hydrophobic phase of the reaction mixture but was unaffected by a 2-fold expansion of the aqueous phase, confirming that the photolabeling reaction took place in the lipid phase of the vesicle bilayer. The hydrophobic properties of the sodium channel subunits were examined further using phase separation in the nonionic detergent Triton X-114. Under conditions in which beta 1 is dissociated from alpha, the beta 1 subunit was preferentially extracted into the Triton X-114 phase, and the disulfide-linked alpha beta 2 complex was retained in the aqueous phase. When the disulfide bonds between the alpha and beta 2 subunits were reduced with dithioerythritol, the beta 2 subunit was also preferentially extracted into the Triton X-100 phase leaving the free alpha subunit in the aqueous phase. A preparative method for isolation of the beta 1 and beta 2 subunits was developed based on this technique. Considered together, the results of our hydrophobic labeling and phase separation experiments indicate that the alpha, beta 1, and beta 2 subunits all have substantial hydrophobic domains that may interact with the hydrocarbon phase of phospholipid bilayer membranes. Since the alpha subunit is known to be a transmembrane protein with many potential membrane-spanning segments, we conclude that the beta 1 and beta 2 subunits are likely to also be integral membrane proteins with one or more membrane-spanning segments.(ABSTRACT TRUNCATED AT 400 WORDS)     

The sodium channel from rat brain. Separation and characterization of subunits

Procedures are described for separation of the alpha, beta 1, and beta 2 subunits of the voltage-sensitive sodium channel from rat brain by gel filtration in sodium dodecyl sulfate (SDS) before and after reduction of intersubunit disulfide bonds or by preparative SDS-gel electrophoresis. Partial proteolytic maps of the SDS-denatured subunits indicate that they are nonidentical polypeptides. They are all heavily glycosylated and contain complex carbohydrate chains that bind wheat germ agglutinin. The apparent molecular weights of the separated subunits were estimated by gradient SDS-gel electrophoresis, by Ferguson analysis of migration in SDS gels of fixed acrylamide concentration, or by gel filtration in SDS or guanidine hydrochloride. For the alpha subunit, SDS-gel electrophoresis under various conditions gives an average Mr of 260,000. Gel filtration methods give anomalously low values. Removal of carbohydrate by sequential treatment with neuraminidase and endoglycosidase F results in a sharp protein band with apparent Mr = 220,000, suggesting that 15% of the mass of the native alpha subunit is carbohydrate. Electrophoretic and gel filtration methods yield consistent molecular weight estimates for the beta subunits. The average values are: beta 1, Mr = 36,000, and beta 2, Mr = 33,000. Deglycosylation by treatment with endoglycosidase F, trifluoromethanesulfonic acid, or HF yields sharp protein bands with apparent Mr = 23,000 and 21,000 for the beta 1 and beta 2 subunits, respectively, suggesting that 36% of the mass of the native beta 1 and beta 2 subunits is carbohydrate.     

Preferential assembly of epithelial sodium channel (ENaC) subunits in Xenopus oocytes: role of furin-mediated endogenous proteolysis

The epithelial sodium channel (ENaC) is preferentially assembled into heteromeric alphabetagamma complexes. The alpha and gamma (not beta) subunits undergo proteolytic cleavage by endogenous furin-like activity correlating with increased ENaC function. We identified full-length subunits and their fragments at the cell surface, as well as in the intracellular pool, for all homo- and heteromeric combinations (alpha, beta, gamma, alphabeta, alphagamma, betagamma, and alphabetagamma). We assayed corresponding channel function as amiloride-sensitive sodium transport (I(Na)). We varied furin-mediated proteolysis by mutating the P1 site in alpha and/or gamma subunit furin consensus cleavage sites (alpha(mut) and gamma(mut)). Our findings were as follows. (i) The beta subunit alone is not transported to the cell surface nor cleaved upon assembly with the alpha and/or gamma subunits. (ii) The alpha subunit alone (or in combination with beta and/or gamma) is efficiently transported to the cell surface; a surface-expressed 65-kDa alpha ENaC fragment is undetected in alpha(mut)betagamma, and I(Na) is decreased by 60%. (iii) The gamma subunit alone does not appear at the cell surface; gamma co-expressed with alpha reaches the surface but is not detectably cleaved; and gamma in alphabetagamma complexes appears mainly as a 76-kDa species in the surface pool. Although basal I(Na) of alphabetagamma(mut) was similar to alphabetagamma, gamma(mut) was not detectably cleaved at the cell surface. Thus, furin-mediated cleavage is not essential for participation of alpha and gamma in alphabetagamma heteromers. Basal I(Na) is reduced by preventing furin-mediated cleavage of the alpha, but not gamma, subunits. Residual current in the absence of furin-mediated proteolysis may be due to non-furin endogenous proteases.     

Subunit structure and localization of dihydropyridine-sensitive calcium channels in mammalian brain, spinal cord, and retina

Monoclonal antibodies that recognize the alpha 2 delta subunits of calcium channels from skeletal muscle immunoprecipitate a complex of alpha 1, alpha 2 delta, beta, and gamma subunits. They also immunoprecipitate 64% of rabbit brain dihydropyridine-sensitive calcium channels followed by immunoprecipitation reveals alpha 1-, alpha 2 delta-, and beta-like subunits that have apparent molecular masses of 175, 142, and 57 kd, respectively. A polypeptide of 100 kd is also specifically immunoprecipitated. Immunocytochemical studies identify dihydropyridine-sensitive calcium channels in neuronal somata and proximal dendrites in rat brain, spinal cord, and retina. Staining of many neuronal somata is uneven, revealing relatively high densities of dihydropyridine-sensitive calcium channels at the base of major dendrites. L-type calcium channels in this location may serve to mediate long-lasting increases in intracellular calcium in the cell body in response to excitatory inputs to the dendrites.     

The Drosophila PS2 antigen is an invertebrate integrin that, like the fibronectin receptor, becomes localized to muscle attachments

We establish that the position-specific antigen 2 (PS2), a Drosophila cell surface glycoprotein complex, is an invertebrate member of the vertebrate fibronectin receptor (integrin) family. New monoclonal antibodies show that in Drosophila embryos and larvae PS2 alpha subunits have a size of ca. 140 kd. Analysis of cDNA and genomic clones revealed that the canonical PS2 alpha subunit contains 1394 amino acids and has extensive homology to the heavy and light chains of integrin alpha subunits. The distribution of the PS2 antigen is regulated at the level of PS2 alpha subunit mRNA. In early Drosophila development the protein is restricted to mesoderm and appears to be involved in muscle attachment. We suggest that PS2, like vertebrate fibronectin receptors, mediates changes in cell shape and cell-extracellular matrix adhesion by binding to a basement membrane protein.     

Antigen activation of murine T cells induces tyrosine phosphorylation of a polypeptide associated with the T cell antigen receptor

The antigen receptor complex on murine MHC class II-restricted T cells consists of disulfide-linked alpha and beta chains noncovalently associated with four additional polypeptides, two that are endoglycosaminidase F-sensitive, gp26 and gp21, and two that are endoglycosaminidase F-resistant, p25 and p16. We demonstrate here that treatment of murine T cell hybridomas with phorbol 12-myristate 13-acetate results in phosphorylation of p25 and gp21 on serine residues. However, activation of cells by antigen results in the phosphorylation of the gp21 chain and a heretofore unidentified 21 kd protein. This newly defined polypeptide, p21, is specifically immunoprecipitated with the antigen receptor complex, is endoglycosaminidase F-resistant, and is itself part of a disulfide-linked molecule. Unlike antigen-induced phosphorylation of gp21, which occurs on serine residues, phosphorylation of p21 occurs uniquely on tyrosine residues.     

Biosynthesis and processing of platelet GPIIb-IIIa in human megakaryocytes

Platelet membrane glycoprotein IIb-IIIa forms a calcium-dependent heterodimer and constitutes the fibrinogen receptor on stimulated platelets. GPIIb is a two-chain protein containing disulfide-linked alpha and beta subunits. GPIIIa is a single chain protein. These proteins are synthesized in the bone marrow by megakaryocytes, but the study of their synthesis has been hampered by the difficulty in obtaining enriched population of megakaryocytes in large numbers. To examine the biosynthesis and processing of GPIIb-IIIa, purified human megakaryocytes were isolated from liquid cultures of cryopreserved leukocytes stem cell concentrates from patients with chronic myelogenous leukemia. Immunoprecipitation of [35S]methionine pulse-chase-labeled cell extracts by antibodies specific for the alpha or beta subunits of GPIIb indicated that GPIIb was derived from a precursor of Mr 130,000 that contains the alpha and beta subunits. This precursor was converted to GPIIb with a half-life of 4-5 h. No precursor form of GPIIIa was detected. The glycosylation of GPIIb-IIIa was examined in megakaryocytes by metabolic labeling in the presence of tunicamycin, monensin, or treatment with endoglycosidase H. The polypeptide backbones of the GPIIb and the GPIIIa have molecular masses of 120 and 90 kD, respectively. High-mannose oligosaccharides are added to these polypeptide backbones co-translationally. The GPIIb precursor is then processed with conversion of high-mannose to complex type carbohydrates yielding the mature subunits GPIIb alpha (Mr 116,000) and GPIIb beta (Mr 25,000). No posttranslational processing of GPIIIa was detected.     

Lysine 271 in the transmembrane domain of the T-cell antigen receptor beta chain is necessary for its assembly with the CD3 complex but not for alpha/beta dimerization

The T-cell antigen receptor (TcR) complex present on most T-cells is formed by a clone-specific disulfide-linked alpha/beta heterodimer noncovalently associated to the CD3 complex, the latter composed of five invariant polypeptides: gamma, delta, epsilon, zeta/zeta, or zeta/eta. The presence of conserved, oppositely charged, amino acids in the predicted transmembrane domains of all the subunits of the TcR.CD3 complex suggests that these residues may have a critical function in the assembly and/or stabilization of the complex. In order to analyze the role of the transmembrane-charged amino acids in the association and cell surface expression of the TcR.CD3 complex, we have carried out site-directed mutagenesis of Lys271 in the transmembrane domain of the TcR beta chain and analyzed the capacity of the altered chain to assemble in a TcR beta-negative T-cell line. Here we show that substitution of this positively charged residue by alanine or glutamine does not prevent cytoplasmic association of alpha and beta chains to form disulfide-linked heterodimers, but does abolish formation of an alpha/beta.CD3 complex and, consequently, its expression on the cell surface.     

A previously unrecognized subunit of the receptor for immunoglobulin E

Our laboratory previously found that under conditions that stabilized the interaction between the alpha and beta subunits of the receptor for immunoglobulin E, two new components were recovered having apparent molecular weights of 45 000 and 20 000, respectively. In this paper, we characterize the 20-kDa material. We demonstrate that it consists of a disulfide-linked dimer of 10-kDa polypeptides and that these have all the characteristics expected for subunits of the receptor. We propose that they be termed gamma chains and that the receptor consists of four chains: one alpha, one beta, and two gamma chains. The gamma chains share many of the labeling properties of the beta chain and, like the latter, are likely to be embedded in the plasma membrane and exposed on the internal but not the external surface of the bilayer.