Gut thoughts on the Golgi complex

The new millennium coincides within 1 year of Camillo Golgi's centennial celebrations. It is quite remarkable that the structure and formation of this organelle is as controversial today as was its mere existence from Golgi's time to the 1950s, when EM approaches were introduced. Since the late 1950s, two opposing models of Golgi structure and function have split the Golgi scientific community, namely vesicular transport versus organelle maturation. Although a few years ago Golgi maturation seemed to be 'out for the count', it has recently seen an almost messianic revival. In this review, I argue that this large-scale desertion from the vesicle transport model to the maturation camp is premature. I propose an alternative, dynamic steady-state model, in which transient tubular connections function in parallel to vesicular transport and that the biosynthetic pathway is made up of three major distinct compartments: the ER, the Golgi and the TGN.     

Endocytic delivery to lysosomes mediated by concurrent fusion and kissing events in living cells

In mammalian cells, macromolecules internalized by endocytosis are transported via endosomes for digestion by lysosomal acid hydrolases . The mechanism by which endosomes and lysosomes exchange content remains equivocal . However, lysosomes are reusable organelles because they remain accessible to endocytic enzyme replacement therapies and undergo content mixing with late endosomes . The maturation model, which proposes that endosomes mature into lysosomes , cannot explain these observations. Three mechanisms for content mixing have been proposed. The first is vesicular transport, best supported by a yeast cell-free assay . The second suggests that endosomes and lysosomes engage in repeated transient fusions termed "kiss-and-run" . The third is that endosomes and lysosomes fuse completely, yielding hybrid compartments from which lysosomes reform , termed "fusion-fission" . We utilized time-lapse confocal microscopy to test these hypotheses in living cells. Lysosomes were loaded with rhodamine dextran by pulse-chase, and subsequently late endosomes were loaded with Oregon green 488 dextran. Direct fusions were observed between endosomes and lysosomes, and one such event was captured by correlative electron microscopy. Fluorescence intensity analyses of endosomes that encountered lysosomes revealed a gradual accumulation of lysosomal content. Our data are compatible with a requirement for direct contact between organelles before content is exchanged.     

On vesicles and membrane compartments

Summary Two different mechanisms have been proposed to explain transport along the endocytic and biosynthetic transport routes in cells. The first involves stable compartments connected by vesicular traffic while the second argues that the key organelles (early endosomes or the cis Golgi) form de novo by fusion of vesicles and subsequently mature into later forms. In the first part of this article, I propose a classification that distinguishes between stable, preexisting membrane compartments and vesicles that are, by definition, transient organelles. In this scheme, compartments, but not vesicles, are capable of homotypic fusion while vesicles, but not compartments, are able to mature, a process defined as an irreversible set of biochemical events which lead to a physiologically distinct end-state of the vesicle prior to its vectorial fusion with a target compartment. In the second part, I summarize my current ideas about the ultrastructural organization of the ER-Golgi region. Finally, I review the cell biology of selected examples of different vesicle types in order to exemplify the fascinating diversity of functions that this class of membrane organelles has evolved.Abbreviations COP coatomer - ECV endosome carrier vesicle - ER endoplasmic reticulum - HRP horseradish peroxidase - IC intermediate compartment between ER and Golgi - MVB multivesicular body - NSF N-ethyl maleimide sensitive factor - SNAPS soluble NSF associated proteins - TGN trans Golgi network Dedicated to Professor Eldon H. Newcomb in recognition of his contributions to cell biology     

Transport-dependent maturation of organelles in neurons

Some organelles show a spatial gradient of maturation along the neuronal process where more mature organelles are found closer to the cell body. This gradient is set up by progressive maturation steps that are aided by differential organelle distribution as well as transport. Autophagosomes and endosomes mature as they acquire lysosomal membrane proteins and decrease their luminal pH as they are retrogradely transported towards the cell body. The acquisition of lysosomal proteins along the neuronal processes likely occurs through fusion or membrane exchange events with Golgi-derived donor transport carriers that are transported anterogradely from the cell body. The mechanisms by which endosomes and autophagosomes mature might be applicable to other organelles that are transported along neuronal processes. Defects in axonal transport may also contribute to the accumulation of immature organelles in neurons. Such accumulations have been seen in neurons of neurodegenerative models.     

The Organelle Proteome of the DT40 Lymphocyte Cell Line

A major challenge in eukaryotic cell biology is to understand the roles of individual proteins and the subcellular compartments in which they reside. Here, we use the localization of organelle proteins by isotope tagging technique to complete the first proteomic analysis of the major organelles of the DT40 lymphocyte cell line. This cell line is emerging as an important research tool because of the ease with which gene knockouts can be generated. We identify 1090 proteins through the analysis of preparations enriched for integral membrane or soluble and peripherally associated proteins and localize 223 proteins to the endoplasmic reticulum, Golgi, lysosome, mitochondrion, or plasma membrane by matching their density gradient distributions to those of known organelle residents. A striking finding is that within the secretory and endocytic pathway a high proportion of proteins are not uniquely localized to a single organelle, emphasizing the dynamic steady-state nature of intracellular compartments in eukaryotic cells.The chicken pre-B cell line DT40 exhibits a remarkably high ratio of targeted to random integration for transfected DNA constructs. This property is unusual in vertebrate cell lines and enables targeted gene disruption experiments to be carried out with relative ease (1). Consequently, DT40 has become a major research tool for the molecular dissection of a wide range of cellular and biochemical mechanisms in a vertebrate context, including membrane traffic, signal transduction, and cell cycle (2).Proteins in eukaryotic cells are organized according to their functions within a dynamic network of membranes. Localization is therefore paramount in assigning functions to uncharacterized proteins and understanding the processes occurring in subcellular compartments. An increased knowledge of the protein localization within the DT40 cell line would be of great value. Traditional localization methods such as immunofluorescence microscopy are typically low throughput and are more suitably applied to the study of specific proteins of interest rather than the cataloguing of large numbers of proteins. Recent developments in proteomics have made it possible to analyze the protein composition of organelles using a variety of different approaches. Several groups have utilized label-free quantitative proteomics in the high throughput assignment of proteins to subcellular compartments. In one approach, protein correlation profiling, proteins from enriched organelle fractions are quantified by peptide ion intensity measurements (3, 4). Other similar methods employ quantitation by spectral counting, recording the number of ions detected per protein (5, 6). Localization of organelle proteins by isotope tagging (LOPIT)¹ is a complementary approach, which employs isotope labeling for quantitation (7–9). Rather than processing each sample separately as in label-free techniques, differentially labeled fractions are pooled early in the LOPIT protocol. This has the important advantage of reducing the points at which variation might be introduced into the data.LOPIT begins with the partial separation of organelles by density gradient centrifugation and relies on the assumption that proteins from each organelle co-fractionate. Protein profiles along the gradient are quantified by the use of isotopically coded tags in conjunction with two-dimensional liquid chromatography of peptides and tandem mass spectrometry. Multivariate statistical techniques are then used to assign localizations to proteins by comparing their gradient profiles to those of established organelle markers in an unbiased manner. The major strength of such an approach is that it enables residents of different subcellular compartments to be resolved even if their gradient distributions overlap, and genuine organelle constituents can be readily distinguished from contaminants.Here we use LOPIT to produce the first proteomic analysis of the major organelles of DT40. We have reproducibly identified 1090 proteins through the parallel analysis of preparations enriched for integral membrane or soluble and peripherally associated proteins. We use the distributions of 102 known organelle resident proteins as a basis to assign a further 223 proteins to five organelles: 79 to the endoplasmic reticulum (ER), 42 to the Golgi, 2 to the lysosome, 31 to the mitochondrion, and 69 to the plasma membrane (PM). We also demonstrate the resolution of components of the vesicular transport machinery. A striking finding is that a high proportion of identified proteins are not localized to a single organelle. This indicates that at steady state a substantial fraction of proteins are in transit between compartments, emphasizing the dynamic nature of intracellular organelles in eukaryotic cells. Our results represent the first application of LOPIT to a vertebrate system, provide the first organelle proteomic analysis of any lymphocyte cell line, and establish a major resource for the DT40 community.     

Kinesin is bound with high affinity to squid axon organelles that move to the plus-end of microtubules

This paper addresses the question of whether microtubule-directed transport of vesicular organelles depends on the presence of a pool of cytosolic factors, including soluble motor proteins and accessory factors. Earlier studies with squid axon organelles (Schroer et al., 1988) suggested that the presence of cytosol induces a > 20-fold increase in the number of organelles moving per unit time on microtubules in vitro. These earlier studies, however, did not consider that cytosol might nonspecifically increase the numbers of moving organelles, i.e., by blocking adsorption of organelles to the coverglass. Here we report that treatment of the coverglass with casein, in the absence of cytosol, blocks adsorption of organelles to the coverglass and results in vigorous movement of vesicular organelles in the complete absence of soluble proteins. This technical improvement makes it possible, for the first time, to perform quantitative studies of organelle movement in the absence of cytosol. These new studies show that organelle movement activity (numbers of moving organelles/min/micron microtubule) of unextracted organelles is not increased by cytosol. Unextracted organelles move in single directions, approximately two thirds toward the plus-end and one third toward the minus-end of microtubules. Extraction of organelles with 600 mM KI completely inhibits minus-end, but not plus-end directed organelle movement. Upon addition of cytosol, minus-end directed movement of KI organelles is restored, while plus--end directed movement is unaffected. Biochemical studies indicate that KI-extracted organelles attach to microtubules in the presence of AMP-PNP and copurify with tightly bound kinesin. The bound kinesin is not extracted from organelles by 1 M KI, 1 M NaCl or carbonate (pH 11.3). These results suggest that kinesin is irreversibly bound to organelles that move to the plus-end of microtubules and that the presence of soluble kinesin and accessory factors is not required for movement of plus-end organelles in squid axons.     

Protein transport in plant cells: in and out of the Golgi

In plant cells, the Golgi apparatus is the key organelle for polysaccharide and glycolipid synthesis, protein glycosylation and protein sorting towards various cellular compartments. Protein import from the endoplasmic reticulum (ER) is a highly dynamic process, and new data suggest that transport, at least of soluble proteins, occurs via bulk flow. In this Botanical Briefing, we review the latest data on ER/Golgi inter-relations and the models for transport between the two organelles. Whether vesicles are involved in this transport event or if direct ER-Golgi connections exist are questions that are open to discussion. Whereas the majority of proteins pass through the Golgi on their way to other cell destinations, either by vesicular shuttles or through maturation of cisternae from the cis- to the trans-face, a number of membrane proteins reside in the different Golgi cisternae. Experimental evidence suggests that the length of the transmembrane domain is of crucial importance for the retention of proteins within the Golgi. In non-dividing cells, protein transport out of the Golgi is either directed towards the plasma membrane/cell wall (secretion) or to the vacuolar system. The latter comprises the lytic vacuole and protein storage vacuoles. In general, transport to either of these from the Golgi depends on different sorting signals and receptors and is mediated by clathrin-coated and dense vesicles, respectively. Being at the heart of the secretory pathway, the Golgi (transiently) accommodates regulatory proteins of secretion (e.g. SNAREs and small GTPases), of which many have been cloned in plants over the last decade. In this context, we present a list of regulatory proteins, along with structural and processing proteins, that have been located to the Golgi and the 'trans-Golgi network' by microscopy.     

Insights into the role of the membranes in Rab GTPase regulation

Rab GTPases are molecular switches with essential roles in mediating vesicular trafficking and establishing organelle identity. The conversion from the inactive, cytosolic to the membrane-bound, active species and back is tightly controlled by regulatory proteins. Recently, the roles of membrane properties and lipid composition of different target organelles in determining the activity state of Rabs have come to light. The investigation of several Rab guanine nucleotide exchange factors (GEFs) has revealed principles of how the recruitment via lipid interactions and the spatial confinement on the membrane surface contribute to spatiotemporal specificity in the Rab GTPase network. This paints an intricate picture of the control mechanisms in Rab activation and highlights the importance of the membrane lipid code in the organization of the endomembrane system.     

Morphological analysis of protein transport from the ER to Golgi membranes in digitonin-permeabilized cells: role of the P58 containing compartment

The glycoside digitonin was used to selectively permeabilize the plasma membrane exposing functionally and morphologically intact ER and Golgi compartments. Permeabilized cells efficiently transported vesicular stomatitis virus glycoprotein (VSV-G) through sealed, membrane-bound compartments in an ATP and cytosol dependent fashion. Transport was vectorial. VSV-G protein was first transported to punctate structures which colocalized with p58 (a putative marker for peripheral punctate pre-Golgi intermediates and the cis-Golgi network) before delivery to the medial Golgi compartments containing alpha-1,2-mannosidase II and processing of VSV-G to endoglycosidase H resistant forms. Exit from the ER was inhibited by an antibody recognizing the carboxyl-terminus of VSV-G. In contrast, VSV-G protein colocalized with p58 in the absence of Ca2+ or the presence of an antibody which inhibits the transport component NSF (SEC18). These studies demonstrate that digitonin permeabilized cells can be used to efficiently reconstitute the early secretory pathway in vitro, allowing a direct comparison of the morphological and biochemical events involved in vesicular tafficking, and identifying a key role for the p58 containing compartment in ER to Golgi transport.     

Modeling Fusion/Fission‐Dependent Intracellular Transport of Fluid Phase Markers

A fundamental feature of eukaryotic cells is the presence of distinct membrane‐bound compartments having unique protein and lipid composition. These compartments are interconnected by active trafficking mechanisms that must direct macromolecules to defined locations, and at the same time maintain the protein and lipid composition of each organelle. It is well accepted that Rab proteins play a central role in intracellular transport regulating the recognition, fusion and fission of organelles. However, how the transport is achieved is not completely understood. We propose a model whereby a soluble component in the luminal compartment is transported along different Rab‐containing organelles that interact according to the following simple principles: (i) only organelles with the same or compatible Rab membrane domains can fuse; (ii) after fusion, an asymmetric fission occurs producing a tubule and a round‐shaped vesicle; and (iii) Rab membrane domains distribute asymmetrically between the two resulting organelles. When this model was tested in a simulation, efficient unidirectional transport was observed, while the compartment identity was preserved. All three principles were absolutely necessary for transport. The model is compatible with Rab association/dissociation dynamics and with Rab conversion. In simulations mimicking a simplified endocytic pathway, soluble and membrane‐associated markers were efficiently transported preserving the identity of the interacting compartments.     

RAB GTPases and SNAREs at the trans-Golgi network in plants

Membrane traffic is a fundamental cellular system to exchange proteins and membrane lipids among single membrane-bound organelles or between an organelle and the plasma membrane in order to keep integrity of the endomembrane system. RAB GTPases and SNARE proteins, the key regulators of membrane traffic, are conserved broadly among eukaryotic species. However, genome-wide analyses showed that organization of RABs and SNAREs that regulate the post-Golgi transport pathways is greatly diversified in plants compared to other model eukaryotes. Furthermore, some organelles acquired unique properties in plant lineages. Like in other eukaryotic systems, the trans-Golgi network of plants coordinates secretion and vacuolar transport; however, uniquely in plants, it also acts as a platform for endocytic transport and recycling. In this review, we focus on RAB GTPases and SNAREs that function at the TGN, and summarize how these regulators perform to control different transport pathways at the plant TGN. We also highlight the current knowledge of RABs and SNAREs’ role in regulation of plant development and plant responses to environmental stimuli.

     

Single microtubules from squid axoplasm support bidirectional movement of organelles

Single filaments, dissociated from the extruded axoplasm of the squid giant axon and visualized by video-enhanced differential interference contrast microscopy, transport organelles bidirectionally. Organelles moving in the same or opposite directions along the same filament can pass each other without colliding, indicating that each transport filament has several tracks for organelle movement. In order to characterize transport filaments, organelle movements were first examined by video microscopy, and then the same filaments were examined by electron microscopy after rapid-freezing, freeze-drying, and rotary-shadowing. Transport filaments that supported bidirectional movement of organelles are 22 nm to 27 nm in diameter and have a substructure indicative of a single microtubule. Immunofluorescence showed that virtually all transport filaments contain tubulin. These results show that single microtubules can serve as a substratum for organelle movement, and suggest that an interaction between organelles and microtubules is the basis of fast axonal transport.     

Regulation of vesicular and tubular membrane traffic of the Golgi complex by coat proteins.

Transport of cargo through and from the Golgi complex is mediated by vesicular carriers and transient tubular connections. Two classes of vesicle have been implicated in the biosynthetic or anterograde membrane traffic of this organelle. Both classes of vesicle are coated on the cytoplasmic surface with proteins, of which at least one component is related. Tubular connections also enable exchange of material between membrane-bounded compartments associated with the Golgi complex, most obviously in cells that have been treated with the drug, brefeldin A. Coat proteins appear to be involved in the regulation of these transport processes. Their putative functions include sorting of cargo, as well as regulation of budding, fusion or targeting of the membrane carriers.     

Powering membrane traffic in endocytosis and recycling

Early in evolution, the diversification of membrane-bound compartments that characterize eukaryotic cells was accompanied by the elaboration of molecular machineries that mediate intercompartmental communication and deliver materials to specific destinations. Molecular motors that move on tracks of actin filaments or microtubules mediate the movement of organelles and transport between compartments. The subjects of this review are the motors that power the transport steps along the endocytic and recycling pathways, their modes of attachment to cargo and their regulation.     

Protein trafficking in plant cells: Tools and markers

Eukaryotic cells consist of numerous membrane-bound organelles,which compartmentalize cellular materials to fulfil a variety of vital functions.In the post-genomic era,it is widely recognized that identification of the subcellular organelle localization and transport mechanisms of the encoded proteins are necessary for a fundamental understanding of their biological functions and the organization of cellular activity.Multiple experimental approaches are now available to determine the subcellular localizations and dynamics of proteins.In this review,we provide an overview of the current methods and organelle markers for protein subcellular localization and trafficking studies in plants,with a focus on the organelles of the endomembrane system.We also discuss the limitations of each method in terms of protein colocalization studies.     

Toxoplasma gondii Vps11, a subunit of HOPS and CORVET tethering complexes,is essential for the biogenesis of secretory organelles

Apicomplexan parasites harbour unique secretory organelles (dense granules, rhoptries and micronemes) that play essential functions in host infection. Toxoplasma gondii parasites seem to possess an atypical endosome‐like compartment, which contains an assortment of proteins that appear to be involved in vesicular sorting and trafficking towards secretory organelles. Recent studies highlighted the essential roles of many regulators such as Rab5A, Rab5C, sortilin‐like receptor and syntaxin‐6 in secretory organelle biogenesis. However, little is known about the protein complexes that recruit Rab‐GTPases and SNAREs for membrane tethering in Apicomplexa. In mammals and yeast, transport, tethering and fusion of vesicles from early endosomes to lysosomes and the vacuole, respectively, are mediated by CORVET and HOPS complexes, both built on the same Vps‐C core that includes Vps11 protein. Here, we show that a T. gondii Vps11 orthologue is essential for the biogenesis or proper subcellular localization of secretory organelle proteins. TgVps11 is a dynamic protein that associates with Golgi endosomal‐related compartments, the vacuole and immature apical secretory organelles. Conditional knock‐down of TgVps11 disrupts biogenesis of dense granules, rhoptries and micronemes. As a consequence, parasite motility, invasion, egress and intracellular growth are affected. This phenotype was confirmed with additional knock‐down mutants of the HOPS complex. In conclusion, we show that apicomplexan parasites use canonical regulators of the endolysosome system to accomplish essential parasite‐specific functions in the biogenesis of their unique secretory organelles.     

Golgi apparatus: Homotypic fusion maintains biochemical gradients within the Golgi and improves the accuracy of protein maturation

Eukaryotic cells are compartmentalized into organelles which, although constantly exchanging proteins and lipids with their environment, maintain a relatively well-defined biochemical identity. How can such large heterogeneities of chemical composition between (and within) organelles be maintained if different organelles are in constant contact through mass transport? Generic nonlinearities in the transport processes, as would result from specific molecular interactions, can cause the spontaneous chemical differentiation of interacting organelles and compartments within organelles. For the Golgi apparatus, the role of which is to process an incoming flux of lipids and proteins, this spontaneous differentiation decreases inter-cisternal exchange and increases the protein transit time under conditions of high incoming flux, This mechanism enables the Golgi apparatus to spontaneously adjust the protein transit time to the amount of protein requiring processing, thereby improving the processing accuracy of even a limited amount of maturation enzymes.     

Piecing together the structural organisation of lipid exchange at membrane contact sites

Membrane contact sites (MCSs) are areas of close proximity between organelles, implicated in transport of small molecules and in organelle biogenesis. Lipid transfer proteins at MCSs facilitate the distribution of lipid species between organelle membranes. Such exchange processes rely on the apposition of two different membranes delimiting distinct compartments and a cytosolic intermembrane space. Maintaining organelle identity while transferring molecules therefore implies control over MCS architecture both on the ultrastructural and molecular levels. Factors including intermembrane distance, density of resident proteins, and contact surface area fine-tune MCS function. Furthermore, the structural arrangement of lipid transfer proteins and associated proteins underpins the molecular mechanisms of lipid fluxes at MCSs. Thus, the architecture of MCSs emerges as an essential aspect of their function.