Relation of the extra-sequence of the precursor form of chicken liver δ-aminolevulinate synthase to its quaternary structure and catalytic properties

Precursor and mature forms of δ-aminolevulinate (ALA) synthase were purified to near homogeneity from chicken liver mitochondria and cytosol, respectively, and their properties were compared. The enzyme purified from mitochondria had apparently the same subunit molecular weight (65,000) as that of the native mitochondrial enzyme. The enzyme purified from the cytosol fraction, however, showed a subunit molecular weight of about 71,000, which was somewhat smaller than that estimated for the native cytosolic enzyme (73,000). The enzyme purified from liver cytosol seems to have been partially degraded by some endogenous protease during the purification, but may have the major part of the signal sequence. On sucrose density gradient centrifugation, the purified mitochondrial and cytosolic ALA synthases showed an apparent molecular weight of about 140,000, indicating that both enzymes exist in a dimeric form. The ALA synthase synthesized in vitro was also shown to exist as a dimer. Apparently the extra-sequence does not interfere with the formation of dimeric form of the enzyme. The purified cytosolic ALA synthase had a specific activity comparable to that of the purified mitochondrial enzyme. Kinetic properties of the two enzymes, such as the pH optimum and the apparent K_m values for glycine and succinyl-CoA, were quite similar. The extra-sequence does not appear to affect the catalytic properties of ALA synthase. The isoelectric point of the cytosolic ALA synthase was 7.5, whereas that of the mitochondrial enzyme was 7.1. This suggests that the extra-sequence in the cytosolic enzyme may be relatively rich in basic amino acids.     

Regulation of production of delta-aminolaevulinate synthase in tissues of chick embryos. Effects of porphyrogenic agents and of haem precursors.

Studies conducted by several groups have established that porphyrogenic agents which caused elevations in chick-embryo liver delta-aminolaevulinate (ALA) synthase activity also increased the concentrations of the enzyme's RNA, and that haemin inhibited these elevations. We have determined in this study, using immune-blot analyses, that administration in ovo of allylisopropylacetamide (AIA) in combination with diethyl 1,4-dihydro-2,4,6-trimethyl,3,5-pyridinedicarboxylate (DDC) increased the mass of ALA synthase in intestine and kidney of chick embryos. Furthermore, the molecular mass of the subunit of the enzyme in those tissues appeared identical with that of liver ALA synthase. Using a synthetic oligonucleotide complementary to ALA synthase mRNA, we determined by solution hybridization and Northern-blot analyses that AIA and DDC also increased the concentrations of ALA synthase mRNA in intestine and kidney and that testosterone elevated the concentration of the RNA in kidney. In analyses of RNA obtained from chick-embryo liver, intestine, kidney, heart, brain and lung, the probe bound primarily in each case to a single 2.3 kb RNA. Finally, the haem precursors ALA and FeCl3, when injected together into the fluid surrounding embryos, inhibited both the elevations in ALA synthase mass and RNA concentration brought about by porphyrogenic agents in liver, kidney and intestine. Thus the results indicated that: (1) certain porphyrogenic agents increased ALA synthase mass and RNA in chick-embryo intestine and kidney, in addition to liver; (2) ALA and FeCl3 inhibited the elevations; and (3) the sizes of ALA synthase's subunit as well as the enzyme's mRNA appeared identical, in each case, in all tissues examined.     

The 1-aminocyclopropane-1-carboxylate synthase of Cucurbita. Purification, properties, expression in Escherichia coli, and primary structure determination by DNA sequence analysis

The key regulatory enzyme in the biosynthetic pathway of the plant hormone ethylene is 1-aminocyclopropane-1-carboxylic acid (ACC) synthase (EC 4.4.1.14). We have partially purified ACC synthase 6,000-fold from Cucurbita fruit tissue treated with indoleacetic acid + benzyladenine + aminooxyacetic acid + LiCl. The enzyme has a specific activity of 35,000 nmol/h/mg protein, a pH optimum of 9.5, an isoelectric point of 5.0, a Km of 17 microM with respect to S-adenosylmethionine, and is a dimer of two identical subunits of approximately 46,000 Da each. The subunit exists in vivo as a 55,000-Da species similar in size to the primary in vitro translation product. DNA sequence analysis of the cDNA clone pACC1 revealed that the coding region of the ACC synthase mRNA spans 493 amino acids corresponding to a 55,779-Da polypeptide; and expression of the coding sequence (pACC1) in Escherichia coli as a COOH terminus hybrid of beta-galactosidase or as a nonhybrid polypeptide catalyzed the conversion of S-adenosylmethionine to ACC (Sato, T., and Theologis, A. (1989) Proc. Natl. Acad. Sci. U.S.A. 86, 6621-6625). Immunoblotting experiments herein show that the molecular mass of the beta-galactosidase hybrid polypeptide is 170,000 Da, and the size of the largest nonhybrid polypeptide is 53,000 Da. The data suggest that the enzyme is post-translationally processed during protein purification.     

Studies on the mechanism of the conversion of cytosol δ-aminolevulinic acid synthase to the mitochondrial enzyme in the liver of the allylisopropylacetamide-treated rat

δ-Aminolevulinic acid (ALA) synthase was partially purified from liver cytosol fraction of rats treated with allylisopropylacetamide (AIA). The cytosol ALA synthase showed an apparent molecular weight of 320,000. The cytosol ALA synthase of this size dissociates into at least three protein components when subjected to sucrose density gradient centrifugation in the presence of 0.25 m NaCl: one is the catalytically active protein with an s value of about 6.4 or a molecular weight of 110,000, and the other two are catalytically inactive binding proteins showing s values of about 4 and 8, respectively. Recombination of the 6.4 S protein and the 4 S protein yielded a protein complex with an apparent molecular weight of 170,000 and recombination of all three protein components resulted in formation of the original cytosol ALA synthase. The cytosol ALA synthase also loses its binding proteins when treated with various proteases; thus, the enzyme-active protein obtained after papain digestion was very similar, if not identical, to mitochondrial ALA synthase. When treated with trypsin, however, the cytosol ALA synthase was converted to an enzyme showing an apparent molecular weight of 170,000, which probably represents the complex of the mitochondria-type enzyme and the 4 S binding protein. The cytosol ALA synthase tends to aggregate to form a dimer with an apparent molecular weight of 650,000–700,000. The aggregated form of the cytosol ALA synthase was less susceptible to trypsin digestion. Hemin strongly stimulated dimer formation of the cytosol ALA synthase and the aggregate produced by contact with hemin was very tight and did not easily dissociate into its respective protein components by sucrose gradient centrifugation or even after treatment with trypsin. The possible mechanisms of the conversion of cytosol ALA synthase to the mitochondrial enzyme and also of the inhibition by hemin of the intracellular translocation of ALA synthase are discussed.     

Identification of an Mr 77,000 - 80,000 product of in vitro translation of rat liver mRNA using antibody to glycogen synthase

Rabbit antibody to rat liver glycogen synthase has been used to identify a product of Mr 77,000 - 80,000 from in vitro translation of rat liver mRNA. A comparison of various protease inhibitors on the relative molecular weight of rat liver glycogen synthase suggest that higher molecular weight enzyme forms could arise from incomplete hydrolysis of glycogen before enzyme isolation and enzyme subunit Mr determinations.     

A detergent-independent procedure for the isolation of gap junctions from rat liver

In this paper, the isolation of rat liver gap junctions from alkali-extracted rat liver plasma membranes is described. The purification is significantly more rapid than the commonly used detergent-based approaches and is subject to less variability. The gap junctions isolated by this method are comprised of a 27,000-Da polypeptide previously identified as the major gap junction polypeptide. The isolated gap junctions have the characteristic double-membrane organization and subunit structure observed in vivo. The protein yield is from 8 to 10 micrograms/g of liver (wet weight), about a 10-fold increase in recovery over that of earlier isolation procedures. With the availability of increased amounts of material, antibodies were raised to the liver gap junction polypeptide. Immunofluorescence localization of these antibodies on rat liver sections revealed a distribution consistent with that expected from electron microscopic analysis of liver thin sections. Double diffusion of antibody against solubilized gap junctions in detergent-containing gels resulted in the formation of precipitin arcs, suggesting response to multiple determinants. Antibody binding to the 27,000-Da gap junction polypeptide was demonstrated by immunoblot analysis of sodium dodecyl sulfate-polyacrylamide gels containing rat liver plasma membranes and isolated gap junctions. These results confirm the identification of the 27,000-Da polypeptide as the major protein component of gap junctions.     

Expression of the trichodiene synthase gene of Fusarium sporotrichioides in Escherichia coli results in sesquiterpene production

Trichodiene synthase is a sesquiterpene cyclase involved in the biosynthesis of trichothecene mycotoxins. We report that insertion of the unaltered trichodiene synthase gene of Fusarium sporotrichioides into the Escherichia coli expression vector pDR540 produced an inactive polypeptide with a molecular weight approximately 2000 greater than that of trichodiene synthase. This result is consistent with the presence of an intron in the trichodiene synthase gene, and prompted us to specifically delete a putative 60-nucleotide intron sequence. Insertion of the intron-deleted open reading frame into pDR540 resulted in the production of active enzyme. Trichodiene synthase activity in crude extracts from induced cultures was 0.07 nmol/min/mg of protein and represented 0.05-0.10% of the total cell protein. A cross-reactive protein was present with the same apparent molecular weight as the subunit of native trichodiene synthase. The recombinant enzyme was partially purified and shown to have properties closely resembling those of the native enzyme. Trichodiene was detected in ethyl acetate extracts from induced cultures at a concentration of 60 micrograms/liter after 4.5 h. These findings support the primary structure recently reported for trichodiene synthase and demonstrate that the expression of a sesquiterpene cyclase in E. coli results in sesquiterpene production.     

Purification and characterization of the trifunctional beta-subunit of anthranilate synthase from Neurospora crassa

The trifunctional beta-subunit of anthranilate synthase complex of Neurospora crassa has been purified from a mutant which produces no detectable alpha-subunit. The isolated beta-subunit appeared to be a highly asymmetric dimer with a s20,w of 7.35 and an apparent molecular weight of 200,000 as determined by gel filtration on Sephacryl S-300 compared with a monomer molecular weight of approximately 84,000 Da as determined by sodium dodecyl sulfate-gel electrophoresis. The purified subunit was cleaved by elastase, trypsin, or chymotrypsin into fragments which retained the three enzyme activities. After elastase digestion, two active fragments were separated by gel filtration and ion exchange chromatography. A 30,000-Da fragment, which behaved as a monomer on gel filtration, interacted with free alpha-subunit to produce glutamine-dependent anthranilate synthase activity. A second 56,000-Da fragment, which behaved as an asymmetric dimer (apparent molecular weight 140,000) on gel filtration, retained both N-(5'-phosphoribosyl)anthranilate isomerase and indole-3-glycerol phosphate synthase activity. The failure to detect an NH2-terminal amino acid residue on either the intact beta-subunit or the 30,000-Da complementing fragment, while the 56,000-Da fragment possessed an NH2-terminal histidine residue, indicated that the complementing fragment was derived from the NH2-terminal sequence of the beta-subunit.     

delta-Aminolevulinate synthase isozymes in the liver and erythroid cells of chicken

Antibodies raised against the purified chicken liver delta-aminolevulinate synthase showed a partial cross-reactivity with the chicken erythroid delta-aminolevulinate synthase. delta-Aminolevulinate synthase synthesized in vitro using polysomes from erythroid cells showed a subunit molecular weight of 55,000, whereas the enzyme synthesized in vitro using liver polysomes had a subunit molecular weight of 73,000. delta-Aminolevulinate synthase isolated from mitochondria of erythroid cells showed a molecular weight of 53,000, while the enzyme in liver mitochondria had a value of 65,000. These observations imply that the erythroid delta-aminolevulinate synthase differs from the hepatic enzyme.     

Maturation of embryonic chick liver delta-aminolevulinate synthase: precursor pools and regulation by intra-cellularly produced heme

1. Immunoblot analyses were carried out to determine the relative distributions of delta-aminolevulinate synthase (ALA synthase) in mitochondrial and cytosol fractions prepared from embryos at different times after injections with allylisopropylacetamide (AIA). 2. The results indicated that the molecular mass of mature ALA synthase (Mr 65,000) increased with time in mitochondria. 3. At no time was the precursor form (Mr 75,000) of the enzyme detected either in mitochondria or in the cytosol. 4. In primary cultures of hepatocytes, where the increased production of ALA synthase had been induced with AIA, addition of delta-aminolevulinic acid (ALA) and Fe2(SO4)3 into the culture medium completely blocked the processing of the precursor form of the enzyme. 5. On the other hand, the addition of ALA together with deferoxamine mesylate into the medium had no detectable effect on the maturation of ALA synthase in the hepatocytes. 6. The results indicated: first, that upon induction of porphyria the pools of pre-ALA synthase in liver are relatively low in chick embryos when compared with those in other organisms; and second, that increased heme production by the hepatocytes caused the inhibition of processing of the precursor form of ALA synthase.     

Production of delta-aminolevulinate: subcellular localization and purification of murine hepatic L-alanine: 4,5-dioxovaleric acid aminotransferase

1. L-Alanine: 4,5-dioxovaleric acid aminotransferase (DOVA transaminase) activity was measured in murine liver, kidney and spleen homogenates. 2. Among the organs examined, the specific activity of the enzyme was highest in kidney, followed by liver then spleen. 3. No differences in DOVA transaminase activity in kidney, liver and spleen homogenates were detected between mouse strains C57BL/6J and DBA/2J. 4. Based on enzyme activity, the capacity of DOVA transaminase to catalyze the formation of delta-aminolevulinic acid (ALA) in liver appeared much greater than the capacity of ALA synthase. 5. In DBA/2J animals, DOVA transaminase activity in liver mitochondrial fractions prepared by differential centrifugation was 24 nmol ALA formed/hr/mg protein compared with 0.63 nmol ALA formed/hr/mg protein for ALA synthase. 6. Cell fractionation analyses indicated that liver DOVA transaminase is located in the mitochondrial matrix. 7. The liver enzyme was purified from mitoplasts by chromatography on DEAE-Sephacel followed by affinity chromatography on L-alanine-AH-Sepharose. 8. The specific activity of the purified DOVA transaminase was 1600 nmol ALA formed/hr/mg protein. 9. The yield of the purification was ca 90 micrograms of protein per gram liver wet weight. 10. The purified enzyme had a subunit mol. wt of 146,000 +/- 5000 as determined by electrophoresis under denaturing conditions.     

Characterization of chicken liver L-alanine:4,5-dioxovaleric acid aminotransferase

1. A procedure is described for purifying the enzyme L-alanine:4,5-dioxovaleric acid aminotransferase (DOVA transaminase) from chicken liver. The enzyme catalyzes a transamination reaction between L-alanine and 4,5-dioxovaleric acid (DOVA), yielding delta-aminolevulinic acid (ALA). 2. In cell fractionation studies, DOVA transaminase activities were detected in mitochondria and in the post-mitochondrial supernatant fraction from liver homogenates. 3. For the mitochondrial enzyme, any of most L-amino acids could serve as a source for the amino group transferred to DOVA, but L-alanine appeared the preferred substrate. At pH 7.0, the enzyme had an apparent Km of 60 microM for DOVA and of 400 microM for L-alanine. 4. The enzyme was purified from disrupted mitoplasts in three steps: chromatography on DEAE-Sephacel, gel filtration through Sephadex G-150, and chromatography on hydroxyapatite. The yield was approx. 100 micrograms of enzyme protein per 10 g wet wt of liver. 5. The purified enzyme had a subunit mol. wt of 63,000 as determined by gel electrophoresis under denaturing conditions. 6. The activity of DOVA transaminase was also measured in embryonic chicken liver, and based on activity, the enzyme's capacity to produce ALA was significantly greater than that of ALA synthase. Unlike ALA synthase, however, DOVA transaminase activity did not increase in liver mitochondria of chicken embryos exposed for 18 hr to two potent porphyrogenic agents.     

Acetyl-coenzyme-A carboxylase from rat liver. Subunit structure and proteolytic modification.

The subunit structure of rat liver acetyl-coenzyme-A carboxylase has been studied by polyacrylamide gel electrophoresis in the presence of dodecylsulfate. A number of individual preparations of the enzyme purified by the same procedures exhibited three different types of electrophoretic patterns as follows: first, a single slow-moving protein bands (Mr 230000); secondly, two adjacent fast-moving protein band (M4 124000 and 118 000); finally, all three protein bands. With the use of the [14C]biotin-labelled enzyme, the biotinyl prosthetic group was shown to be associated with the polypeptide of 230000 Mr as well as with that of 124000 Mr, but not with the polypeptide of 118000 Mr. Studies were next made with the labelled enzyme to examine the possibility that the two light polypeptides might have been formed by proteolytic modification of the heavy polypeptide during the procedures used for the purification of the enzyme. Treatment of the enzyme with trypsin or chymotrypsin resulted in cleavage of the heavy polypeptide into two nonidentical polypeptides with molecular weights of approximately 120000. Incubation of the enzyme with proteases derived from rat liver converted the heavy polypeptide into lighter polypeptides of 80000-130000 Mr. Acetyl-CoA carboxylase isolated from crude rat liver extracts by means of immunoprecipitation with specific antibody invariably showed only the heavy polypeptide. The biotin content of the enzyme was found to be 1 mol per 237000 g protein. These results indicate that rat liver acetyl-CoA carboxylase, unlike bacterial and plant biotin enzymes, has only one kind of subunit, which has a molecular weight of 230000 and contains one molecular of biotin. Thus, the mammalian enzyme exhibits a highly integrated subunit structure.     

Iduronate sulfatase from human placenta

The major enzyme component of iduronate sulfatase from human placenta was purified 30 000-fold by a five-step procedure. Sucrose gradient centrifugation of the native enzyme gave a molecular weight estimate of 80 000 +/- 10 000. Electrophoresis in sodium dodecyl sulfate of the enzyme reduced with mercaptoethanol showed a protein band of Mr 82 000. We suggest that the enzyme is composed of a single polypeptide chain of Mr 80 000-90 000.     

Casein kinase II of yeast contains two distinct alpha polypeptides and an unusually large beta subunit

Casein kinase II of yeast has been purified to near homogeneity by a procedure which includes affinity chromatography on heparin-agarose. The purified enzyme consists of four polypeptides with molecular weights of 42,000, 41,000, 35,000, and 32,000. The 42,000- and 35,000-Da polypeptides are immunologically related and exhibit cross-reactivity with the alpha subunits of calf and Drosophila casein kinase II. Amino-terminal sequencing reveals that the two subunits are distinct but homologous polypeptides and that both sequences share 40-50% homology with the Drosophila alpha subunit. These results demonstrate that yeast contains two distinct alpha subunits which must be encoded by separate genes. The 41,000- and 32,000-Da polypeptides both incorporate phosphate during autophosphorylation, a characteristic of the beta subunit in all type II casein kinases studied to date. The 41,000-Da subunit also exhibits immunological cross-reactivity with the beta subunit of Drosophila casein kinase II. These results identify the 41,000-Da polypeptide as an unusually large beta subunit. The possibility that the 32,000-Da polypeptide may be a beta' subunit is currently under investigation. The interpretation of the subunit structure of yeast casein kinase II reported here differs significantly from previous reports (Rigobello, M. P., Jori, E., Carignani, G., and Pinna, L. A. (1982) FEBS Lett. 144, 354-358; Kudlicki, W. N., Szyszka, R., and Gasior, E. (1984) Biochim. Biophys. Acta 784, 102-107).     

Limited proteolytic digestion and dissociation of smooth muscle phosphatase-I modifies its substrate specificity. Preparation and properties of different forms of smooth muscle phosphatase-I

Smooth muscle phosphatase-I (SMP-I), a protein phosphatase purified from turkey gizzard smooth muscle, is composed of 2 regulatory subunits (Mr = 60,000 and 55,000) and a catalytic subunit (Mr = 38,000). Two other forms of this enzyme have been prepared and characterized. The free catalytic subunit, termed SMP-Ic, was prepared by ethanol treatment of SMP-I, and a form devoid of the 55,000-Da subunit, termed SMP-I2, was prepared by limited tryptic digestion. Exposure of SMP-I to proteases like trypsin and chymotrypsin results in a rapid degradation of the 55,000-Da polypeptide. Degradation of the catalytic subunit is observed only upon prolonged digestion. The 60,000-Da polypeptide appears to be resistant to the action of trypsin and chymotrypsin. SMP-I dephosphorylates myosin light chains but is not active toward intact myosin or heavy meromyosin. However, when the catalytic subunit is dissociated from both regulatory subunits or from the 55,000-Da polypeptide, the enzyme becomes active toward myosin suggesting that the 55,000-Da polypeptide inhibits the activity of the catalytic subunit toward myosin. In addition to alteration of the substrate specificity, the regulatory subunits also modulate the effect of divalent cations, like Mn2+, on the activity of the enzyme.     

Conversion of a mitochondrial precursor polypeptide into subunit 1 of cytochrome oxidase in the mi-3 mutant of Neurospora crassa.

1. The cytochrome-alpha alpha 3-deficient mi-3 cytoplasmic mutant of Neurospora crassa synthesizes a mitochondrial translation product which crossreacts with antibodies specific to subunit 1 of cytochrome oxidase. The immunoprecipitated polypeptide migrates more slowly during gel electrophoresis than the authentic 41 000-Mr subunit 1 of the wild-type enzyme. An apparent molecular weight of about 45 000 was estimated for the mutant product. 2. Radioactive labelling experiments in vivo show that the crossreacting material found in the mutant is relatively stable and does not form complexes with other subunits of the oxidase. 3. After induction of a functional cytochrome oxidase in the mutant cells with antimycin A, the 45 000-Mr polypeptide is converted to a 41 000-Mr component, which exhibits the same electrophoretic mobility as subunit 1 of the oxidase. Pulse-chase labelling kinetics reveal a typical precursor product relationship. 4. The converted polypeptide becomes assembled with other enzyme subunits to form a protein complex which has the immunological characteristics of cytochrome oxidase. A possible physiological role of the post-translational processing of the mitochondrially synthesized component is discussed.     

Isolation of a functional transferase component from the rat fatty acid synthase by limited trypsinization of the subunit monomer. Formation of a stable functional complex between transferase and acyl carrier protein domains

Limited trypsinization of rat fatty acid synthase monomers results in cleavage at sites protected in the native dimer. A 47,000-Da polypeptide containing the transferase component was isolated from the digest and its location in the multifunctional polypeptide established. Both acetyl and malonyl moieties are transferred stoichiometrically from CoA ester to this polypeptide and each can replace the other, confirming that a single common site is utilized in the loading of these substrates onto the fatty acid synthase. Transferase activity of the 47,000-Da polypeptide decreases with increasing acyl donor chain length (malonyl = acetyl greater than butyryl greater than hexanoyl greater than octanoyl). Activity is inhibited by certain thiol-directed reagents, and protection is afforded by substrate suggesting the presence of a sensitive cysteine residue near the substrate binding site. The transferase was also able to utilize as acyl acceptor the Escherichia coli acyl carrier protein and the acyl carrier protein domain of the multifunctional fatty acid synthase. When the fatty acid synthase monomer was trypsinized under milder conditions, the 47,000-Da transferase domain could be isolated in association with the 8,000-Da acyl carrier protein domain. The transferase was capable of translocating substrate moieties from CoA ester donors to the associated acyl carrier protein. The results provide the first direct evidence that, in the head-to-tail oriented fatty acid synthase homodimer, functional communication between the transferase domain located near the end of one polypeptide and the acyl carrier protein domain located at the opposite end of the other polypeptide is facilitated by a stable physical interaction between these domains.     

Characterization of the 1,4-dihydropyridine receptor using subunit-specific polyclonal antibodies. Evidence for a 32,000-Da subunit

The purified receptor for the 1,4-dihydropyridine Ca2+ channel blockers from rabbit skeletal muscle contains protein components of 170,000 Da (alpha 1), 175,000 Da (alpha 2), 52,000 Da (beta), and 32,000 Da (gamma) when analyzed by sodium dodecyl sulfate-polyacrylamide gel electrophoresis under nonreducing conditions. Subunit-specific polyclonal antibodies have now been prepared and used to characterize the association of the 32,000-Da polypeptide (gamma subunit) with other subunits of the dihydropyridine receptor. Immunoblot analysis of fractions collected during purification of the dihydropyridine receptor shows that the 32,000-Da polypeptide copurified with alpha 1 and alpha 2 subunits at each step of the purification. In addition, monoclonal antibodies against the alpha 1 and beta subunits immunoprecipitate the digitonin-solubilized dihydropyridine receptor as a multisubunit complex which includes the 32,000-Da polypeptide. Polyclonal antibodies generated against both the nonreduced and reduced forms of the alpha 2 subunit and the gamma subunit have been used to show that the 32,000-Da polypeptide is not a proteolytic fragment of a larger component of the dihydropyridine receptor and not disulfide linked to the alpha 2 subunit. In addition, polyclonal antibodies against the rabbit skeletal muscle 32,000-Da polypeptide specifically react with similar proteins in skeletal muscle of other species including avian and amphibian species. Thus, our results demonstrate that the 32,000-Da polypeptide (gamma subunit) is an integral and distinct component of the dihydropyridine receptor.     

Biochemical and ultrastructural characterization of the 1,4-dihydropyridine receptor from rabbit skeletal muscle. Evidence for a 52,000 Da subunit

The 1,4-dihydropyridine receptor purified from rabbit skeletal muscle contains four polypeptide components of 175,000 Da (nonreduced)/150,000 Da (reduced), 170,000, 52,000, and 32,000 Da (Leung, A. T., Imagawa, T., and Campbell, K. P. (1987) J. Biol. Chem. 262, 7943-7946). A monoclonal antibody specific to the 52,000-Da polypeptide component of the dihydropyridine receptor has been produced and used in immunoprecipitation and immunoblotting experiments to demonstrate that the 52,000-Da polypeptide is an integral subunit of the purified dihydropyridine receptor. Peptide mapping experiments with 32P-labeled dihydropyridine receptor have also demonstrated that the 52,000-Da polypeptide is distinct from and not a proteolytic fragment of the 170,000-Da subunit. Densitometric scanning of Coomassie Blue-stained sodium dodecyl sulfate-polyacrylamide gels of the purified dihydropyridine receptor has demonstrated that the 52,000-Da polypeptide exists in a 1:1 stoichiometric ratio with the 170,000-, 175,000/150,000-, and 32,000-Da subunits of the dihydropyridine receptor. Electron microscopy of the freeze-dried, rotary-shadowed dihydropyridine receptor has shown that the preparation contains a homogeneous population of 16 x 22-nm ovoidal particles large enough to contain all four polypeptides of the dihydropyridine receptor. The particles have two distinct components of similar size which may represent the location in the molecule of the two larger subunits.