Demonstration that the insulin receptor undergoes an early structural modification following insulin binding

Processing of the insulin receptor by hepatocytes was studied using a 125I-labelled photoreactive insulin derivative which could be covalently attached to the receptor and facilitate the analysis of receptor structure in isolated subcellular fractions by SDS-polyacrylamide gel electrophoresis. Following binding at the cell surface, the label was rapidly internalised and located in a low-density subcellular fraction ('endosomes'). The intact receptor (350 000 molecular weight) and binding (alpha) subunit (135 000), produced by in vitro disulphide reduction of the samples, were found in the plasma membrane fraction but not in endosomes. In endosomes, the label was concentrated in a band at 140 000 (non-reduced) which on reduction generated species of 100 000 and 68 000 predominantly. The insulin receptor therefore undergoes an early structural change during endocytosis. This modification does not involve complete disulphide reduction and may be due to a proteolytic event.     

Photoreactive insulin analogues used to characterise the insulin receptor

Three photoreactive insulin analogues (“photoprobes”) have been prepared in which an aryl azide group was substituted at either the A1, B1 or B29 positions of the insulin molecule. When incubated with rat liver plasma membranes and irradiated all three photoprobes covalently labelled specific insulin binding sites within the membrane. SDS-polyacrylamide gel electrophoresis of plasma membranes covalently tagged with either of the three ¹²⁵I-photoprobes resolved one major specifically labelled polypeptide with an apparent molecular weight of 130,000. The labelled polypeptide migrated anomalously in SDS-polyacrylamide gels and a molecular weight of 90,000 for the polypeptide was determined from a ‘Ferguson’ plot using the combined results from gels of different acrylamide concentrations. Column chromatography of detergent solubilised photoprobe-labelled membranes indicated that the labelled polypeptide may be a subunit of a larger protein complex.     

Demonstration of an intact complex of epidermal growth factor and its receptor in the endosomes of A-431 cells

The compartmentalization of the epidermal growth factor (EGF) receptors in A-431 cells was studied using centrifugation of the microsomal fraction of these cells in continuous Percoll gradient. The existence of an intact (non-degraded) EGF receptor in plasma membrane and endosome fraction was demonstrated by electrophoretic analysis of in vitro phosphorylated Percoll fractions. No phosphorylated receptor was revealed in lysosomal fraction by this method. The existence of non dissociated EGF-receptor complexes in intracellular compartments 30 minutes after the start of internalization was proven using a synthesized photoreactive labeled EGF derivative (125I-EGF-SANAH). The removing of pH gradient in organellar membranes by 10 mkM of monensin did not affect dissociation from its receptor. The data obtained proved the existence of non-dissociated and non-degraded EGF-receptor complexes in the endosomal compartment of A-431 cells.     

Compartmentalization and in vivo insulin-induced translocation of the insulin-signaling inhibitor Grb14 in rat liver

The molecular adaptor Grb14 binds in vitro to the activated insulin receptor (IR) and inhibits IR signaling. In this study, we have used rat liver subcellular fractionation to analyze in vivo insulin effects on Grb14 compartmentalization and IR phosphorylation and activity. In control rats, Grb14 was recovered mainly in microsomal and cytosolic fractions, but was also detectable at low levels in plasma membrane and Golgi/endosome fractions. Insulin injection led to a rapid and dose-dependent increase in Grb14 content, first in the plasma membrane fraction, and then in the Golgi/endosome fraction, which paralleled the increase in IR beta-subunit tyrosine phosphorylation. Upon sustained in vivo IR tyrosine phosphorylation induced by high-affinity insulin analogs, in vitro IR dephosphorylation by endogenous phosphatases, and in vivo phosphorylation of the IR induced by injection of bisperoxo(1,10 phenanthroline)oxovanadate, a phosphotyrosine phosphatase inhibitor, we observed a striking correlation between IR phosphorylation state and Grb14 content in both the plasma membrane and Golgi/endosome fractions. In addition, coimmunoprecipitation experiments provided evidence that Grb14 was associated with phosphorylated IR beta-subunit in these fractions. Altogether, these data support a model whereby insulin stimulates the recruitment of endogenous Grb14 to the activated IR at the plasma membrane, and induces internalization of the Grb14-IR complex in endosomes. Removal of Grb14 from fractions of insulin-treated rats by KCl treatment led to an increase of in vivo insulin-stimulated IR tyrosine kinase activity, indicating that endogenous Grb14 exerts a negative feedback control on IR catalytic activity. This study thus demonstrates that Grb14 is a physiological regulator of liver insulin signaling.     

Peptides Containing Multiple Photolabels: A new Tool for the Analysis of Ligand-Receptor Interactions: Reversible Long-lasting Stimulation and Inhibition of MSH Receptors by Multiple Photocrosslinks with α-MSH

Abstract

Crosslinking of MSH receptors on melanophores of the lizard Anolis carolinensis with analogues of α-MSH containing a photoreactive group in position 1, 7, 9 or 13 leads to long-lasting receptor stimulation. Reversibility of this long-lasting stimulation is obtained by employing a disulfide-containing photoreactive group which can be cleaved from the receptor by thiol reagents [Ref. 3]. When two photo-reactive groups are simultaneously present on the α-MSH molecule (e.g in positions 1 + 9; 1 + 13; 7 + 13, or 9 + 13), identical results were obtained and long-lasting receptor stimulation was not altered after cleavage of one single crosslink. α-MSH analogues with three photoreactive groups in positions 1 + 7 + 13 led to irreversible receptor stimulation whereas one compound with the photoreactive groups in positions 1 + 9 + 13 induced reversible receptor inactivation which could be changed into long-lasting stimulation by cleaving the crosslink at position 1 of α-MSH. These results demonstrate that one and the same peptide ligand may contain structural information for both receptor activation and inhibition and that the receptor may become arrested in an activated or inhibited state by multiple photocrosslinking, depending on the relative positions of these crosslinks.     

Characterization of rat liver endosomal fractions. In vivo activation of insulin-stimulable receptor kinase in these structures

A protocol employing discontinuous sucrose gradient centrifugation was developed to prepare light mitochondrial (L) and Golgi fraction endosomes from simultaneously prepared parent L and microsomal fractions. As judged by the concentration of labeled hormone postinjection, L intermediate and heavy endosome subfractions were 40- to 175-fold purified and Golgi intermediate and heavy endosome subfractions were 30- to 45-fold purified. On electron microscopy, L endosomal fractions contained a predominance of lipoprotein-filled vesicles and were less heterogeneous than corresponding Golgi endosomal fractions. All endosomal fractions were enriched in receptors for insulin and prolactin but binding sites for the former were more broadly distributed in other subfractions than those for the latter. On Percoll gradient centrifugation, L endosomal fractions yielded one peak (rho 1.057) corresponding to the heavier of two peaks seen in Golgi endosomal fractions. The protein composition of high density L and Golgi endosomes, as assessed by sodium dodecyl sulfate-polyacrylamide gel electrophoresis, was similar. The bulk of marker enzymes assayed did not migrate with the endosomal components. Combined acid phosphatase cytochemistry and electron microscope radioautography established that about 80% of the L endosomes contained no acid phosphatase. By affinity labeling and immunological titration with insulin receptor antibody, insulin receptors were identical in L and Golgi endosomes. Insulin-stimulable receptor kinase was demonstrable in both L and Golgi endosome fractions. Following in vivo insulin administration, the insulin receptor kinase in both L and Golgi endosomes was significantly activated. This activated state was not inhibited by a large excess of antiserum to insulin and thus not due to insulin contaminating the partially purified receptor preparation. These observations are compatible with the maintenance and/or initiation of hormone-dependent phosphorylations intracellularly.     

Trafficking of the epidermal growth factor receptor and transferrin in three hepatocytic endosomal fractions.

Hepatocytes rapidly internalize epidermal growth factor (EGF) and transferrin by receptor-mediated endocytosis. Both EGF and its receptor are thought to be targeted for destruction in lysosomes, leading to down-regulation of the receptor, whereas transferrin, after unloading iron within the cell, is thought to recycle to the cell surface bound to its receptor. Previously, we isolated three endosomal fractions from livers of estradiol-treated rats and examined their roles in cellular trafficking of low density lipoproteins (LDL) and the LDL receptor, which cycles constitutively (Belcher, J. D., Hamilton, R. L., Brady, S. E., Hornick, C. A., J?ckle, S., Schneider, W. J., and Havel, R. J., Proc. Natl. Acad. Sci. U. S. A. (1987) 84, 6785-6789). In the current study we have taken advantage of the distinct trafficking of the EGF receptor and transferrin to evaluate further the functions of these endosome fractions. Intravenous injection of a saturating amount of EGF into estradiol-treated rats induced internalization of a single population of EGF receptors, which rapidly accumulated in the endosome fraction of intermediate density ("compartment of uncoupling of receptor and ligand" (CURL)) and subsequently in the low density endosome fraction (multivesicular bodies (MVBs)). The high density endosome fraction, whose membranes contain a high concentration of recycling receptors (designated receptor-recycling compartment (RRC)), failed to accumulate EGF receptors after injection of EGF. In livers of rats not given exogenous EGF, EGF receptors were found in small but comparable concentrations in RRC, CURL, and MVB membranes, consistent with other evidence that targeting of the EGF receptor to lysosomes is mediated by ligand-induced phosphorylation. Transferrin also accumulated first in CURL and later in MVBs, but it also accumulated rapidly in the RRC fraction, consistent with the proposed function of this fraction in receptor recycling. Since transferrin is not degraded during its endocytic cycle, these observations indicate that apotransferrin and its receptor recycle from late endosomes (MVBs) located at the apical pole of hepatocytes, as well as from early endosomes near the sinusoidal pole.     

Interaction of a cationic polymer with negatively charged proteoliposomes

In the present study, we have analyzed a previously identified constitutively active pituitary adenylate cyclase activating polypeptide (PACAP) type I (PAC1) receptor with a deletion of the single amino acid residue Glu(261) (Y.-J. Cao, G. Gimpl, F. Fahrenholz, A mutation of second intracellular loop of pituitary adenylate cyclase activating polypeptide type I receptor confers constitutive receptor activation, FEBS Lett. 469 (2000)). This glutamic acid residue is highly conserved within the second intracellular loop of class II G protein-coupled receptors and may thus be of importance for many members of this receptor class. To explore the molecular characteristics of this mutant receptor, we performed photoaffinity labeling using previously defined photoreactive PACAP analogues. In COS cells, the PAC1 receptor was expressed in two differently glycosylated forms: a M(r) 75,000 and a M(r) 55,000 form. According to partial deglycosylation, at least three carbohydrate chains may exist in the rat PAC1 receptor expressed in COS cells. The constitutively active PAC1 receptor was expressed at the surface of COS-7 cells at the same density as the wild-type receptor. With respect to the different photoreactive PACAP analogues, the labeling specificity was the same for the wild-type versus mutant receptor: (125)I-[Lys(15)(pBz(2))]-PACAP-27 and (125)I-[Bpa(22)]-PACAP-27 were efficiently incorporated into each of the receptors, whereas (125)I-[Bpa(6)]-PACAP-27 labeled each of the receptors only to a negligible extent. This suggests that both receptors have the same or at least a very similar hormone binding site which is in close contact to Tyr(22) and Lys(15) located in the carboxy-terminal alpha-helical region of the PACAP-27 molecule. However, in comparison with the wild-type PAC1 receptor, the constitutively active receptor showed a markedly (approx. 6--8-fold) enhanced photoaffinity labeling efficiency in particular of the high glycosylated form. The enzymatically deglycosylated rat PAC1 receptor was efficiently labeled by photoreactive PACAP analogues. In contrast, nonglycosylated PAC1 receptors produced by tunicamycin treatment of the transfected COS-7 cells showed a 30-fold lower affinity for PACAP-27 and were capable of signal transduction with 30--50-fold lower potency as compared with the glycosylated PAC1 receptors.     

Identification and enzymatic deglycosylation of the myometrial oxytocin receptor using a radioiodinated photoreactive antagonist.

To identify and characterize oxytocin receptors, a 125I-labeled photoreactive oxytocin antagonist was synthesized. The specific oxytocin antagonist [1-(beta-mercapto-beta,beta- cyclopentamethylenepropionic acid), 2-O-methyltyrosine,4-threonine,8- ornithine,9-tyrosylamide]oxytocin ([Mca,Tyr(O-Me)2,Thr4,Orn8,Tyr9-NH2]oxytocin) described by Elands et al. (Elands, J., Barberis, C., Jard, S., Tribollet, E., Dreifuss, J.-J., Bankowski, K., Manning, M., and Sawyer, W. H. (1987) Eur. J. Pharmacol. 147, 192-207) bound to the guinea pig uterine oxytocin receptor with high affinity (apparent Kd = 0.74 nM). The introduction of a 4-azidophenylamidino group at Orn8 resulted in the photoreactive ligand [Mca1,Tyr(O-Me)2,Thr4,Orn(4-azidophenylamidino)8,Tyr9- NH2]oxytocin, which retained the high binding affinity (Kd = 0.69 nM) of the parent compound. The photoreactive antagonist monoiodinated at Tyr9 had approximately double (Kd = 0.39 nM) the affinity of the photoreactive antagonist and several times that of oxytocin (Kd = 2.6 nM) for the guinea pig uterine oxytocin receptor. In photo-affinity labeling experiments using myometrial membranes obtained from guinea pigs during late pregnancy, the 125I-labeled photoreactive antagonist specifically labeled a protein with an apparent molecular mass of between 68 and 80 kDa: the labeling of this protein was completely suppressed by a 100-fold molar excess of oxytocin and oxytocin receptor-specific agonists, but not by vasopressin analogues specific for V1 or V2 receptors or by other peptide hormones. The ability of oxytocin to suppress labeling was decreased in the presence of guanosine 5'-O-(thiotriphosphate) or in the absence of Mn2+. Digestion of the photolabeled oxytocin receptor with endoglycosidase F gave rise to a protein with an apparent molecular mass of 38 +/- 2 kDa. The endoglycosidase F effect and the lack of endoglycosidase H action show that the myometrial oxytocin receptor is highly glycosylated with asparagine-linked complex oligosaccharide chains. Our results suggest that the radioiodinated photoreactive oxytocin antagonist could be a helpful tool in the isolation and further characterization of the oxytocin receptor.     

Proliferative effects of insulin analogues on mammary epithelial cells

Structural modification of insulin results in the generation of insulin analogues that show altered binding affinities to the insulin receptor and/or IGF-I receptor. As a consequence these insulin analogues may have increased mitogenic potency. Nine benign or malignant human mammary epithelial cells, which show different insulin receptor and IGF-I receptor expression patterns, were studied regarding mitogenicity of insulin and insulin analogues. Only insulin glargine showed a significantly higher proliferative effect on MCF-7 breast cancer cells compared to regular insulin among a panel of short- or long-acting insulin analogues, that are in clinical use.     

Release of iron from endosomes is an early step in the transferrin cycle

Transferrin bound to K 562 cells at 4 degrees C was internalized quickly on temperature shift to 37 degrees C. Endosomes were isolated according to two different procedures. The endosome fraction was shown to be heterogeneous and consisted of two vesicle populations, differing in density properties and iron content. Iron was partially released from endosomes to the supernatant after 3 and 5 min endocytosis. Isolated endosomes, still capable of internal acidification, did not release iron on incubation with ATP. However, endosomes did release iron on incubation with the iron chelator pyridoxal-isonicotinoyl hydrazone. Gel-filtration of solubilized endosomes demonstrated the presence of the transferrin-transferrin receptor complexes, free transferrin and free low molecular weight iron.     

Iodinated photoreactive vasopressin antagonists: labelling of hepatic vasopressin receptor subunits

To identify and characterize V1 vasopressin receptors, photoreactive antagonists of the glycogenolytic and vasoconstrictor activity of vasopressin have been synthesized. The following analogues with 3-mercapto-3,3-cyclopentamethylene-propionic acid (Mca) and N-methylalanine (MeAla) in position 1 and 7 of vasopressin (VP) were effective V1 antagonists: [Mca1, D-Tyr2, MeAla7, Lys8]VP (1), [Mca1, MeAla7, Arg8, Lys9]VP (2), [Mca1, MeAla7, Arg8, D-Lys9]VP (3). Introduction of the photoreactive 4-azidophenylamidino group into the side-chain of Lys8 in analogue 1 or into Lys9 in analogues 2 and 3 increased the potency (for analogue 1 a tenfold increase in the antiglycogenolytic effect and a fivefold increase in the antivasopressor effect) and binding affinity for the rat hepatic V1 receptor. Mono-iodination at Tyr2 with 125I resulted in photoreactive antagonists of high specific radioactivity, which had roughly the same binding affinity as vasopressin for the rat hepatic V1 receptor (Kd = 0.9-1.8 nM). In photoaffinity labelling experiments with purified rat liver membranes, containing 2--3 pmol V1 receptor/mg protein, the analogues labelled specifically two proteins with the relative molecular masses (Mr) of 30,000 and 38,000. These results and the results of a recent study using 3H-labelled photoreactive vasopressin agonists [Boer, R. and Fahrenholz, F. (1985) J. Biol. Chem. 260, 15051-15054] provide evidence that both vasopressin agonists and antagonists can interact with the same two subunits of the heterodimeric hepatic V1 receptor. Furthermore the radioiodinated photoreactive V1 antagonists should be helpful to identify V1 receptor proteins in membranes of other cell types.     

Evidence that insulin receptor from human placenta has a high affinity for only one molecule of insulin

Insulin receptor, partially purified from human placenta by chromatography on wheat germ agglutinin, was shown, by means of double probe labeling, to bind only one molecule of insulin with a high affinity. In the double probe labeling protocol used, 125I-insulin (probe 1) was affinity cross-linked to its receptor in the presence of an excess of unlabeled N epsilon B29-biotinylinsulin (probe 2). The ability of succinylavidin to bind to receptor-linked probe 2 and alter the electrophoretic mobility of the cross-linked complex (during polyacrylamide gel electrophoresis in the presence of sodium dodecyl sulfate) was used to determine the amount of receptor which was cross-linked to both probes relative to that which was cross-linked to only probe 1. The fraction of receptor bound to two molecules of insulin prior to cross-linking was estimated from the cross-linking efficiency and the yield of receptor cross-linked to both probes relative to the yield of receptor cross-linked only to probe 1. The low fraction of receptor bound to both probes in the presence of high concentrations of probe 2 indicated that the affinity of the receptor for a second molecule of insulin was approximately 100 times less than that for the first and that in the range of insulin concentrations (less than 20 nM) usually used to determine the stoichiometry for the interaction between receptor and insulin, more than 80% of the receptor molecules should be bound to only one molecule of insulin. This knowledge of how insulin receptor interacts with insulin was shown to be important for proper determination of receptor purity, interpretation of curvilinear Scatchard plots, and interpretation of the insulin-enhanced rate of dissociation of receptor-bound insulin.     

Lipid chain geometry of C14 glycerol-based lipids: effect on lipoplex structure and transfection

The effects have been determined of a systematic alteration of the alkyl chain geometry of a C14 analogue of DOTMA on the detailed molecular architecture of the resulting cationic vesicles formed both in the absence and presence of 50 mol% DOPE, and of the lipoplexes prepared from these vesicles using either calf thymus or plasmid DNA. The C14 DOTMA analogues studied involved cis- or trans-double bonds at positions Δ9 or Δ11, and a compound (ALK) featuring an alkyne at position C9. For all of these analogues, examination by light scattering and neutron scattering, zeta potential measurement, and negative staining electron microscopy showed that there were no significant differences in the structures or charges of the vesicles or of the resulting lipoplexes, regardless of the nature of the DNA incorporated. Differences were observed, however, between the complexes formed by the various lipids when examining the extent of complexation and release by gel electrophoresis, where the E-lipids appeared to complex the DNA more efficiently than all other lipids tested. Moreover, the lipoplexes prepared from the E-lipids were the most effective in transfection of MDA-MB-231 breast cancer cells. As indicated through confocal microscopy studies, the E-lipids also showed a higher internalisation capacity and a more diffuse cellular distribution, possibly indicating a greater degree of endosomal escape and/or nuclear import. These observations suggest that the extent of complexation is the most important factor in determining the transfection efficiency of the complexes tested. At present it is unclear why the E-lipids were more effective at complexing DNA, although it is thought that the effective area per molecule occupied by the cationic lipid and DOPE head groups, and therefore the density of positive charges on the surface of the bilayer most closely matches the negative charge density of the DNA molecule. From a consideration of the geometry of the cationic lipids it is anticipated that the head groups of the E-lipids would occupy a smaller area per molecule than the ALK or Z-lipids.     

Evaluation of protein-N-(2-hydroxypropyl)methacrylamide copolymer conjugates as targetable drug carriers. 1. Binding, pinocytic uptake and intracellular distribution of transferrin and anti-transferrin receptor antibody conjugates

The transferrin receptor of human skin fibroblasts was studied as an in vitro model target antigen receptor for interaction with protein-polymer conjugates having potential for targeted drug delivery. Pinocytic uptake of 125I-labelled N-(2-hydroxypropyl)methacrylamide (HPMA) copolymer conjugated to monoclonal antibody B3/25 (specific for the transferrin receptor) or transferrin was up to 9-fold greater than uptake of the parent HPMA copolymer. The ability of these conjugates to bind specifically was confirmed by Scatchard analysis. Pinocytic internalisation was dependent on the molecular mass of the conjugate. Intracellular routing following internalisation was evaluated using density-gradient centrifugation. Unmodified HPMA copolymer was transferred via the endosomal compartment into secondary lysosomes, where, being resistant to degradation, it accumulated. Although the majority of endocytosed transferrin is recycled via the endosome, it was shown that any transferrin reaching the lysosomes was rapidly degraded and low-molecular-weight degradation products were released. Monoclonal antibody B3/25 showed a subcellular distribution consistent with prolongation on the cell surface, followed by internalisation and subcellular trafficking, via endosomes, into the lysosomal compartment, with subsequent degradation. Conjugation of protein to HPMA copolymer increased lysosomal accumulation of polymer up to 9-fold, with no detectable degradation of conjugate. The data presented here have implications regarding clinical potential of protein-HPMA copolymer conjugates designed for lysosomotropic drug delivery.     

Estradiol-mediated internalisation of the non-activated estrogen receptor from the goat uterine plasma membrane: Identification of the proteins involved

An indirect approach has been made to study the molecular details associated with the estradiol-induced internalisation of the non-activated estrogen receptor (naER) from the goat uterine plasma membrane. The internalisation of naER appears to be an energy dependent process. Exposure of the plasma membrane to estradiol results in the activation of a Mg2+ dependent ATPase associated with the membrane fraction. Presence of quercetin in the medium prevented the activation of the Mg2+ ATPase as well as the dissociation of naER from the plasma membrane. Using isolated plasma membrane preparations it has been possible to identify the proteins which interact with naER during various stages of its internalisation. The main proteins identified are: (1) a 58 kDa protein, p58, which apparently recognizes the nuclear localization signals on the naER and transports it to the nucleus: (2) hsp70: (3) hsp90, the functional roles of which remain unknown at this stage; (4) a 50 kDa protein associated with the clathrin coated vesicles, presumed to be involved in recognizing the tyrosine based internalisation signals on the naER; (5) actin which mediates the plasma membrane-to-nucleus movement of the naER-p58 complex.     

Insulin and its receptor: structure, function and evolution

I present here a personal perspective on more than three decades of research into the structural biology of the insulin-receptor interaction. The solution of the three-dimensional structure of insulin in 1969 provided a detailed understanding of the insulin surfaces involved in self-assembly. In subsequent years, hundreds of insulin analogues were prepared by insulin chemists and molecular biologists, with the goal of relating the structure to the biological function of the molecule. The design of methods for direct receptor-binding studies in the 1970s, and the cloning of the receptor in the mid 1980s, provided the required tools for detailed structure-function studies. In the absence of a full three-dimensional structure of the insulin-receptor complex, I attempt to assemble the existing pieces of the puzzle generated by our and other laboratories, in order to generate a plausible mechanistic model of the insulin-receptor interaction that explains its kinetics and negative cooperativity.     

小鼠抗人胰岛素受体单克隆抗体的制备、纯化及鉴定

 M11D杂交瘤细胞株是由人胎盘细胞膜纯化所得胰岛素受体免疫BALB/C小鼠后,取其脾细胞与同系小鼠骨髓瘤细胞株NS-1细胞融合所得。该杂交瘤细胞分泌的抗体经ELISA及放射免疫沉淀法证实为胰岛素受体特异的单克隆抗体。该抗体经Protein A-Sepharose亲和层析分离、纯化,SDS-聚丙烯酰胺梯度凝胶电泳鉴定得分子量分别为53000及23000的两条区带,免疫双扩证明为IgGl。该抗体特异地沉淀125Ⅰ-人胎盘细胞膜胰岛素受体,沉淀经SDS-聚丙烯酰胺凝胶电泳后放射自显影得分子量为135000的特异显影带,与胰岛素受体α亚基分子量相同,说明M11D为抗胰岛素受体α亚基的单克隆抗体。     

Characterization of endocytic compartments using the horseradish peroxidase-diaminobenzidine density shift technique

We have employed a modification of the horseradish peroxidase (HRP)-diaminobenzidine density shift technique of Courtoy et al. (J. Cell Biol., 1984, 98:870-876) to examine the biochemical properties of the endosome. This organelle is involved in receptor recycling and the sorting of internalized receptor ligand complexes. Transferrin covalently bound to HRP was used to place peroxidase activity specifically within the endosome. The peroxidase-catalyzed polymerization of diaminobenzidine within these vesicles causes an increase in buoyant density, thus allowing them to be separated from other membranes. Using this technique we demonstrate that 125I-low density lipoprotein, 131I-epidermal growth factor, and Tf-HRP are internalized into the same endosome. We discovered that the diaminobenzidine reaction product "cross-links" the lumen of the vesicle, rendering vesicular components detergent insoluble. Furthermore, the reaction inactivates enzymatic activities associated with the endosome. Thus, the diaminobenzidine density shift procedure has limited usefulness in studies designed to isolate endosomal constituents. Nonetheless, we have found that the inactivation of enzymatic activities is confined to those endosomes that contain peroxidase. This selectivity allows us to define endosome-specific activities.