Cellular compartment

About: Cellular compartment is a research topic. Over the lifetime, 1082 publications have been published within this topic receiving 53794 citations. The topic is also known as: cell compartmentation.

Characterization of a putative 82 kDa nuclear ligand for the N-acetylglucosamine-binding protein CBP70

Abstract: Since nuclear lectins were first characterized several years ago, six lectins have been isolated. Furthermore, the existence of nuclear glycoproteins containing N-linked complex-oligosaccharide chains or O-linked GlcNAc residues was evidenced. These latter are abundant in the nucleus and are well-studied so far. The presence of both glycoprotein and lectin in the cell nucleus led us to postulate that these two proteins could interact and play a role in some nuclear activities such as the modulation of transcription and/or nuclear cytoplasmic exchanges or by the disruption of protein-protein interactions. In such context, the recent data concerning the GlcNAc-binding activity of CBP70 argued this postulate. However, to study the possible role of a glycoprotein-lectin complex, it was critical to isolate the two partners. Because CBP70 was also a cytoplasmic protein, the lectin was isolated in both cytoplasmic and nuclear compartments in order to investigate the putative ligand in the two cellular compartments. The results obtained with cross-linking experiments on isolated and membranedepleted nuclei incubated with the CBP70 bearing an iodinatable, cleavable, photoreactive cross-linking agent (sulfosuccinimidyl 2-(p-azidosalicylamido) ethyl-1,3'-dithiopropionate) and immunoprecipitation experiments with polyclonal antibodies raised against CBP70, revealed that both nuclear and cytoplasmic CBP70 have the same 82 kDa nuclear ligand which is absent in the cytoplasmic fraction. In addition, this ligand is glycosylated, containing GlcNAc residues, and, therefore, the complex between CBP70 and the 82 kDa polypeptide could be due to a glycoprotein-lectin interaction. These results raised the possibility that nuclear glycoprotein-lectin interaction could be involved in nuclear activities.

Lipid vector for the delivery of peptides towards intracellular pharmacological targets.

Abstract: The ability of single-chain lipopeptides to gain access to cellular compartments other than those related to degradation/recycling was first deduced from their capacity to deliver peptide antigens into MHC-class I loading mechanisms. The ability of lipopeptides to escape complete endosome degradation was further illustrated by the selective inhibition of different protein kinase C isoenzymes and, more recently, the presentation of agonistic activity towards the interferon gamma receptor. Taken together, several independent results indicate that modification of a peptide by a single lipid chain confers upon it intracellular trafficking properties that can be used to deliver functional cargo peptides into living cells; the endoplasmic reticulum, cytosolic protease activity, sites of kinase activity, or even the signalling pathway associated with cytokine stimulation, all appear accessible to peptide modified by a single lipidic moiety. In this context, the interferon gamma receptor can be considered as a very discriminative pharmacological model, useful for the comparative evaluation of the cellular delivery of lipopeptides, as it allows the unambiguous tracking of their intact delivery into a wide range of cellular compartments. This model is now being used to probe the influence of the nature of the lipid moiety on the trafficking properties of lipopeptides.

A Stereological Approach for Estimation of Cellular Immunogold Labeling and Its Spatial Distribution in Oriented Sections Using the Rotator

Abstract: Particulate gold labeling applied to ultrathin sections is a powerful approach for locating cellular proteins and lipids on thin sections of cellular structures and compartments. Effective quantitative methods now allow estimation of both density and distribution of gold labeling across aggregate organelles or compartment profiles. However, current methods generally use random sections of cells and tissues, and these do not readily present the information needed for spatial mapping of cellular quantities of gold label. Yet spatial mapping of gold particle labeling becomes important when cells are polarized or show internal organization or spatial shifts in protein/lipid localization. Here we have applied a stereological approach called the rotator to estimate cellular gold label and proportions of labeling over cellular compartments at specific locations related to a chosen cell axis or chosen cellular structures. This method could be used in cell biology for mapping cell components in studies of protein translocation, cell polarity, cell cycle stages, or component cell types in tissues.

Intrazellulärer Transport in grünen Pflanzenzellen

Abstract: This report gives an overview of the functions of intracellular metabolite transport in a green plant cell. The phosphate translocator located in the inner membrane of the chloroplast envelope catalyzes the export of triose phosphate, the main product of photosynthesis, to the cytosol of the plant cell. For the reutilization of glycolate, the byproduct of photosynthesis, numerous transport processes across chloroplastic, peroxysomal and mitochondrial membranes are involved. During illumination, ATP and redox equivalents are delivered from the chloroplasts to the cytosol by the above mentioned phosphate translocator, in catalyzing a triosephosphate3-phosphoglycerate shuttle. Malate oxaloacetate shuttles between the chloroplastic, mitochondrial and peroxysomal spaces transfer redox equivalents between these cellular metabolic compartments. G rfinc Pflanzenzellen zeichnen sich gegen-fiber anderen eukaryontischen Zellen dadurch aus, dal3 ihr Stoffwechsel in besonders hohem MaDe kompartimentiert ist; diese Zellen weisen daher auch eine besonders hohe Anzahl von intrazellulfiren Transportvorgfingen auf. Es soll hier ein Uberblick fiber diese Transportvorg/inge gegeben werden.