Solubilization of UDP-glucose collagen glucosyltransferase activities from chick embryo liver: Golgi apparatus, smooth and rough endoplasmic reticulum.

1. The choice of a suitable detergent for solubilization of UDP-glucose collagen glucosyltransferase (GGT) activities from chick embryo liver has been investigated. Several detergents were used (zwitterionic detergent as Chaps, and non-ionic detergents as Triton X-100, Nonidet P 40, Brij 35). 2. All the detergents with GGT activities were tested in Golgi apparatus, smooth and rough endoplasmic reticulum (SER, RER). 3. 80-100% GGT Golgi apparatus activity was easily solubilized at low concentrations in surfactant (0.5 mg/ml). 25-78% of SER and RER GGT activities were extracted at this concentration. 4. A higher level of detergent (5 mg/ml) was necessary to release all GGT activities of SER and RER. Protein extraction was identical to GGT activities.     

Evidence of partial localization in Golgi apparatus of UDP-glucose collagen glucosyltransferase from chick embryo liver

1. Collagens are the most important components of the connective tissue. 2. Collagen synthesis involves greater than 12 different enzymes whereas three enzymatic systems are involved in the ordered degradation. 3. Some enzymes are found in the rough endoplasmic reticulum (RER). The subcellular localization of disulfur isomerase, alpha D-glucosidase, proteases, galactosyltransferases and glucosyltransferases specific to collagen is unknown. 4. After having determined the best subcellular fractionation conditions for the chick embryo liver, we demonstrate that the galactosylhydroxylysyl glucosyltransferase specific to collagen is located in the RER and in the Golgi apparatus.     

Positioning the Golgi apparatus

Ríos et al. (2004) report in this issue that the Golgi protein GMAP-210 is sufficient to confer pericentrosomal positioning and recruits gamma-tubulin and associated microtubule-nucleating ring complex proteins to Golgi membranes. The results raise the possibility that short microtubules emanate from the Golgi to mediate its organization and positioning.     

Effect of phospholipids on UDP-glucose: ceramide glucosyltransferase from Golgi membranes

1. The removal of phospholipids completely abolished the activity of the enzyme UDP-glucose:ceramide glucosyltransferase from Golgi membranes. 2. Modulation of enzyme activity by phospholipids was undertaken on the solubilized form of the enzyme. 3. Well-defined fatty acyl chains and polar head groups were necessary for maximal stimulation by phospholipids. 4. A specific requirement for phosphatidylcholine is suggested by preliminary experiments of reconstitution of enzyme activity with phosphatidylcholine vesicles.     

Subcompartmentalizing the Golgi apparatus

The subcompartmentalized structure of the Golgi apparatus contributes to efficient glycosylation in the secretory pathway. Subcompartmentalization driven by maturation relies primarily on constant and accurate vesicle-mediated local recycling of Golgi residents. The precision of this vesicle transport is dependent on the interplay between the key factors that mediate vesicle budding and fusion--the coat proteins and the SNARE fusion machinery. These alone, however, may not be sufficient to ensure establishment of compartments de novo, and additional regulatory mechanisms operate to modify their activity.     

Camillo Golgi and the discovery of the Golgi apparatus

 Camillo Golgi (1843–1926) was born at Corteno, near Brescia, in northern Italy. After graduating in Medicine at the ancient University of Pavia, the former seat of great scientists and naturalists, Golgi continued a long-standing Italian tradition by studying the histology of the nervous system. While working as a modest physician at Abbiategrasso, a small town near Pavia, he developed a silver–osmium technique, the ”reazione nera” (black reaction), for which he was awarded the Nobel Prize in 1906. In the late 1890’s, 25 years after the publication of his black reaction and while Professor of General Pathology in Pavia, Golgi noticed a fine internal network in only partially silver-osmium-blackened Purkinje cells. Following confirmation by his assistant Emilio Veratti, Golgi published the discovery, called the ”apparato reticolare interno”, in the Bollettino della Società medico-chirurgica di Pavia in 1898, which is now considered the birthday of the ”Golgi apparatus”. The discovery of the Golgi apparatus can be added to the long list of accidental discoveries. The man after whom it is named was not a cytologist engaged in studying the inner structure of the cell, but a pathologist searching to prove a neuroanatomical theory. Accepted: 24 October 1997     

Organization of the Golgi apparatus

Investigators are revisiting basic concepts of the structure-function relationships of the Golgi apparatus. A key issue is the properties of the transport carriers that operate within the secretory pathway. Golgi morphology and dynamics differ between species but data from various model systems are pointing toward an integrated view of Golgi organization.     

Lipoprotein particles from the Golgi apparatus of guinea-pig liver

1. A cell fraction has been isolated from guinea-pig liver and shown to be rich in Golgi apparatus by electron microscopy. The activity of UDP-d-galactose-N-acetylglucosamine galactosyltransferase was over 100-fold greater in this cell fraction than in the liver homogenate. These data support the conclusion that the fraction was enriched in Golgi apparatus. 2. The Golgi cisternae and secretory vesicles contained electron-dense particles of 10-80nm diameter. Disruption of the Golgi apparatus cell fraction released these particles, which were separated into VLD (very-low-density) and LD (low-density) species on the basis of their density. 3. The Golgi VLD particles possessed morphological, flotational, chemical and immunochemical properties which closely resembled those of the serum VLD lipoproteins from the same animals. 4. The Golgi LD particles were rich in phospholipid, containing 48.1% by weight. The chemical composition of these particles was quite distinct from that of the serum LD lipoproteins, but did, however, show some similarity to that of the serum VLD lipoproteins. A marked resemblance was noted in the chemical characteristics of the Golgi LD and VLD particles (with the exception of triglyceride content). In addition, these two species of Golgi particles possessed the same antigenic determinant. 5. The results suggest that the Golgi VLD particles are the precursors of the serum VLD lipoproteins. On the basis of similarities in gross chemical composition and in the antigenic determinant of the Golgi LD and VLD particles, we conclude that the LD particles are probably the precursors of the VLD particles. In view of the marked differences in gross chemical composition of the Golgi LD particles and serum LD lipoproteins, it appears unlikely that the LD particles are directly secreted into the serum pool.     

Deciphering the Golgi apparatus: from imaging to genes

The Golgi apparatus is a vital organelle in eukaryotic cells. It grabs and processes secretory materials synthesized by the endoplasmic reticulum (ER) before sorting them to their destination. The Golgi also receives materials from vacuoles/lysosomes and the plasma membrane for further recycling to other compartments within the cell (1) (Figure 1). Given the vital role of the Golgi in a cell, it is important to understand how this organelle attains and maintains its structural and functional integrity during the intense processes of membrane traffic. Despite an equally central role of the Golgi in membrane traffic in eukaryotes, the organization of this organelle has some unique features in each cell system. Therefore, the wealth of information available on the structure and activity of the Golgi in one system is not always directly transferable to others. However, certain morphological and functional aspects are common among cell systems. Therefore, studying the factors that regulate organelle biogenesis and organization of the Golgi apparatus is important in basic cell biology of eukaryotes and may also contribute to a better understanding of how different cell systems have evolved. In this study, we report on the identification of Golgi mutants in plant cells. We have developed a screen that is a promising strategy not only for the identification of genes responsible for the morphological and functional integrity of the plant Golgi but could also provide fundamental information on other multicellular systems for which the power of forward genetics cannot be exploited as easily as in Arabidopsis.     

Calcium in the Golgi apparatus

The secretory-pathway Ca2+-ATPases (SPCAs) represent a recently recognized family of phosphorylation-type ATPases that supply the lumen of the Golgi apparatus with Ca2+ and Mn2+ needed for the normal functioning of this structure. Mutations of the human SPCA1 gene (ATP2C1) cause Hailey-Hailey disease, an autosomal dominant skin disorder in which keratinocytes in the suprabasal layer of the epidermis detach. We will first review the physiology of the SPCAs and then discuss how mutated SPCA1 proteins can lead to an epidermal disorder.     

Derlin-dependent retrograde transport from endosomes to the Golgi apparatus

Cells have to maintain stable plasma membrane protein and lipid compositions under normal conditions and to remodel their plasma membranes in response to stimuli. This maintenance and remodeling require that integral membrane proteins at the plasma membrane that become misfolded, because of the relatively harsher extracellular milieu or carbohydrate and amino acid sequence changes, are degraded. We had previously shown that Derlin proteins, required for quality control mechanisms in the endoplasmic reticulum, also localize to endosomes and function in the degradation of misfolded integral membrane proteins at the plasma membrane. In this study, we show that Derlin proteins physically associate with sorting nexins that function in retrograde membrane transport from endosomes to the Golgi apparatus. Using genetic studies in Caenorhabditis elegans and ricin pulse-chase analyses in murine RAW264.7 macrophages, we show that the Derlin-sorting nexin interaction is physiologically relevant. Our studies suggest that at least some integral membrane proteins that are misfolded at the plasma membrane are retrogradely transported to the Golgi apparatus and ultimately to the endoplasmic reticulum for degradation via resident quality control mechanisms.     

Structure of Golgi apparatus

Summary Golgi apparatus (GA) of eukaryotic cells consist of one or more stacks of flattened saccules (cisternae) and an array of fenestrae and tubules continuous with the peripheral edges of the saccules. Golgi apparatus also are characterized by zones of exclusion that surround each stack and by an assortment of vesicles (or vesicle buds) associated with both the stacks and the peripheral tubules of the stack cisternae. Each stack (sometimes referred to as Golgi apparatus, Golgi complex, or dictyosome) is structurally and functionally polarized, reflecting its role as an intermediate between the endoplasmic reticulum, the cell surface, and the lysosomal system of the cell. There is probably only one GA per cell, and all stacks of the GA appear to function synchronously. All Golgi apparatus are involved in the generation and movement of product and membrane within the cell or to the cell exterior, and these functions are often reflected as structural changes across the stacks. For example, in plants, both product and membrane appear to maturate from the cis to the trans poles of the stacks in a sequential, or serial, manner. However, there is also strong ultrastructural evidence in plants for a parallel input to the stack saccules, probably through the peripheral tubules. The same modes of functioning probably also occur in animal GA; although here, the parallel mode of functioning almost surely predominates. In some cells at least, GA stacks give rise to tubular-vesicular structures that resemble the trans Golgi network. Rudimentary GA, consisting of tubular-vesicular networks, have been identified in fungi and may represent an early stage of GA evolution.     

Cytochemical contributions to differentiating GERL from the Golgi apparatus

Synopsis Recent studies from our laboratory are described which deal with endocrine cells (insulinoma, -cells of the pancreas, thyroid epithelial cells), pancreatic exocrine cells, and hepatocytes. These emphasize the importance of the hydrolase-rich specialized region of endoplasmic reticulum, known as GERL, in secretory cells. Also reviewed in this paper are the varied molecular transformations which apparently occur in GERL in different cell types, as reported from other laboratories as well as our own. Evidence of the continuity of GERL with rough endoplasmic reticulum is presented. Two hydrolytic enzyme activities in GERL, in addition to acid phosphatase activity, are recorded. Finally, the use of cytochemical staining procedures in the study of microperoxisomes is briefly described. The Histochemical Journal lecture 1976. Delivered to the Histochemistry and Cytochemistry Section of the Royal Microscopical Society on 14 September 1976     

Intercisternal substances of the Golgi apparatus

Summary In media of high ionic strength, neutral pH, low temperature, and varying ion composition, plant dictyosomes were disassembled into component cisternae. The effective ions included phosphotungstate and several halides. Constituents of the intercisternal or bonding regions were revealed through electron microscope analysis. These included intercisternal elements and electrontransparent plaques of undetermined composition. The intercisternal plaques were confined to the central platelike regions of cisternae and were distinct from the intercisternal fibers. The findings demonstrate that plant dictyosomes can be dissociated into component cisternae. With monovalent halide salts, the unstacking process was sufficiently mild to reveal constituents of the intercisternal region as well as yield intact single cisternae.     

The Golgi apparatus: defining the identity of Golgi membranes

The Golgi apparatus is a stack of compartments that serves as a central junction for membrane traffic, with carriers moving through the stack as well as arriving from, and departing toward, many other destinations in the cell. This requires that the different compartments in the Golgi recruit from the cytosol a distinct set of proteins to mediate accurate membrane traffic. This recruitment appears to reflect recognition of small GTPases of the Rab and Arf family, or of lipid species such as PtdIns(4)P and diacylglycerol, which provide a unique "identity" for each compartment. Recent work is starting to reveal the mechanisms by which these labile landmarks are generated in a spatially restricted manner on specific parts of the Golgi.     

Structural organization of the Golgi apparatus

The Golgi apparatus is a universal feature of eukaryotes, carrying out the key functions of processing, sorting and trafficking of newly synthesized membrane and secretory proteins. The Golgi apparatus has a clearly defined structure, comprising stacks of flattened cisternal membranes that in vertebrates are connected to form a ribbon. How this structure is maintained and how it relates to the functions of the Golgi apparatus has long been an area of interest. In this review I describe recent progress in the identification and characterization of the molecular machinery that together help generate the characteristic organization of this organelle.