Two ALLN (N-acetyl-leucyl-leucyl-norleucinal)-sensitive endoplasmic reticulum (ER)-localized proteases (ER-60 and ER-72) were recently purified from rat liver. We used an antibody to rat ER-60 to investigate the possible role of this protease in apolipoprotein B (apoB) degradation. First, immunoprecipitation and immunoblotting experiments with the anti-rat ER-60 antibody suggested that HepG2 cells contain a homologue of ER-60 with an approximate molecular mass of 58 -60 kDa. The ER-60 homologue was mostly associated with the luminal contents of HepG2 microsomes. Evidence from co-immunoprecipitation and cross-linking experiments appear to suggest that the ER-60 homologue in HepG2 cells is associated with apoB intracellularly. A small pool of apoB was recovered when HepG2 lysates were subjected to immunoprecipitation with anti-rat ER-60 antibody followed by a second immunoprecipitation with anti-apoB antibody. Furthermore, cross-linking of permeabilized cells with dithiobis(succinimidylpropionate) further demonstrated association of apoB with the ER-60 homologue in HepG2 cells. Three polypeptides with molecular masses of 78, 66, and 50 kDa were consistently found to be associated with apoB as well as the 58-kDa ER-60 homologue. The 78-kDa protein associated with both apoB and ER-60 appeared to represent immunoglobulin heavy chain-binding protein (BiP) based on immunoprecipitation with a monoclonal antibody. Cross-linking and immunoblotting experiments suggested the association of the 78-kDa BiP with both the 58-kDa ER-60 homologue as well as the 550-kDa apoB.In summary, the data suggests that HepG2 cells contain a 58-kDa protein which is homologous to the rat liver ER-60 in size, antigenecity, and intracellular localization. The ER-60 homologue in HepG2 cells appears to be closely associated with apoB, as well as other proteins possibly representing ER chaperones such as BiP. We hypothesize that the ER-60 homologue may be involved in the degradation of apoB in the ER lumen of HepG2 cells.Post-translational degradation of apoB has been shown to modulate the intracellular levels of newly-synthesized apoB molecules (1-19). Recent evidence suggest that apoB degradation may occur in the cytosol by the proteasome (19) as well as in the ER 1 lumen by an unidentified ER protease(s) (17, 18). The identity of the ER-associated protease involved in apoB degradation has remained elusive, however, some characteristic features of this degradative system have recently been documented. The ER-associated protease appears to be responsible for fragmentation of apoB into a number of distinct degradation intermediates including an abundant 70-kDa fragment (12, 16). The activity of the ER-associated protease is also inhibitable by ALLN in a dose-dependent manner (12, 16). Intraluminal degradation of secretion-competent apoB associated with nascent HDL-like and LDL-like lipoprotein particles in the secretory pathway is also ALLN-sensitive and may be mediated by a putative ER-localized protease (17). Work by Ginsberg and co-workers (18)...
Synthetic nanoparticle formulations have the potential for tumor-targeted gene delivery. Receptor-targeted nanocomplex (RTN) formulations comprise mixtures of cationic liposomes and targeting peptides that self-assemble on mixing with nucleic acids. RTN formulations were prepared containing different polyethylene glycol (PEG)ylated lipids with esterase-cleavable linkers (e.g., ME42) to promote intracellular PEG detachment and nanoparticle disassembly. In addition, integrin-targeting peptides (peptide ME27) were tested with endosomal furin- and cathepsin B-cleavable peptide linkers located between the integrin-binding ligand and the K(16) nucleic acid-binding domain to promote intracellular disengagement from the receptor. ME42/ME27 RTNs formed stable particles of <200 nm in isotonic salt buffers, compared with 4-microm particles formed by un-PEGylated RTNs. Transfection efficiency by PEG-modified, cleavable RTNs improved approximately 2-fold in 4 different cell lines, with 80% efficiency in murine neuroblastoma cells. In an in vivo model of neuroblastoma, ME42/ME27 RTNs delivering luciferase genes were tumor specific, with little expression in other organs tested. PEGylation of the RTNs enhanced luciferase transfection 5-fold over non-PEG formulations, whereas the cleavability of the peptide ME27 enhanced transfection 4-fold over that of RTNs with noncleavable peptides. Cleavability of the lipid for in vivo transfections had no effect. PEGylated, cleavable RTN formulations offer prospects for tumor-specific therapeutic gene transfer.
Cationic peptide sequences, whether linear, branched, or dendritic, are widely used to condense and protect DNA in both polyplex and lipopolyplex gene delivery vectors. How these peptides behave within these particles and the consequences this has on transfection efficiency remain poorly understood. We have compared, in parallel, a complete series of cationic peptides, both branched and linear, coformulated with plasmid DNA to give polyplexes, or with plasmid DNA and the cationic lipid, DOTMA, mixed with 50% of the neutral helper lipid, DOPE, to give lipopolyplexes, and correlated the transfection efficiencies of these complexes to their biophysical properties. Lipopolyplexes formulated from branched Arg-rich peptides, or linear Lys-rich peptides, show the best transfection efficiencies in an alveolar epithelial cell line, with His-rich peptides being relatively ineffective. The majority of the biophysical studies (circular dichroism, dynamic light scattering, zeta potential, small angle neutron scattering, and gel band shift assay) indicated that all of the formulations were similar in size, surface charge, and lipid bilayer structure, and longer cationic sequences, in general, gave better transfection efficiencies. Whereas lipopolyplexes formulated from branched Arg-containing peptides were more effective than those formulated from linear Arg-containing sequences, the reverse was true for Lys-containing sequences, which may be related to differences in DNA condensation between Arg-rich and Lys-rich peptides observed in the CD studies.
Permeabilized Hep G2 cells have been used to investigate the turnover of apolipoprotein B-100 (apoB-100). When such cells were chased in the presence of buffer, there was no biosynthesis of apoB-100, nor was the protein secreted from the cells. Thus the turnover of apoB-100 in these cells reflected the posttranslational degradation of the protein. Pulse-chase studies indicated that apoB-100 was degraded both when associated with the membrane and when present as lipoproteins in the secretory pathway. Neither albumin nor ␣ 1 -antitrypsin showed any significant posttranslational intracellular degradation under the same condition. The kinetics for the turnover of apoB-100 in the luminal content differed from that of apoB-100 that was associated with the microsomal membrane. Moreover, while the degradation of the luminal apoB-100 was inhibited by N-acetylleucyl-leucyl-norleucinal (ALLN), this was not the case for the membrane-associated protein. Together these results suggest the existence of different pathways for the degradation of luminal apoB-100 and membrane-associated apoB-100. This was further supported by results from pulse-chase studies in intact cells, showing that ALLN increased the amount of radioactive apoB-100 that associated with the microsomal membrane during the pulse-labeling of the cells. However, ALLN did not influence the rate of turnover of the membrane-associated apoB-100.The presence of an ATP-generating system during the chase of the permeabilized cells prevented the disappearance of pulse-labeled apoB-100 from the luminal lipoprotein-associated pool. The ATP-generating system combined with cytosol protected the total apoB-100 in the system from being degraded. The cells cultured in the presence of oleic acid and chased after permeabilization in the presence of cytosol and the ATP-generating system showed an increase in the amount of apoB-100 present on dense ("high density lipoprotein-like") particles. This increase was linear during the time investigated (i.e. from 0 to 2 h chase) and independent of protein biosynthesis. Our results indicate that the dense particle was generated by a redistribution of apoB-100 within the secretory pathway and that it most likely was assembled from the membrane-associated form of apoB-100. These results indicate that the release of apoB-100 from this membrane-associated form to the microsomal lumen is dependent on cytosolic factors and a source of metabolic energy.
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