细胞内胆固醇运输

作为生物膜的重要成分,细胞内不同膜上胆固醇含量的高低直接影响生物膜的生物物理特性和细胞信号的传递,与细胞正常的生理功能密切相关。外源内吞的胆固醇和内源合成的胆固醇通过囊泡介导和非囊泡介导的胆固醇运输途径在不同细胞膜之间转运,从而维持了不同细胞器上胆固醇的浓度梯度。一系列胆固醇结合和转运蛋白在细胞内胆固醇的运输中发挥了重要作用。本文旨在总结细胞内胆固醇运输途径与参与胆固醇运输的重要分子及相关作用机制。     

Intracellular trafficking of Parachlamydia acanthamoebae

Parachlamydia acanthamoebae is an obligate intracellular bacterium that naturally infects free-living amoebae. It is a potential agent of pneumonia that resists destruction by human macrophages. However, the strategy used by this Chlamydia-like organism in order to resist to macrophage destruction is unknown. We analysed the intracellular trafficking of P. acanthamoebae within monocyte-derived macrophages. Infected cells were immunolabelled for the bacteria and for various intracellular compartments by using specific antibodies. We analysed the bacteria colocalization with the different subcellular compartments by using epifluorescence and confocal microscopy. Bacterial replication took place 4-6 h post infection within acidic vacuoles. At that time, P. acanthamoebae colocalized with Lamp-1, a membrane marker of late endosomal and lysosomal compartments. A transient accumulation of EEA1 15 min post infection, and of rab7 and the mannose 6-phosphate receptor 30 min post infection confirmed that P. acanthamoebae traffic through the endocytic pathway. The acquisition of Lamp-1 was not different after infection with living and heat-inactivated bacteria. However, 24.5% and 79.5% of living and heat-inactivated P. acanthamoebae, respectively, colocalized with the vacuolar proton ATPase. Moreover, P. acanthamoebae did not colocalized with cathepsin D, a lysosomal hydrolase, suggesting that P. acanthamoebae interferes with maturation of its vacuole. Thus, P. acanthamoebae survives to destruction by human macrophages probably by controlling the vacuole biogenesis.     

Intracellular trafficking of Shiga-toxin-B-subunit-functionalized spherulites

Background information. Spherulites are multi‐lamellar lipidic vesicles that can encapsulate biomolecules and may be used as carriers for drug delivery. STxB (Shiga toxin B‐subunit) is known to bind the glycosphingolipid Gb3 (globotriaosyl ceramide), which is overexpressed by various human tumours. After Gb3 binding, the toxin enters the cytoplasm via the retrograde route, bypassing the degrading environment of the late endosomes/lysosomes. STxB is non‐toxic and has been identified as a promising tool for drug delivery. So far, applications have relied on direct coupling with therapeutic agents. In the present study, we have investigated the functionalization of spherulites by STxB and the intracellular trafficking of these structures. Results. We demonstrate that STxB‐spherulites (ST×B‐functionalized spherulites) are internalized into HeLa cells in a receptor‐dependent manner. The intracellular distribution was studied by confocal microscopy for lipids, ligand and content. We observed an early separation between spherulites and STxB, leading to a late endosomal/lysosomal localization of lipids and content, whereas STxB remained partially at the plasma membrane. Conclusions. Although recognition of Gb3 is the cause of their specific adhesion to cell membranes, STxB‐spherulites do not follow the retrograde transport route. Our results strongly suggest that STxB‐spherulites are, at least in part, disrupted at the plasma membrane, leading to lipid and content targeting to the classical endocytic pathway. We discuss how these findings influence the development of innovative delivery strategies.     

Intracellular trafficking of TRP channels

Thirteen years ago, it was suggested that exocytotic insertion of store-operated channels into the plasma membrane lead to increased Ca(2+) entry in non-excitable cells upon G protein-coupled or tyrosine kinase receptor stimulation. Since the discovery of the TRP channel superfamily and their involvement in receptor-induced Ca(2+) entry, many studies have shown that different members of the TRP superfamily translocate into the plasma membrane upon stimulation. While the exact molecular mechanism by which TRP channels insert into the plasma membrane is unknown, TRP-binding proteins have been shown to directly regulate this trafficking. This review summarizes recent advances related to the mechanism of TRP channel trafficking, focusing on the role of TRP-binding proteins.     

Intracellular trafficking in Plasmodium-infected erythrocytes

The past few years have witnessed considerable progress in molecular and biochemical studies of intracellular trafficking in malaria-infected red cells. Highlights include the identification of solute channels in the vacuolar membrane and the red blood cell membrane, a tubovesicular membrane network that delivers exogenous nutrients and drugs to the parasite, and parasite gene families that mediate adherence to endothelial cells and red cells.     

Intracellular trafficking in the trypanosomatids

Trypanosomes are members of the kinetoplastida, a group of divergent protozoan parasites responsible for considerable morbidity and mortality worldwide. These organisms have highly complex life cycles requiring modification of their cell surface together with engagement of immune evasion systems to effect survival; both processes intimately involve the membrane trafficking system. The completion of three trypanosomatid and several additional protist genomes in the last few years is providing an exciting opportunity to evaluate, at the molecular level, the evolution and diversity of membrane trafficking across deep evolutionary time as well as to analyse in unprecedented detail the membrane trafficking systems of trypanosomes.     

Intracellular trafficking of cell surface sialoglycoconjugates

Recent reports have suggested that the majority of the molecular traffic through the Golgi apparatus is comprised of recycling, rather than newly synthesized, molecules. To evaluate the importance of this recycling pathway in greater detail, we examined the internalization and recycling of cell surface glycoproteins on EL-4 cells, a murine T-cell lymphoma, using sialic acids as covalent markers. Sialic acids were removed from the surface of living cells by exhaustive treatment with Vibrio cholerae sialidase at 4 degrees C and shown to be derived primarily from glycoproteins (93%), with only a small amount from glycolipids (7%). Cells were recultured at 37 degrees C over time and monitored for the resialylation of the cell surface using a sensitive high pressure liquid chromatography adaptation of the thiobarbituric acid assay for sialic acids. The return of sialic acid to the cell surface was found to be contingent upon de novo protein synthesis indicating that the bulk of plasma membrane sialoglycoconjugates do not recycle to an endogenous sialyltransferase-containing compartment for oligosaccharide reprocessing. Identical results were found for K562 cells, a human erythroleukemia cell line. The movement of specific glycoproteins was followed using the enzyme rat liver alpha 2-6Gal beta 1-4GlcNAc sialyltransferase together with CMP-[3H]NeuAc as an impermeant probe of the cell surface. Surface sialoglycoproteins were internalized slowly, a process unaffected by cycloheximide treatment. Only a few of these internalized glycoproteins were found to return to a trans-Golgi compartment followed by recycling to the cell surface. Taken together, these data indicate that the majority of replacement of sialic acids on the cell surface is due to de novo synthesis of glycoproteins and that only a small number of glycoproteins recycle through a trans-Golgi compartment.     

Intracellular trafficking of lysosomal membrane proteins

Lysosomes are the site of degradation of obsolete intracellular material during autophagy and of extracellular macromolecules following endocytosis and phagocytosis. The membrane of lysosomes and late endosomes is enriched in highly glycosylated transmembrane proteins of largely unknown function. Significant progress has been made in recent years towards elucidating the pathways by which these lysosomal membrane proteins are delivered to late endosomes and lysosomes. While some lysosomal membrane proteins follow the constitutive secretory pathway and reach lysosomes indirectly via the cell surface and endocytosis, others exit the trans-Golgi network in clathrin-coated vesicles for direct delivery to endosomes and lysosomes. Sorting from the Golgi or the plasma membrane into the endosomal system is mediated by signals encoded by the short cytosolic domain of these proteins. This review will discuss the role of lysosomal membrane proteins in the biogenesis of the late endosomal and lysosomal membranes, with particular emphasis on the structural features and molecular mechanisms underlying the intracellular trafficking of these proteins.     

P-糖蛋白的细胞内转运及表达调控

肿瘤多药耐药(multidrug resistance,MDR)的发生多与P-糖蛋白(P-glycoprotein,P-gp)过度表达相关。作为一种糖蛋白,P-糖蛋白在内质网中合成、折叠,然后转运到高尔基体进行加工、修饰,最终定位于细胞膜,且只有定位于细胞膜的P-糖蛋白才与肿瘤多药耐药的产生相关。P-糖蛋白的表达与多种信号通路如MAPK、Wnt/β-catenin、PKC、NF-κB有关。研究证实,还有多种miRNA与肿瘤多药耐药的发生相关。本文综述了P-糖蛋白的细胞内转运过程及P-糖蛋白表达相关信号通路的研究进展,为以P-糖蛋白为靶标的肿瘤多药耐药逆转剂提供新的研究策略。     

Intracellular trafficking and dynamics of P bodies

RNAs are exported from the nucleus to the cytoplasm, where they undergo translation and produce proteins needed for the cellular life cycle. Some mRNAs are targeted by different RNA decay mechanisms and thereby undergo degradation. The 5’→3’ degradation machinery localizes to cytoplasmic complexes termed P bodies (PBs). They function in RNA turnover, translational repression, RNA-mediated silencing, and RNA storage. A quantitative live-cell imaging approach to study the dynamic aspects of PB trafficking in the cytoplasm revealed that PB movements are rather confined and dependent on an existing microtubule network. Microtubule depolymerization led to a drastic decrease in PB mobility, as well as a release of regulation on PB assembly and a dramatic increase in PB numbers. The different aspects of PB trafficking and encounters with mRNA molecules in the cytoplasm are discussed.     

Intracellular trafficking of Notch receptors and ligands

The Notch pathway represents a highly conserved signaling network, which regulates the formation and maintenance of various organ systems along development and during adulthood. Direct cell-cell contacts between ligand- and receptor-expressing cells underlie activation of the Notch pathway. Notch signaling requires endocytosis in both signal emitting and receiving cells. Recent findings on the roles of a number of modulators show that they act either on the maintenance of an active receptor at the membrane, or on the production of active ligand, or on signal transduction after activation.     

Intracellular trafficking of heat shock factor 2

HSF2 is an enigmatic member of the heat shock factor family, identified in the homeotherm classes of birds and mammals. We report the characterization of HSF2 from an evolutionary ancient vertebrate, the fish rainbow trout (rtHSF2). rtHSF2 appears closely related to its mammalian counterparts at structural and functional levels. The conservation of the distinctive features of HSF2 from fish to human suggests that it should ensure important biological functions, not redundant with those of HSF1. Proteasome inhibition, reported as a potent stimulator of HSF2, leads to the stabilization and to a striking nuclear trafficking of rtHSF2-GFP fusion protein. Upon treatment with the proteasome inhibitor MG132, rtHSF2-GFP accumulates into PML nuclear bodies (NBs) independently of its sumoylation and, if expressed at moderate level, moves to nucleoli. The translocation of rtHSF2-GFP from NBs to nucleoli is greatly favored by overexpression of the heat shock protein Hsp70. The mammalian counterpart mouse HSF2 (mHSF2) also exhibited changes in intracellular distribution upon MG132 treatment. mHSF2 partitioned between a juxtanuclear area that we characterized as an aggresome and the nucleoli. These relocalizations are likely to reflect common structural changes of mouse and trout HSF2 upon activation.