细胞内吞的研究进展

细胞内吞(endocytosis)是细胞从周围环境中摄取各种物质的过程,是细胞生理代谢的一个极为重要的现象。几乎所有的真核细胞都通过内吞作用摄取细胞外基质中的大分子。70年代中期,Steinman等人发现了细胞膜系就再循环现象,Goldstein等人第一次较为完整地描述了由受体介导的低密度脂蛋白(Low densitylipoprotein,简称LDL)内吞过程,这两项成果使细胞内吞成为细胞生物学研究领域中的     

网格蛋白介导的内吞作用机制

受体介导的内吞作用是目前公认的生物体摄取生物大分子的途径,而网格蛋白介导的内吞又是最主要的受体介导方式.结合国内外最新报道,介绍了网格蛋白和衔接蛋白的结构、分子特性和功能;从衔接蛋白、网格蛋白的招募;包被小凹的内陷、缢缩和包被液泡的芽殖和包被液泡的脱壳等过程,阐释了网格蛋白介导的内吞作用机制.     

冠状病毒入侵细胞途径的研究进展

近年来，冠状病毒严重威胁人类和动物的健康。病毒具有专性胞内寄生的特点，其需要利用细胞完成自身的增殖，因此入侵细胞的过程是其感染机制中非常重要的一部分。多项研究表明冠状病毒能通过细胞表面途径和内吞途径入侵细胞。通过对冠状病毒入侵途径研究有助于了解其生命周期，有利于冠状病毒的防治以及新型药物和疫苗的研发。本文对近年来不同冠状病毒的入侵途径及针对入侵途径所开发的潜在药物的相关研究进行总结，以期为全面了解冠状病毒的入侵方式提供参考。     

病毒入胞机制研究方法及其研究进展

多数病毒家族利用胞吞作为入侵宿主细胞的途径。胞吞既可以介导病毒内化,也可以将病毒运输到复制位点。已知的胞吞途径包括:网格蛋白依赖型内吞、小窝蛋白依赖型内吞、巨胞饮和网格蛋白、小窝蛋白非依赖型内吞。随着对胞吞过程中各组分结构和功能了解的日趋深入,研究胞吞过程以及病毒入侵过程的手段也变得更有效,特异性更高。目前,化学抑制剂的使用仍十分普遍,但该方法常非特异性地阻断细胞某些功能。一些分子抑制方法,如过表达显性负突变体和siRNA技术等,因其对单一途径的特异性阻断,使得应用分子型抑制剂逐渐取代了化学抑制剂。本文主要分析了研究病毒入侵途径时所使用的实验方法,并列举了一些实例。     

吞蛋白A2在非网格蛋白内吞中的作用研究进展

内吞作用是细胞从细胞外空间和内化横跨膜的细胞表面蛋白转运物质到细胞内的过程.吞蛋白(endophilin)一直被认为参与了网格蛋白介导的细胞内吞作用,2015年《自然》(Nature)发表的两篇研究论文报道了一种由endophilin A标记和控制的独立于网格蛋白的有被囊泡内吞作用.本文主要综述近年来endophilin A2的研究,着重介绍endophilin A2在非网格蛋白介导的内吞作用中的功能和机制.     

巨噬细胞细胞内吞过程中膜受体流动性的测量——两种标记受体…

本文首次实现了细胞内吞过程中膜受体流动性的测量。实验选择巨噬细胞膜和伴刀豆凝集素Ａ（ＣｏｎＡ）。分别用ＣｏｎＡ－Ｂｉｏｔｉｎ＋Ａｖｉｄｉｎ－ＦＩＴＣ（ＡＢＣ法）和ＣｏｎＡ－ＦＩＴＣ（直接法）两种方法标记巨哓细胞膜ＣｏｎＡ受体，比较了这两咱方法标记的巨噬细胞ＣｏｎＡ受体的荧光强度，利用ＦＲＡＰ技术。分别用两种标记方法测量了巨细胞ＣｏｎＡ受体的流动性。结果显示ＣｏｎＡ－Ｂｉｏｔｉｎ＋Ａｖｉｄｉｎ－ＦＩ     

内吞蛋白家族的研究近况

内吞蛋白是最近发现的一类功能蛋白质,主要参与细胞膜的物质运输和信息交流。内吞蛋白具有特殊的结构,家族成员之间有很高的同源性,成员蛋白一般多具有C端的SH3结构域和N端的溶血磷脂酸脂酰基转移酶结构域。C端的SH3结构域可与许多能结合SH3的蛋白质相结合,N端则参与细胞膜的内凹形成囊泡。内吞蛋白在神经递质的回收过程中发挥重要的作用,并在细胞的信号转递和凋亡过程中具有重要的作用．     

Ｇ蛋白偶联受体失敏及内吞相关蛋白的研究进展

Ｇ蛋白偶联受体的失敏和内吞对受体功能的调节非常重要,但其具体机制并不十分清楚,在某些方面还存在分歧。近年来的研究发现,第二信使激酶、Ｇ蛋白偶联受体激酶、arrestin及笼形蛋白等在此过程中扮演了重要的角度,本文就与受体失敏和内吞关系密切的几种蛋白的研究进展进行综述。     

细胞内吞和自噬的新标志物VCP/p97

含缬酪肽蛋白(VCP)即p97,是一种广泛存在的膜结合糖蛋白,在细胞活性中有着广泛的功能,作为类似分子伴侣在内质网相关蛋白降解及细胞周期调控中起重要作用。在这些细胞过程中,p97与其辅因子UFD1-NPL4结合,把多泛素化错误折叠的蛋白通过蛋白酶进行降解。新近研究发现,p97能够独立于UFD1-NPL4,参与细胞质内运输和自噬。有趣的是,这些途径通过溶酶体也能够使蛋白降解。我们就近年来VCP/p97在细胞内吞作用和自噬中的作用进行综述。     

巨胞饮的机制及功能的研究进展

巨胞饮（macropinocytosis）是内吞的一种形式,指在某些因素刺激下,细胞膜皱褶形成大且不规则的原始内吞小泡,它们被称为巨胞饮体。巨胞饮体的直径一般为0．5～2μm,有时可达5μm。与其它内吞形式的小泡相比,巨胞饮体直径较大,为非选择性地内吞细胞外营养物质和液相大分子提供了一条有效途径。最近的研究表明,巨胞饮具有清除凋亡细胞、参与免疫反应、介导某些病原菌侵袭细胞、更新细胞膜等功能。     

Caveolae/raft-dependent endocytosis

Although caveolae are well-characterized subdomains of glycolipid rafts, their distinctive morphology and association with caveolins has led to their internalization being considered different from that of rafts. In this review, we propose that caveolae and rafts are internalized via a common pathway, caveolae/raft-dependent endocytosis, defined by its clathrin independence, dynamin dependence, and sensitivity to cholesterol depletion. The regulatory role of caveolin-1 and ligand sorting in this complex endocytic pathway are specifically addressed.     

Effects of endocytosis inhibitory drugs on rubella virus entry into VeroE6 cells

It has been suggested that infectious entry of rubella virus (RV) is conducted by receptor mediated endocytosis. To explore the cellular entry mechanism of RV, inhibitory effects of drugs affecting various endocytic pathways on RV entry into VeroE6 cells were analyzed. Results showed that RV infectious entry into VeroE6 cells is mediated by clathrin-dependent endocytosis and not by caveolae-mediated endocytosis. Moreover, chemical inhibition of macropinocytosis such as treatments of amiloride, actin and microtubule-disrupting drug significantly reduced RV infection. Considering that macropinocytosis is inducible endocytosis by cellular stimulations, clathrin-mediated endocytosis is likely to be a major route of RV infectious entry.     

The molecular physiology of activity-dependent bulk endocytosis of synaptic vesicles

Central nerve terminals release neurotransmitter in response to a wide variety of stimuli. Because maintenance of neurotransmitter release is dependent on the continual supply of synaptic vesicles (SVs), nerve terminals possess an array of endocytosis modes to retrieve and recycle SV membrane and proteins. During mild stimulation conditions, single SV retrieval modes such as clathrin-mediated endocytosis predominate. However, during increased neuronal activity, additional SV retrieval capacity is required, which is provided by activity-dependent bulk endocytosis (ADBE). ADBE is the dominant SV retrieval mechanism during elevated neuronal activity. It is a high capacity SV retrieval mode that is immediately triggered during such stimulation conditions. This review will summarize the current knowledge regarding the molecular mechanism of ADBE, including molecules required for its triggering and subsequent steps, including SV budding from bulk endosomes. The molecular relationship between ADBE and the SV reserve pool will also be discussed. It is becoming clear that an understanding of the molecular physiology of ADBE will be of critical importance in attempts to modulate both normal and abnormal synaptic function during intense neuronal activity.     

Regulation of cargo‐selective endocytosis by dynamin 2 GTPase‐activating protein girdin

In clathrin‐mediated endocytosis (CME), specificity and selectivity for cargoes are thought to be tightly regulated by cargo‐specific adaptors for distinct cellular functions. Here, we show that the actin‐binding protein girdin is a regulator of cargo‐selective CME. Girdin interacts with dynamin 2, a GTPase that excises endocytic vesicles from the plasma membrane, and functions as its GTPase‐activating protein. Interestingly, girdin depletion leads to the defect in clathrin‐coated pit formation in the center of cells. Also, we find that girdin differentially interacts with some cargoes, which competitively prevents girdin from interacting with dynamin 2 and confers the cargo selectivity for CME. Therefore, girdin regulates transferrin and E‐cadherin endocytosis in the center of cells and their subsequent polarized intracellular localization, but has no effect on integrin and epidermal growth factor receptor endocytosis that occurs at the cell periphery. Our results reveal that girdin regulates selective CME via a mechanism involving dynamin 2, but not by operating as a cargo‐specific adaptor.     

Cellular and structural insight into dynamin function during endocytic vesicle formation: a tale of 50 years of investigation

Dynamin is one of the major proteins involved in endocytosis. First identified 50 years ago in a genetic screen in Drosophila melanogaster, it has become a central player in many forms of endocytosis, such as clathrin-mediated endocytosis or synaptic vesicle endocytosis, as well as other important cellular processes such as actin remodelling. Decades of work using biochemical and structural studies, cell-free assays, live cell imaging, acute inhibition and genetic studies have led to important insights on its mode of action. Dynamin is a remarkable mechano-GTPase, which can do a lot to membranes on its own but which is, in cells, at the centre of a vast protein and lipid network and cannot work in isolation. This review summarizes the main features of dynamin structure and function and its central role in membrane remodelling events, and give an update on the latest results.     

900 MHz modulated electromagnetic fields accelerate the clathrin‐mediated endocytosis pathway

We report new data regarding the molecular mechanisms of GSM‐induced increase of cell endocytosis rate. Even though endocytosis represents an important physical and biological event for cell physiology, studies on modulated electromagnetic fields (EMF) effects on this process are scarce. In a previous article, we showed that fluid phase endocytosis rate increases when cultured cells are exposed to 900 MHz EMF similar to mobile phones' modulated GSM signals (217 Hz repetition frequency, 576 µs pulse width) and to electric pulses similar to the GSM electrical component. Trying to distinguish the mechanisms sustaining this endocytosis stimulation, we exposed murine melanoma cells to Lucifer Yellow (LY) or to GSM–EMF/electric pulses in the presence of drugs inhibiting the clathrin‐ or the caveolin‐dependent endocytosis. Experiments were performed at a specific absorption rate (SAR) of 3.2 W/kg in a wire patch cell under homogeneously distributed EMF field and controlled temperature (in the range of 28.5–29.5 °C). Thus, the observed increase in LY uptake was not a thermal effect. Chlorpromazine and ethanol, but not Filipin, inhibited this increase. Therefore, the clathrin‐dependent endocytosis is stimulated by the GSM–EMF, suggesting that the cellular mechanism affected by the modulated EMF involves vesicles that detach from the cell membrane, mainly clathrin‐coated vesicles. Bioelectromagnetics 30:222–230, 2009. © 2008 Wiley‐Liss, Inc.     

The evolution of dynamin to regulate clathrin-mediated endocytosis: speculations on the evolutionarily late appearance of dynamin relative to clathrin-mediated endocytosis

Whereas clathrin-mediated endocytosis (CME) exists in all eukaryotic cells, we first detect classical dynamin in Ichthyosporid, a single-cell, metazoan precursor. Based on a key functional residue in its pleckstrin homology domain, we speculate that the evolution of metazoan dynamin coincided with the specialized need for regulated CME during neurotransmission.     

Furrow-specific endocytosis during cytokinesis of zebrafish blastomeres

Mutations affecting endocytosis, such as those in clathrin and dynamin, unexpectedly cause defects in cytokinesis in a number of organisms. To explore the relationship between endocytosis and cytokinesis, we used the relatively large cells of the transparent zebrafish embryo. Using fluorescent markers for fluid-phase as well as plasma membrane uptake, we demonstrate that cytokinesis involves furrow-specific endocytosis. Clathrin-coated pits are visible near the furrow in ultrathin sections, while immunolabeling demonstrates that clathrin and caveolin are localized to the cleavage furrow. Hence, it is likely that both clathrin- and caveolae-mediated endocytosis occurs at the furrow during cytokinesis. Dynamin II is also localized to the furrow and may mediate furrow-specific endocytosis. Treatment of embryos with chlorpromazine or with methyl-beta-cyclodextrin, both of which inhibit endocytosis, prevents the normal completion of cytokinesis. These data suggest that furrow-specific endocytosis is an integral part of cytokinesis.     

Days and knights discussing membrane dynamics in endocytosis: meeting report from the Euresco/EMBL Membrane Dynamics in Endocytosis, 6--11 October in Tomar, Portugal

The Euresco/EMBL sponsored meeting on 'Membrane Dynamics in Endocytosis' took place on 6–11 October in Tomar, Portugal. Here we report on the 5 full days of exciting talks and active poster sessions that covered topics ranging from the mechanisms of clathrin-mediated endocytosis, the regulation of phagocytosis, caveolae dynamics and function, the role of lipids in regulating endocytic transport, the formation of and sorting into and out of multivesicular bodies, new links between the actin cytoskeleton and vesicular transport, and emerging roles for endocytic trafficking in signal transduction and development.     

Roles of cortactin, an actin polymerization mediator, in cell endocytosis

Cortactin, an actin-binding protein and a substrate of Src, is encoded by the EMS 1 oncogene. Cortactin is known to activate Arp2/3 complex-mediated actin polymerization and interact with dynamin, a large GTPase and proline rich domain-containing protein. Transferrin endocytosis was significantly reduced in cells by knock-down of cortactin expression as well as in vivo introduction of cortactin immunoreagents. Cortactin-dynamin interaction displayed morphologically dynamic co-distribution with a change in the endocytosis level in cells treated with an actin depolymerization reagent, cytochalasin D. In an in vitro beads assay, a branched actin network was recruited onto dynamin-coated beads in a cortactin Src homology domain 3 （SH3）-dependent manner. In addition, cortactin was found to function in the late stage of clathrin coated vesicle formation. Taken together, cortactin is required for optimal clathrin mediated endocytosis in a dynamin directed manner.