Further characterization and chemical purity assessment of the human erythrocyte glucose transporter preparation

Chemical and functional purity of the human erythrocyte glucose transporter preparation obtained by DEAE column chromatography after octyl glucoside solubilization was assessed. The cytochalasin B binding capacity of the preparation indicates that the preparation is 60-85% functional glucose transporter. Gel filtration chromatography on TSK 250 column separates this preparation into at least three major peptide fractions, namely, P0, P1 and P2, with apparent Mr of approx. 80 000, 43 000 and 17 000, respectively. When the preparation is photolabelled with [3H]cytochalasin B prior to the separation only P0 and P1 are labelled. Exposure of the preparation to octyl glucoside or to ultraviolet light irradiation results in an increase in P0 in a time-dependent manner with a concomitant and proportional reduction in P1, without affecting P2 appreciably. For individual preparations, relative abundance of P0 and P1 vary widely in a reciprocal fashion, while that of P2 is practically fixed at approx. 10% of the total protein. The specific activity of cytochalasin B binding of each preparation correlates linearly with the relative abundance of P1 of the preparation, which gives a calculated specific binding activity of 22 nmol/mg protein for this fraction. These results indicate that P1 and P0 are native and denatured transporter, respectively, while P2 is contaminating protein impurities. These results demonstrate that the glucose transporter preparation contains approx. 10% of nontransporter protein impurities, with a varying amount (up to 30%) of denatured transporter, and that the transporter free of the chemical impurities and the denatured transporter can be obtained by a gel filtration chromatography of this preparation.     

beta-Internexin, a ubiquitous intermediate filament-associated protein

In this article we show a Triton-insoluble, intermediate filament-associated protein of approximately 70 kD to be expressed ubiquitously in diverse mammalian cell types. This protein, assigned the name beta-internexin, exhibits extreme homology in each of the various cell lines as demonstrated by identical limited peptide maps, similar mobilities on two-dimensional gels, and detection in Triton-soluble and -insoluble extracts. beta-Internexin also shares some degree of homology with alpha-internexin, an intermediate filament-associated protein isolated and purified from rat spinal cord, which accounts for the immunologic cross-reactivity displayed by these polypeptides. Light microscopic immunolocalization of beta-internexin with a monoclonal antibody (mAb-IN30) reveals it to be closely associated with the vimentin network in fibroblasts. The antigen is also observed to collapse with the vimentin reticulum during the formation of a juxtanuclear cap induced by colchicine treatment. Ultrastructural localization, using colloidal gold, substantiates the affinity of beta-internexin for cytoplasmic filaments and, in addition, demonstrates its apparent exclusion from the intranuclear filament network. We examine also the resemblance of beta-internexin to a microtubule-associated polypeptide and the constitutively synthesized mammalian heat shock protein (HSP 68/70).     

Lymphocyte recognition of lymph node high endothelium. VII. Cell surface proteins involved in adhesion defined by monoclonal anti-HEBFLN (A.11) antibody

Lymphocyte entry into lymph nodes (LN) and Peyer's patches (PP) occurs specifically at high endothelial cell venules (HEV). We previously isolated a high endothelial binding factor (HEBFLN) from rat lymph that blocked the lymphocyte binding sites of HEVLN but not HEVPP. In this study, mouse monoclonal anti-HEBFLN antibody (A.11) was used to investigate rat lymphocyte surface structures mediating adhesion to high endothelium. The A.11 antigen was expressed on the majority of thoracic duct lymphocytes (TDL), spleen, LN, PP cells, but was only detected on few (1 to 10%) thymus and bone marrow cells (indirect immunofluorescence). The treatment of TDL with the A.11 IgG blocked their ability to bind to HEVLN. This effect was specific, inasmuch as A.11 antibody did not block lymphocyte binding to HEVPP, and an anti-leukocyte-common antigen monoclonal antibody, OX1, did not block lymphocyte binding to HEVLN. In addition, the A.11 antigen isolated from the lymph and detergent lysates of TDL by antibody affinity chromatography had the capacity to block the lymphocyte binding sites of HEVLN but not HEVPP. Immunoprecipitation studies revealed that the A.11 antibody recognized the radioiodinated surface membrane proteins of TDL and TDL-derived T cells and B cells, which resolved with SDS-PAGE autoradiography into three polypeptides with relative m.w. of approximately 135,000, 63,000, and 40,000. We conclude that the A.11 antigen is a component of the lymphocyte surface recognition structure that mediates adhesion to high endothelial cells of rat peripheral lymph nodes.     

Monoclonal antibodies to epitopes on different regions of the 200 00 dalton neurofilament protein : Probes for the geometry of the filament

Neurofilaments in mammalian nervous tissues have three subunit proteins. These subunit proteins have apparent molecular masses of 200 (NF200), 150 (NF150) and 68 (NF68) kD. Biochemical assembly studies have indicated that the NF68 protein forms the core of the filament and that the other two proteins are associated proteins. Electron microscopy immunolocalization studies have been performed previously on isolated filaments and on filaments from neurons in culture, and have confirmed the localization of NF68 as a core filament protein and NF200 as a peripheral protein. We have raised two monoclonal antibodies to the NF200 components. Using immunogold labelled protein A, we have been able to localize these antibodies to tissue sections of adult cerebellum at the EM level. With this method, we have found that one of the monoclonal antibodies (NF2) shows a linear arrangement of gold particles directly on the filament, whereas the second monoclonal antibody (NF111) reacts with the filaments to give a periodic arrangement of gold particles. By immunoblotting against chymotryptic fragments of the NF200 protein, we have found that the mAB-NF111 reacts solely with a 160 kD piece, whereas the other monoclonal antibody reacts with both the 160 kD piece and the 40 kD piece. The latter piece was shown to be associated to the filament by binding studies with iodinated NF68. Thus the EM localization studies and the biochemical studies indicate that the two monoclonal antibodies react with different parts of the NF200 molecule, one binding to a part of the molecule which is located closer to the filament, and one to a more peripheral part of the molecule.     

Isolation and characterization of calcium-accumulating matrix vesicles from chondrocytes of chicken epiphyseal growth plate cartilage in primary culture

Matrix vesicles (MV) can be readily isolated from culture media of chicken growth plate hypertrophic chondrocytes grown in primary culture. The chondrocytes maintain normal morphology and synthesize type II collagen throughout the culture period. The culture-derived MV are morphologically indistinguishable from MV seen in situ and are rich in alkaline phosphatase. Formation of alkaline phosphatase-rich MV is strongly influenced by the stage of culture: large numbers are released shortly after cell seeding; marked decline is seen during cell spreading and rapid cell division; notable resurgence in alkaline phosphatase-rich MV production occurs as the cells attain confluency. Increasing the initial chondrocyte seeding density proportionately increases MV production. Cells derived from the hypertrophic region are much more capable of forming alkaline phosphatase-rich MV than those from the proliferating zone, indicating that MV formation is dependent on cellular differentiation. MV released by the cultured chondrocytes were compared in protein and phospholipid composition and in their ability to accumulate mineral ions, with plasma membrane fractions and collagenase-released MV obtained from the same tissue. Electrophoretic patterns of proteins, and the phospholipid profiles, suggest that significant modification of the plasma membrane occurs during MV formation. The vesicles are capable of accumulating large amounts of mineral ions from a metastable synthetic cartilage lymph when supplied with alkaline phosphatase substrates. This culture system thus appears to be a useful model for isolating native MV and characterizing factors required for vesicle formation and mineralization.     

Role of supernatant protein factor and anionic phospholipid in squalene uptake and conversion by microsomes

Supernatant protein factor (SPF), a cytosolic protein (Mr = 47,000) stimulates microsomal squalene epoxidase activity 4- to 10-fold in the presence of anionic phospholipid such as phosphatidylglycerol (PG) (Saat, Y., and Bloch, K. (1976) J. Biol. Chem. 251, 5155-5160). This effect has been ascribed to substrate translocation from inactive to active pools within the membrane of the endoplasmic reticulum (Friedlander, E. J., Caras, I. W., Lin, L. F. H., and Bloch, K. (1980) J. Biol. Chem. 255, 8042-8045). Here we show that SPF and PG also stimulate squalene uptake per se by microsomes as well as stimulate squalene epoxidase. Microsomes preloaded with substrate in the presence of SPF and PG show full epoxidase activity. They do not require further addition of these factors during enzyme assay. Addition of SPF and PG to assay mixtures containing microsomes preloaded with substrate in the presence of SPF and PG did not further increase epoxidase activity. We also show that PG tightly binds to microsomes. This binding of PG is essential for the response of microsomal epoxidase to SPF. Solubilized microsomal enzymes have been reconstituted and show high epoxidase activity. In this system, SPF and PG do not stimulate the conversion of squalene into products.     

~3H-TdR转化细胞蛋白质酪氨酸残基的特异磷酸化

 <正> 1980年,Hunter首次发现Rous肉瘤病毒转化的细胞,其蛋白质分子上的酪氨酸残基磷酸化水平明显升高。现已知道,其它的肿瘤病毒诱导的转化细胞以及某些恶性肿瘤细胞的酪氨酸残基磷酸化作用亦有不同程度的增强。但迄今物理的致癌因素如放射性同位素引起的细胞转化是否伴随着酪氨酸特异的磷酸化的增强,尚未见报道。因此,本实验对C_3H10     

Internal duplication and homology with bacterial transport proteins in the mdr1 (P-glycoprotein) gene from multidrug-resistant human cells

Resistance of tumor cells to multiple cytotoxic drugs is a major impediment to cancer chemotherapy. Multidrug resistance in human cells is determined by the mdr1 gene, encoding a high molecular weight membrane glycoprotein (P-glycoprotein). Complete primary structure of human P-glycoprotein has been determined from the cDNA sequence. The protein, 1280 amino acids long, consists of two homologous parts of approximately equal length. Each half of the protein includes a hydrophobic region with six predicted transmembrane segments and a hydrophilic region. The hydrophilic regions share homology with peripheral membrane components of bacterial active transport systems and include potential nucleotide-binding sites. These results are consistent with a function for P-glycoprotein as an energy-dependent efflux pump responsible for decreased drug accumulation in multidrug-resistant cells.