Transport and processing of endogenously synthesized ApoE on the macrophage cell surface

We have previously established the presence of a pool of apoE sequestered on the macrophage cell surface by demonstrating its displacement from a cell monolayer at 4 degrees C. In this series of experiments, we use a cell surface biotinylation protocol to directly quantitate apoE on the macrophage cell surface and evaluate its transport to and from this cell surface pool. In human monocyte-derived macrophages labeled to equilibrium and in a mouse macrophage cell line transfected to constitutively express human apoE3, approximately 8% of total cellular apoE was present on the surface, but only a portion of this surface pool served as a direct precursor to secreted apoE. The half-life of apoE on the macrophage cell surface was calculated to be approximately 12 min. On SDS-polyacrylamide gel electrophoresis, the apoE isolated from the surface fraction of cells labeled to equilibrium migrated in an isoform pattern distinct from that observed from the intracellular fraction, with the surface fraction migrating predominantly in a higher molecular weight isoform. Pulse labeling experiments demonstrated that newly synthesized apoE reached the cell surface by 10 min but was predominantly in a low molecular weight isoform. There was also a lag between appearance of apoE on the cell surface and its appearance in the medium. Biotinylated apoE, which accumulated in the medium, even from pulse labeled cells, was predominantly in the high molecular weight isoform. Additional experiments demonstrated that low molecular weight apoE present on the cell surface was modified to higher molecular weight apoE by the addition of sialic acid residues prior to secretion and that this conversion was inhibited by brefeldin A. These results demonstrate an unexpected complexity in the transport and cellular processing of macrophage cell surface apoE. Factors that modulate the size and turnover of the cell surface pool of apoE in the macrophage remain to be identified and investigated.     

Blood group A and B glycosyltransferases synthesize A and B determinants on different acceptor polyglycosyl peptidesin vitro

The glycosylation of polyglycosyl chains from human erythrocytes by human plasma blood group A and B glycosyltransferases was studied in order to clarify why human blood group AB erythrocyte polyglycosyl peptides carry only either A or B determinants [Eur J Biochem (1981) 113:259–65].The blood group A transferase was able to add radioactiveN-acetylgalactosamine from labeled UDP-N-acetylgalactosamine to B-type erythrocytes which had been treated with -galactosidase in order to cleave the B determinant sugar from the erythrocytes. This suggests that the enzymes specified by theA andB genes utilize the same acceptor molecules on erythrocyte membranes. Polyglycosyl peptides isolated from blood group B erythrocytes acted as acceptors for blood group A glycosyltransferase and the generation of hybrid structures containing both A and B determinants was demon-strated. When blood group O polyglycosyl peptides were used as acceptors in the simultaneous presence of both blood group A and B glycosyltransferases, however, the A and B determinant sugars were found in different polyglycosyl peptides. It is suggested that the enzyme-acceptor complex does not dissociate until the final number of determinants has been added.     

ADP-ribosylation of microtubule proteins as catalyzed by cholera toxin

Incubation of purified rat brain tubulin with cholera toxin and radiolabeled [32P] or [8-3H]NAD results in the labeling of both alpha and beta subunits as revealed on sodium dodecyl sulfate polyacrylamide gel electrophoresis (SDS-PAGE). Treatment of these protein bands with snake venom phosphodiesterase resulted in quantitative release of labeled 5'-AMP, respectively labeled with the corresponding isotope. Two-dimensional separation by isoelectric focusing and SDS-PAGE of labeled and native tubulin revealed that labeling occurs at least in four different isotubulins. The isoelectric point of the labeled isotubulins was slightly lower than that of native purified tubulin. This shift in mobility is probably due to additional negative charges involved with the incorporation of ADP-ribosyl residues into the tubulin subunits. SDS-PAGE of peptides derived from [32P]ADP-ribosylated alpha and beta tubulin subunits by Staphylococcus aureus protease cleavage showed a peptide pattern identical with that of native tubulin. Microtubule-associated proteins (MAP1 and MAP2) of high molecular weight were also shown to undergo ADP-ribosylation. Incubation of permeated rat neuroblastoma cells in the presence of [32P]NAD and cholera toxin results in the labeling of only a few cell proteins of which tubulin is one of the major substrates.     

Photoaffinity labeling of the insulin receptor in H4 hepatoma cells: Lack of cellular receptor processing

Photoaffinity labeling techniques were used to identify insulin-binding components of the plasma membrane in insulin-responsive, monolayer-cultured hepatoma cells. The activated, photosensitive reagent, an n-hydroxysuccinimide ester of 4-azidobenzoic acid, was coupled with highly purifed insulin, and the hormone derivative was subsequently iodinated, bound to cell surface receptors of intact H4 cells, and photoactivatcd. After dissolution of the cells, labeled proteins were analyzed by SDS/polyacrylamide gel electrophoresis under reducing conditions. The main labeled band exhibited an apparent molecular weight of 130,000. Two minor components of apparent mol wt 95,000 and 40,000 were also identified. Specific labeling of all 3 bands was inhibited by simultaneous incubation of the cells with native insulin, but not by the heterologous hormone, glucagon, prior to photoactivation. Binding of azidobenzoyl-insulin to H4 cells was time-dependent, as was the correlated labeling of receptor components. Band-labeling by the photosensitive insulin derivative was totally light-dependent; spontaneous covalent linking of insulin and receptor was not observed. The labeled receptor-related proteins were not degraded by the cells under our experimental conditions.     

Specificity of an Antiserum Produced Against Pseudomicrothorax dubius Trichocysts Prepared by a Rapid Isolation Method

ABSTRACT. A rapid method was developed for the isolation of Pseudomicrothorax dubius ciliary and trichocyst fractions which were characterized by SDS-PAGE followed by combined silver and Coomassie blue staining. Antibodies were prepared against the trichocyst fraction and employed to label Lowicryl thin sections of cells. Trichocysts were strongly labeled, as were the surfaces of the plasma and ciliary membranes. Immunoblots of the trichocyst fraction revealed labeling of major bands at 16–29 kD, characteristic of the trichocyst proteins. On immunoblots of the ciliary fraction, approximately eight bands were labeled, including the major cell surface glycoprotein, the immobilization antigen. Ciliary proteins not located on the membrane surface, such as the tubulins, were not labeled. Absorption of the antiserum against fixed P. dubius cells eliminated the cell surface labeling on Lowicryl sections and on immunoblots of the ciliary fraction. The major trichocyst protein bands were as strongly labeled as with the nonabsorbed antiserum. Labeling of several of the minor, higher molecular weight bands of the trichocyst fraction was eliminated, indicating that they are cell surface contaminants. Of the two major structural components of the trichocyst, the shaft and the arms, the antiserum is shown to react nearly exclusively with the shaft proteins on both Lowicryl sections and immunoblots.     

Blood group A and H determinants in polyglycosyl peptides of A1 and A2 erythrocytes

Polyglycosyl peptides were isolated from delipidated erythrocyte membranes of human blood-group A1 and A2 erythrocytes by extensive pronase digestion and gel filtration. As estimated by the amounts of N-acetylgalactosamine and 2-O-substituted galactose residues about 85% of the possible acceptor sites (H determinants) were saturated with A determinants in A1 polyglycosyl peptides whereas only 25% of H sites were filled in A2 glycopeptides. The distribution of A and H determinants in the glycopeptides was studied by affinity chromatography with Sepharose-bound Bandeiraea simplicifolia I-lectin (binds blood-group A and B determinants) and Ulex Europeaus I-lectin (binds blood-group H determinants). About 55% of the polyglycosyl peptides contained A, H, or A and H determinants in both A1 and A2 blood subgroups. 48% of the polyglycosyl peptides of blood group A1 and 10% of A2 bound to Bs I-lectin. 25% of the polyglycosyl peptides in A1 and 53% in A2 carried H determinants. The molecular size, monosaccharide composition and the substitution pattern of the monosaccharides in the Bs-I-bound polyglycosyl peptides were very similar in both A1 and A2 blood groups. The only difference was the amount of N-acetylgalactosamine which was on the average 3.7 mol/mol in A1 and 2.5 mol/mol in A2. The active fraction was found to be heterogeneous with respect to the amount of A determinants, which varied from 1 to 6 per glycopeptide in A1 and A2 polyglycosyl peptides. The findings do not indicate a structural difference between blood-group A1 and A2 polyglycosyl peptides and state chemically that A1 glycopeptides contain more A determinants than A2 glycopeptides.     

Phosphorylation of Okazaki-like DNA fragments in mammalian cells and role of polyamines in the processing of this DNA.

In mammalian cells DNA synthesis is more complicated than in prokaryotes and less well understood. Here we incubated intact mammalian cells (polyamine auxotrophic Chinese hamster ovary cells and primary human fibroblasts) with [32P]orthophosphate and found that, besides high molecular weight DNA, a species of low molecular weight DNA, approximately 450 bp in size, became efficiently labeled. The short DNA was labeled first, and in pulse-chase experiments the labeling was transient. The isolated small DNA fragments (RNase A-treated) were phosphorylated by T4 polynucleotide kinase specific for polynucleotides with 5'-OH ends. A polynucleotide kinase phosphorylating these DNA pieces was also detected in nuclear extracts of the cells. Treatment with alkaline phosphatase removed most of the 32P label incorporated into the small DNA in vivo. Labeling with deoxyribonucleosides did not reveal these fragments. We hypothesize that the low molecular weight DNA represents Okazaki fragments and that the mammalian DNA replication machinery includes a polynucleotide kinase phosphorylating the 5'-termini of Okazaki fragments. This would imply a novel step in DNA synthesis. We also show that depriving cells of polyamines reversibly blocks synthesis of high molecular weight DNA and leads to accumulation of the short DNA pieces, suggesting a role for polyamines in joining the Okazaki fragments.     

Inhibition of soluble yeast mitochondria ATPase by ethidium-bromide.

Surface galactosyl residues of alive embryonal carcinoma cells were tritium-labeled by the galactose oxidase NaB(3H)4 method. The labeled glycopeptides isolated from Pronase digests of the cells, were found to be similar to those prepared from endogeneously labeled embryonal carcinoma cells. They consisted mostly of high molecular weight material, and contained receptors for peanut agglutinin. It is concluded that at least a fraction of the high molecular weight glycopeptides characteristic of early embryonic cells, is displayed on the cell suface.     

External membrane proteins of rabbit lung macrophages

Externally disposed polypeptides of rabbit lung macrophages were labeled using chloramine-T. Optimal conditions, chosen as those which maximized the incorporation of ¹²⁵I without inhibiting phagocytosis of C3-opsonized lipopolysaccharide oil particles, were found to be dependent on concentrations of carrier iodide, chloramine-T, and the cells themselves. These macrophages inhibit the labeling reaction owing to an apparent abundance of surface sulfhydryl groups which preferentially become oxidized before labeling can occur. Analyzed on polyacrylamide gel electrophoresis, whole macrophages displayed major bands of radioactivity whose apparent molecular weights were: 317,000, 245,000, 186,000, 143,000, and 104,000 daltons. All bands were completely removed by trypsin treatment except a large band of 10,000–15,000 daltons which was removed by lipid solvent extraction and diminished by β-mercaptoethanol treatment of whole labeled cells. No label comigrated with actin at 42,000 daltons or with either of the two major proteins found in the lung lavage fluid. Very similar bands were found in podosomes, peripheral hyaline blebs of plasma membrane, prepared from whole labeled cells.     

Identification of a novel serum protein secreted by lung carcinoma cells

The murine anti-human lung tumor monoclonal antibody L3 recognizes antigens found both in the medium of cultured carcinoma cells and in normal human serum. Sequential immunoprecipitation experiments indicate that the L3 antigen is also recognized by a previously described monoclonal antibody directed against a melanoma-associated antigen [Natali, P. G., Wilson, B. S., Imai, K., Bigotti, A., & Ferrone, S. (1982) Cancer Res. 42, 583-589]. This antibody precipitated a Mr 76000 glycoprotein from metabolically labeled extracts of the lung carcinoma cell line Calu-1 and a Mr 94 000 glycoprotein from labeled culture medium. Pulse-chase experiments suggested a precursor-product relationship between these molecules. Analysis of glycosidase sensitivities of the two forms indicated that maturation of carbohydrate side chains correlated with the apparent increase in molecular weights. L3 antigenic activity, measured in a competitive radiometric cell binding assay, was purified more than 90-fold from serum-free medium of Calu-1 cells and more than 3000-fold from normal human serum. The major immunoreactive components purified from culture medium and serum were identical with respect to apparent molecular weight, electrophoretic mobility, pI, glycosidase sensitivity, and V8 protease fingerprints. In addition, the sequence of the amino-terminal 16 N-terminal amino acid residues of the major immunoreactive species from both sources was identical. The properties of the L3 antigen did not correspond to those of any known protein, suggesting that this serum protein has not been previously characterized.     

Products of rat liver mitochondrial protein synthesis: electrophoretic analysis of the number and size of these proteins and their solubility in chloroform: methanol

Rat liver mitochondria were incubated in vitro with radioactive leucine, and submitochondrial particles prepared by several methods. Analysis of the labeled mitochondrial membrane fractions by sodium dodecylsulfate gel electrophoresis revealed three labeled bands of molecular weights corresponding to 40,000; 27,000; and 20,000 daltons. Electrophoresis for longer times at higher concentrations of acrylamide revealed eight labeled bands, ranging in molecular weights from 48,000 to 12,000.Mitochondria were incubated for 5 min with [³H]leucine followed by a chase of unlabeled leucine. Gel electrophoresis of the membranes obtained after labeling for 5 min indicated significant synthesis of polypeptides in the 40,000 M_r, range and very little labeling of low molecular-weight polypeptides. After addition of the chase, increased synthesis of the high molecular-weight polypeptides was observed; however, no significant increase or decrease of radioactivity in the bands of low molecular-weight was observed, suggesting that rat liver mitochondria have the ability to synthesize complete proteins in the M_r 27,000–40,000 range.Approximately 16% of the total leucine incorporated into protein by isolated rat liver mitochondria in vitro could be extracted by chloroform: methanol. Gel electrophoresis of the chloroform: methanol extract revealed several bands containing radioactivity with the majority of counts in a band of 40,000 molecular weight. Gel electrophoresis of the chloroform: methanol extract of lyophilized submitochondrial particles indicated label in two broad bands in the low molecular-weight region of 14,000-10,000 with insignificant counts in the higher molecular-weight regions of the gel.Yeast cells were pulse labeled in vivo with [³H]leucine in the presence of cycloheximide and the submitochondrial particles extracted with chloroform:methanol. The extract separated after gel electrophoresis into four labeled bands ranging in molecular weight from 52,000 to 10,000. Preincubation of the yeast cells with chloramphenicol prior to the pulse labeling caused a 6-fold stimulation of labeling into the band of lowest molecular weight of the chloroform: methanol extract. These results suggest that the accumulation of mitochondrial proteins synthesized in the cytoplasm, when chloramphenicol is present in the medium, may stimulate the synthesis of certain specific mitochondrial proteins which are soluble in chloroform: methanol.     

Topography of Chlamydomonas: fine structure and polypeptide components of the gametic flagellar membrane surface and the cell wall

Surface polypeptide components of the flagellar membrane of Chlamydomonas reinhardi Dang. gametes are identified by their accessibility to in-vivo vectoral labeling by glucose oxidase-coupled lactoperoxidase-dependent ¹²⁵I iodination. Vectoral labeling is accomplished without observable adverse effects on cell viability or gametic function. Flagella isolated from labeled wild-type cells carry about 3% of the total incorporated label, which is found by one-dimensional sodium dodecyl sulfate-polyacrylamide gel electrophoresis to be distributed among 16 identifiable polypeptide bands. The most prominent surface-labeled species migrates in the M_r (relative molecular weight) 350 k region of the gel; each of the remaining iodinated polypeptides, which range in M_r from 25 k to 500 k, carries only a small proportion of incorporated label. To determine which polypeptides are unique to the flagellum and which are contaminants from the cell wall, wild-type profiles were compared with those of mutant strains and of mechanically isolated cell walls. Identification of contaminants was also facilitated by two-dimensional peptide mapping. We conclude that only 11 of the labeled bands are contributed by flagellar polypeptides; the remaining five bands are shown to be contaminants from the cell wall, and additional cell-wall polypeptides are found to co-migrate with flagellar species. A polypeptide designated as a possible membrane tubulin in preliminary studies is shown here to be different from tubulin in its peptide map. The 11 polypeptides assigned as specific flagellar surface components are candidate participants in such biological events as sexual adhesion, flagellar surface motility, and sensory signalling.     

Synthesis of sulfated oligosaccharides by cystic fibrosis trachea epithelial cells

The mucin glycoproteins in tracheal mucus of patients with cystic fibrosis is more highly sulfated than the corresponding secretions from healthy individuals [16]. In order to further characterize these differences in sulfation and possibly also glycosylation patterns, we compared the structures of sulfated mucin oligosaccharides synthesized by continuously cultured human tracheal cells transformed by siman virus 40. The synthesis of highly sulfated oligosaccharide chains in mucins secreted by normal human epithelial and submucosal cell lines were compared with mucins formed by cystic fibrosis tracheal epithelial and submucosal cell lines.The epithelial cell lines from cystic fibrosis trachea showed a higher rate of sulfate uptake and a significantly higher rate of synthesis and sulfation of high molecular weight chains. Mucins synthesized by each cell line in the presence of ³⁵SO₄ were isolated and oligosaccharide chains were released by beta-elimination and separated by ion exchange chromatography and gel filtration. The sulfated high molecular weight chains synthesized by the cystic fibrosis cell lines were characterized by methylation analysis and sequential glycosidase digestion before and after desulfation. Carbohydrate analysis yielded Fuc, Gal and GlcNAc in a ratio of 1:2:2.2 and only one galactosaminitol residue for about every 150-200 sugar residues present. The average molecular size of oligosaccharide chains in these fractions was between 30,000-40,000 daltons.These studies show that increased sulfation of oligosaccharides in mucins synthesized by cells from cystic fibrosis trachea is accompanied by a significant increase in the extension of a basic branched structure present in many of the lower molecular weight oligosaccharides.     

Biosynthetic analysis of the human interferon-gamma receptor. Identification of N-linked glycosylation intermediates

Biosynthesis of the human IFN gamma receptor was studied using metabolic labeling techniques and immunoprecipitation with receptor-specific monoclonal antibodies. Colo-205 and HepG2 cells labeled with [35S]methionine gave rise to two components with molecular mass 75 and 90 kDa following sodium dodecyl sulfate-polyacrylamide gel electrophoresis. No bands were detected when immunoprecipitation was performed using irrelevant monoclonal IgG or in the presence of excess ligand, a condition known to block antibody-receptor interaction. When Colo-205 were labeled for increasing periods of time, the 75-kDa form was detected after 5 min, whereas the 90-kDa form appeared only after 60 min. Pulse-chase analysis established that the 75-kDa form was the precursor of the 90-kDa component. Only the 90-kDa form was detected on extrinsically radioiodinated Colo-205 cell surfaces. This observation was confirmed by Western blot analysis of isolated Colo-205 membranes. Digestion of labeled precipitates with peptide:N-glycosidase F caused a 22% reduction in the apparent molecular weight of the IFN gamma receptor. Receptor derived from tunicamycin-treated Colo-205 labeled for 5 min displayed a single molecular mass of 65 kDa and expressed ligand binding activity. Longer labeling periods in the presence of tunicamycin revealed the appearance of a second ligand-binding form of 70 kDa. Thus, Colo-205 IFN gamma receptors carry asparagine (N)-linked oligosaccharides and possibly some other form of post-translational modification.     

Expression of external-surface membrane proteins in differentiated and undifferentiated mouse neuroblastoma cells.

Murine neuroblastoma cultures were labeled externally with the cationic reagent N,N,N-[3H]-trimethylamino-beta-alanyl-N-hydroxy-succinimide ester ([3H]Me3N-beta Ala-NSuc) or with 125I/lactoperoxidase. The cells were labeled in the logarithmic and confluent growth phases as well as in a highly differentiated state following treatment with 2% dimethylsulfoxide. The labeled exterior membrane proteins were analyzed by sodium dodecyl sulfate/polyacrylamide gel electrophoresis. Major changes in the exterior membrane proteins were observed during maturation and differentiation of the cells. Most of these changes were clonal-specific, while others were common to several clones. Two proteins of Mr 55,000 and 65,000 were labeled by both 125I/lactoperoxidase and Me3N-[3H]-beta Ala-NSuc. The level of labeling was dependent on the clonal lines used and the state of the cell maturation. A group of proteins displaying a molecular weight between 150,000 and 200,000 was found to be related to the transition of a culture from logarithmic to confluent growth phases. An additional protein, with an apparent molecular weight of 95,000, was common to differentiated cells of the two inducible clones used. In general the maturation of logarithmic phase cells into confluent cells resulted in a less complex electrophoretic distribution of the pattern of labeling. After dimethyl-sulfoxide treatment, further reduction in the complexity of the externally labeled proteins was observed.     

S gene product: identification and membrane localization of a lysis control protein.

The product of the bacteriophage S gene has been previously shown to be required for an essential step in triggering host cell lysis. By using two different protein labeling systems, maxicells and UV-irradiated infected cells, we identified the S gene product as an 8,500-molecular-weight polypeptide associated with the cell envelope. The apparent molecular weight is significantly less than the 11,500 predicted from the S gene sequence. We were unable to confirm two previous identifications of S gene products, an acidic 15,000-molecular-weight polypeptide found by two-dimensional gel electrophoresis of infected cells and a 5,500-molecular-weight polypeptide in purified phage particles.     

Efficient labeling of mesenchymal stem cells using cell permeable magnetic nanoparticles

For the purpose of successfully monitoring labeled cells, optimum labeling efficiency without any side effect is a prerequisite. Magnetic cellular imaging is a new and growing field that allows the visualization of implanted cells in vivo. Herein, superparamagnetic iron oxide (SPIO) nanoparticles were conjugated with a non-toxic protein transduction domain (PTD), identified by the authors and termed low molecular weight protamine (LMWP), to generate efficient and non-toxic cell labeling tools. The cells labeled with LMWP-SPIO presented the highest iron content compared to those labeled with naked SPIO and the complex of SPIO with poly-l-lysine, which is currently used as a transfection agent. In addition to the iron content assay, Prussian staining and confocal observation demonstrated the highest intracellular LMWP-SPIO presence, and the labeling procedure did not alter the cell differentiation capacity of mesenchymal stem cells. Taken together, cell permeable magnetic nanoparticles conjugated with LMWP can be suggested as labeling tools for efficient magnetic imaging of transplanted cells.     

Proteoglycan synthesis by primary chick skeletal muscle during in vitro myogenesis

The proteoglycans synthesized by primary chick skeletal muscle during in vitro myogenesis were compared with those of muscle-specific fibroblasts. Cultures of skeletal muscle cells and muscle fibroblasts were separately labeled using [35S] sulfate as a precursor. The proteoglycans of the cell layer and medium were separately extracted and isolated by ion-exchange chromatography on DEAE-Sephacel followed by gel filtration chromatography on Sepharose CL-2B. Two cell layer-associated proteoglycans synthesized both by skeletal muscle cells and muscle fibroblasts were identified. The first, a high molecular weight proteoglycan, eluted from Sepharose CL-2B with a Kav of 0.07 and contained exclusively chondroitin sulfate chains with an average molecular weight greater than 50,000. The second, a relatively smaller proteoglycan, eluted from Sepharose CL-2B with a Kav of 0.61 and contained primarily heparan sulfate chains with an average molecular weight of 16,000. Two labeled proteoglycans were also found in the medium of both skeletal muscle and muscle fibroblasts. A high molecular weight proteoglycan was found with virtually identical properties to that of the high molecular weight chondroitin sulfate proteoglycan of the cell layer. A second, smaller proteoglycan had a similar monomer size (Kav of 0.63) to the cell layer heparan sulfate proteoglycan, but differed from it in that this molecule contained primarily chondroitin sulfate chains with an average molecular weight of 32,000. Studies on the distribution of these proteoglycans in muscle cells during in vitro myogenesis demonstrated that a parallel increase in the relative amounts of the smaller proteoglycans occurred in both the cell layer and medium compared to the large chondroitin sulfate proteoglycan in each compartment. In contrast, muscle-derived fibroblasts displayed a constant ratio of the small proteoglycans of the cell layer and medium fractions, compared to the larger chondroitin sulfate proteoglycan of the respective fraction as a function of cell density. Our results support the concept that proteoglycan synthesis is under developmental regulation during skeletal myogenesis.     

Subunit location of sulfhydryl groups of myosin labeled with a purine disulfide analog of adenosine triphosphate.

A purine disulfide analog of ATP, 6,6'-dithiobis(inosinyl imidodiphosphate), forms mixed disulfides with cysteine residues at what are believed to be ATP regulatory sites of myosin. Blocking these sites causes inactivation of the ATPase activity at the active sites. Two cysteine residues per head are specifically modifed by this disulfide analog. The thiopurine nucleotides can be stoichiometrically displaced from myosin by [14-C]cyanide to give a more stable thiocyanato derivative of the enzyme. [14-C]Thiocyanatomyosin (3.7 14-CN/myosin) was dissociated in 4 M urea and the individual subunits were isolated. The heavy chains each had 0.78 14-CN bound per 200,000 molecular weight unit. The light chain with molecular weight of 20,700 had 1.00 14-CN bound and the 16,500 molecular weight light chain had 0.65 14-CN bound. The two 19,000 molecular weight light chains were not labeled. The two labeled light chains have only a single cysteine which is stoichiometrically modified. These two light chains show a high degree of homology and presumably perform identical functions in myosin. Their specific modification by the purine disulfide analog and their other known properties suggest that they contribute directly to the ATP regulatory sites and may, in fact, function as regulatory subunits.     

Identification of distinct binding site subunits of mu and delta opioid receptors

Iodinated human beta-endorphin was affinity-cross-linked to opioid receptors present in membrane preparations from bovine frontal cortex, bovine striatum, guinea pig whole brain, and rat thalamus. Sodium dodecyl sulfate-polyacrylamide gel electrophoresis followed by autoradiography revealed covalently labeled peptides of 65, 53, 41, and 38 kilodaltons (kDa). The 65- and 38-kDa peptides were present in all four tissues. The 41-kDa peptide was seen only in bovine caudate and guinea pig whole brain while the 53-kDa peptide was absent in rat thalamus. All four labeled peptides were constituents of opioid receptors since their labeling was fully suppressed by the presence of excess opiates, such as bremazocine, during binding. The distribution and levels of the labeled species in the brain tissues examined and, in earlier work, in the neuroblastoma X glioma NG 108-15 cell line suggested that the 65-kDa peptide is a binding component of mu receptors while the 53-kDa peptide is a binding subunit of delta receptors. This result was strongly supported by the finding that the labeling of the 65-kDa peptide is selectively reduced by the presence of the highly mu-selective ligand Tyr-D-Ala-Gly-(N-Me)Phe-Gly-ol (DAMGE) during binding, while while the labeling of the 53-kDa peptide is selectively reduced or eliminated by the highly mu-selective ligand [D-Pen2, D-Pen5]enkephalin (DPDPE). The labeling of the 41- and 38-kDa bands was reduced by either DAMGE or DPDPE. The relationship of these lower molecular weight opioid-binding peptides to mu and delta receptors is not understood. Several possible explanations are presented.