The Yeast GRASP Grh1 Colocalizes with COPII and Is Dispensable for Organizing the Secretory Pathway

In mammalian cells, the ‘Golgi reassembly and stacking protein’ (GRASP) family has been implicated in Golgi stacking, but the broader functions of GRASP proteins are still unclear. The yeast Saccharomyces cerevisiae contains a single non‐essential GRASP homolog called Grh1. However, Golgi cisternae in S. cerevisiae are not organized into stacks, so a possible structural role for Grh1 has been difficult to test. Here, we examined the localization and function of Grh1 in S. cerevisiae and in the related yeast Pichia pastoris, which has stacked Golgi cisternae. In agreement with earlier studies indicating that Grh1 interacts with coat protein II (COPII) vesicle coat proteins, we find that Grh1 colocalizes with COPII at transitional endoplasmic reticulum (tER) sites in both yeasts. Deletion of P. pastoris Grh1 had no obvious effect on the structure of tER–Golgi units. To test the role of S. cerevisiae Grh1, we exploited the observation that inhibiting ER export in S. cerevisiae generates enlarged tER sites that are often associated with the cis Golgi. This tER–Golgi association was preserved in the absence of Grh1. The combined data suggest that Grh1 acts early in the secretory pathway, but is dispensable for the organization of secretory compartments.     

Segregation of the Qb‐SNAREs GS27 and GS28 into Golgi Vesicles Regulates Intra‐Golgi Transport

The Golgi apparatus is the main glycosylation and sorting station along the secretory pathway. Its structure includes the Golgi vesicles, which are depleted of anterograde cargo, and also of at least some Golgi‐resident proteins. The role of Golgi vesicles remains unclear. Here, we show that Golgi vesicles are enriched in the Qb‐SNAREs GS27 (membrin) and GS28 (GOS‐28), and depleted of nucleotide sugar transporters. A block of intra‐Golgi transport leads to accumulation of Golgi vesicles and partitioning of GS27 and GS28 into these vesicles. Conversely, active intra‐Golgi transport induces fusion of these vesicles with the Golgi cisternae, delivering GS27 and GS28 to these cisternae. In an in vitro assay based on a donor compartment that lacks UDP‐galactose translocase (a sugar transporter), the segregation of Golgi vesicles from isolated Golgi membranes inhibits intra‐Golgi transport; re‐addition of isolated Golgi vesicles devoid of UDP‐galactose translocase obtained from normal cells restores intra‐Golgi transport. We conclude that this activity is due to the presence of GS27 and GS28 in the Golgi vesicles, rather than the sugar transporter. Furthermore, there is an inverse correlation between the number of Golgi vesicles and the number of inter‐cisternal connections under different experimental conditions. Finally, a rapid block of the formation of vesicles via COPI through degradation of ϵCOP accelerates the cis‐to‐trans delivery of VSVG. These data suggest that Golgi vesicles, presumably with COPI, serve to inhibit intra‐Golgi transport by the extraction of GS27 and GS28 from the Golgi cisternae, which blocks the formation of inter‐cisternal connections .     

Sequential Depletion and Acquisition of Proteins during Golgi Stack Disassembly and Reformation

Herein, we report the stepwise transport of multiple plant Golgi membrane markers during disassembly of the Golgi apparatus in tobacco leaf epidermal cells in response to the induced expression of the GTP‐locked Sar1p or Brefeldin A (BFA), and reassembly on BFA washout. The distribution of fluorescent Golgi‐resident N‐glycan processing enzymes and matrix proteins (golgins) with specific cis–trans‐Golgi sub‐locations was followed by confocal microscopy during disassembly and reassembly. The first event during Golgi disassembly was the loss of trans‐Golgi enzymes and golgins from Golgi membranes, followed by a sequential redistribution of medial and cis‐Golgi enzymes into the endoplasmic reticulum (ER), whilst golgins were relocated to the ER or cytoplasm. This event was confirmed by fractionation and immuno‐blotting. The sequential redistribution of Golgi components in a trans–cis sequence may highlight a novel retrograde trafficking pathway between the trans‐Golgi and the ER in plants. Release of Golgi markers from the ER upon BFA washout occurred in the opposite sequence, with cis‐matrix proteins labelling Golgi‐like structures before cis/medial enzymes. Trans‐enzyme location was preceded by trans‐matrix proteins being recruited back to Golgi membranes. Our results show that Golgi disassembly and reassembly occur in a highly ordered fashion in plants.     

Golgi apparatus activity and membrane flow during scale biogenesis in the green flagellateScherffelia dubia (Prasinophyceae). I: Flagellar regeneration

Summary Cells ofScherffelia dubia regenerate flagella with a complete scale covering after experimental flagellar amputation. Flagellar regeneration was used to study Golgi apparatus (GA) activity during flagellar scale production. By comparing the number of scales present on mature flagella with the flagellar regeneration kinetics, it is calculated that each cell produces ca. 260 scales per minute during flagellar regeneration. Flagellar scales are assembled exclusively in the GA and abstricted from the rims of thetrans-most GA cisternae into vesicles. Exocytosis of scales occurs at the base of the anterior flagellar groove. The central portion of thetrans-most cisterna, containing no scales, detaches from the stack of cisternae and develops a coat to become a coated polygonal vesicle. Scale biogenesis involves continuous turnover of GA cisternae, and scale production rates indicate maturation of four cisternae per minute from each of the cells two dictyosomes. A possible model of membrane flow routes during flagellar regeneration, which involves a membrane recycling loop via the coated polygonal vesicles, is presented.     

Silencing of Mammalian Sar1 Isoforms Reveals COPII‐Independent Protein Sorting and Transport

The Sar1 GTPase coordinates the assembly of coat protein complex‐II (COPII) at specific sites of the endoplasmic reticulum (ER). COPII is required for ER‐to‐Golgi transport, as it provides a structural and functional framework to ship out protein cargoes produced in the ER. To investigate the requirement of COPII‐mediated transport in mammalian cells, we used small interfering RNA (siRNA)‐mediated depletion of Sar1A and Sar1B. We report that depletion of these two mammalian forms of Sar1 disrupts COPII assembly and the cells fail to organize transitional elements that coordinate classical ER‐to‐Golgi protein transfer. Under these conditions, minimal Golgi stacks are seen in proximity to juxtanuclear ER membranes that contain elements of the intermediate compartment, and from which these stacks coordinate biosynthetic transport of protein cargo, such as the vesicular stomatitis virus G protein and albumin. Here, transport of procollagen‐I is inhibited. These data provide proof‐of‐principle for the contribution of alternative mechanisms that support biosynthetic trafficking in mammalian cells, providing evidence of a functional boundary associated with a bypass of COPII .     

Interaction of Golgin‐84 with the COG Complex Mediates the Intra‐Golgi Retrograde Transport

The coiled‐coil Golgi membrane protein golgin‐84 functions as a tethering factor for coat protein I (COPI) vesicles. Protein interaction analyses have revealed that golgin‐84 interacts with another tether, the conserved oligomeric Golgi (COG) complex, through its subunit Cog7. Therefore, we explored the function of golgin‐84 as the tether for COPI vesicles of intra‐Golgi retrograde traffic. First, glycosylic maturation of both plasma membrane (CD44) and lysosomal (lamp1) glycoproteins was distorted in golgin‐84 knockdown (KD) cells. The depletion of golgin‐84 caused fragmentation of the Golgi with the mislocalization of Golgi resident proteins, resulting in the accumulation of vesicles carrying intra‐Golgi soluble N‐ethylmaleimide‐sensitive factor attachment protein receptors (SNAREs) and cis‐Golgi membrane protein GPP130. Similar observations were obtained by diminution of the COG complex, suggesting a strong correlation between the two tethers. Indeed, COG complex‐dependent (CCD) vesicles that accumulate in Cog3 or Cog7 KD cells carried golgin‐84. Surprisingly, the interaction between golgin‐84 and another candidate tethering partner CASP (CDP/cut alternatively spliced product) decreased in Cog3 KD cells. These results indicate that golgin‐84 on COPI vesicles interact with the COG complex before SNARE assembly, suggesting that the interaction of golgin‐84 with COG plays an important role in the tethering process of intra‐Golgi retrograde vesicle traffic.     

A Model for the Self-Organization of Vesicular Flux and Protein Distributions in the Golgi Apparatus

The generation of two non-identical membrane compartments via exchange of vesicles is considered to require two types of vesicles specified by distinct cytosolic coats that selectively recruit cargo, and two membrane-bound SNARE pairs that specify fusion and differ in their affinities for each type of vesicles. The mammalian Golgi complex is composed of 6–8 non-identical cisternae that undergo gradual maturation and replacement yet features only two SNARE pairs. We present a model that explains how distinct composition of Golgi cisternae can be generated with two and even a single SNARE pair and one vesicle coat. A decay of active SNARE concentration in aging cisternae provides the seed for a cis trans SNARE gradient that generates the predominantly retrograde vesicle flux which further enhances the gradient. This flux in turn yields the observed inhomogeneous steady-state distribution of Golgi enzymes, which compete with each other and with the SNAREs for incorporation into transport vesicles. We show analytically that the steady state SNARE concentration decays exponentially with the cisterna number. Numerical solutions of rate equations reproduce the experimentally observed SNARE gradients, overlapping enzyme peaks in cis, medial and trans and the reported change in vesicle nature across the Golgi: Vesicles originating from younger cisternae mostly contain Golgi enzymes and SNAREs enriched in these cisternae and extensively recycle through the Endoplasmic Reticulum (ER), while the other subpopulation of vesicles contains Golgi proteins prevalent in older cisternae and hardly reaches the ER.     

Evidence for prebudding arrest of ER export in animal cell mitosis and its role in generating Golgi partitioning intermediates

During mitosis the interconnected Golgi complex of animal cells breaks down to produce both finely dispersed elements and discrete vesiculotubular structures. The endoplasmic reticulum (ER) plays a controversial role in generating these partitioning intermediates and here we highlight the importance of mitotic ER export arrest in this process. We show that experimental inhibition of ER export (by microinjecting dominant negative Sar1 mutant proteins) is sufficient to induce and maintain transformation of Golgi cisternae to vesiculotubular remnants during interphase and telophase, respectively. We also show that buds on the ER, ER exit sites and COPII vesicles are markedly depleted in mitotic cells and COPII components Sec23p, Sec24p, Sec13p and Sec31p redistribute into the cytosol, indicating ER export is inhibited at an early stage. Finally, we find a markedly uneven distribution of Golgi residents over residual exit sites of metaphase cells, consistent with tubulovesicular Golgi remnants arising by fragmentation rather than redistribution via the ER. Together, these results suggest selective recycling of Golgi residents, combined with prebudding cessation of ER export, induces transformation of Golgi cisternae to vesiculotubular remnants in mitotic cells. The vesiculotubular Golgi remnants, containing populations of slow or nonrecycling Golgi components, arise by fragmentation of a depleted Golgi ribbon independently from the ER.     

A three-stage model of Golgi structure and function

The Golgi apparatus contains multiple classes of cisternae that differ in structure, composition, and function, but there is no consensus about the number and definition of these classes. A useful way to classify Golgi cisternae is according to the trafficking pathways by which the cisternae import and export components. By this criterion, we propose that Golgi cisternae can be divided into three classes that correspond to functional stages of maturation. First, cisternae at the cisternal assembly stage receive COPII vesicles from the ER and recycle components to the ER in COPI vesicles. At this stage, new cisternae are generated. Second, cisternae at the carbohydrate synthesis stage exchange material with one another via COPI vesicles. At this stage, most of the glycosylation and polysaccharide synthesis reactions occur. Third, cisternae at the carrier formation stage produce clathrin-coated vesicles and exchange material with endosomes. At this stage, biosynthetic cargo proteins are packaged into various transport carriers, and the cisternae ultimately disassemble. Discrete transitions occur as a cisterna matures from one stage to the next. Within each stage, the structure and composition of a cisterna can evolve, but the trafficking pathways remain unchanged. This model offers a unified framework for understanding the properties of the Golgi in diverse organisms.     

Cytomembranes in first cleavage xenopus embryos

Summary The ultrastructure and interrelationships of the Golgi body, endoplasmic reticulum and lipid droplets have been studied in the first cleavage Xenopus embryos. Lipid droplets, usually spherical or sometimes multilobed, did not have a discernible limiting membrane, although some had an incomplete electron dense partition. The Golgi bodies and endoplasmic reticulum were seen continuous with lipid droplets and the profiles indicated a probable formation of these membranes from lipid droplet material. Rough endoplasmic reticulum (ER) mainly consisted of paired tubular cisternae and vesicles containing filamentous material that gave a fringed appearance. The relationships of paired cisternae with the Golgi body suggested a transformation of ER membranes into the Golgi body membranes. In addition, paired ER cisternae showed a close apposition with the limiting membrane of the yolk platelet. Lone ER cisternae that contained moderately electron dense material instead of filaments were also present and showed numerous associated vesicles near the Golgi body. The Golgi body showed several morphological forms including a single fenestrated cisterna, two to four flat or cup-shaped cisternae, or up to seven cisternae, some of which were dilated and similar to fringed ER in appearance. These forms could be different developmental stages of the organelle. Coated vesicles were seen continuous with the cisternae of the Golgi body. A probable route for the assembly of the cell surface material has been proposed.This work was supported by a grant from the Medical Research Council of Canada to one of us (E.J.S.).     

ER arrival sites for COPI vesicles localize to hotspots of membrane trafficking

COPI‐coated vesicles mediate retrograde membrane traffic from the cis‐Golgi to the endoplasmic reticulum (ER) in all eukaryotic cells. However, it is still unknown whether COPI vesicles fuse everywhere or at specific sites with the ER membrane. Taking advantage of the circumstance that the vesicles still carry their coat when they arrive at the ER, we have visualized active ER arrival sites (ERAS) by monitoring contact between COPI coat components and the ER‐resident Dsl tethering complex using bimolecular fluorescence complementation (BiFC). ERAS form punctate structures near Golgi compartments, clearly distinct from ER exit sites. Furthermore, ERAS are highly polarized in an actin and myosin V‐dependent manner and are localized near hotspots of plasma membrane expansion. Genetic experiments suggest that the COPI?Dsl BiFC complexes recapitulate the physiological interaction between COPI and the Dsl complex and that COPI vesicles are mistargeted in dsl1 mutants. We conclude that the Dsl complex functions in confining COPI vesicle fusion sites.     

A distinct class of vesicles derived from the trans‐Golgi mediates secretion of xylogalacturonan in the root border cell

Root border cells lie on the surface of the root cap and secrete massive amounts of mucilage that contains polysaccharides and proteoglycans. Golgi stacks in the border cells have hypertrophied margins, reflecting elevated biosynthetic activity to produce the polysaccharide components of the mucilage. To investigate the three‐dimensional structures and macromolecular compositions of these Golgi stacks, we examined high‐pressure frozen/freeze‐substituted alfalfa root cap cells with electron microscopy/tomography. Golgi stacks in border cells and peripheral cells, precursor cells of border cells, displayed similar morphological features, such as proliferation of trans cisternae and swelling of the trans cisternae and trans‐Golgi network (TGN) compartments. These swollen margins give rise to two types of vesicles larger than other Golgi‐associated vesicles. Margins of trans‐Golgi cisternae accumulate the LM8 xylogalacturonan (XGA) epitope, and they become darkly stained large vesicles (LVs) after release from the Golgi. Epitopes for xyloglucan (XG), polygalacturonic acid/rhamnogalacturonan‐I (PGA/RG‐I) are detected in the trans‐most cisternae and TGN compartments. LVs produced from TGN compartments (TGN‐LVs) stained lighter than LVs and contained the cell wall polysaccharide epitopes seen in the TGN. LVs carrying the XGA epitope fuse with the plasma membrane only in border cells, whereas TGN‐LVs containing the XG and PGA/RG‐I epitopes fuse with the plasma membrane of both peripheral cells and border cells. Taken together, these results indicate that XGA is secreted by a novel type of secretory vesicles derived from trans‐Golgi cisternae. Furthermore, we simulated the collapse in the central domain of the trans‐cisternae accompanying polysaccharide synthesis with a mathematical model.     

Electron tomography of RabA4b- and PI-4Kβ1-labeled trans Golgi network compartments in Arabidopsis

The trans Golgi network (TGN) of plant cells sorts and packages Golgi products into secretory (SV) and clathrin-coated (CCV) vesicles. We have analyzed of TGN cisternae in Arabidopsis root meristem cells by cell fractionation and electron microscopy/tomography to establish reliable criteria for identifying TGN cisternae in plant cells, and to define their functional attributes. Transformation of a trans Golgi cisterna into a Golgi-associated TGN cisterna begins with cisternal peeling, the formation of SV buds outside the plane of the cisterna and a 30-35% reduction in cisternal membrane area. Free TGN compartments are defined as cisternae that have detached from the Golgi to become independent organelles. Golgi-associated and free TGN compartments, but not trans Golgi cisternae, bind anti-RabA4b and anti-phosphatidylinositol-4 kinase (PI-4K) antibodies. RabA4b and PI-4Kβ1 localize to budding SVs in the TGN and to SVs en route to the cell surface. SV and CCV release occurs simultaneously via cisternal fragmentation, which typically yields ～30 vesicles and one to four residual cisternal fragments. Early endosomal markers, VHA-a1-green fluorescent protein (GFP) and SYP61-cyan fluorescent protein (CFP), colocalized with RabA4b in TGN cisternae, suggesting that the secretory and endocytic pathways converge at the TGN. pi4k1/pi4k2 knockout mutant plants produce SVs with highly variable sizes indicating that PI-4Kβ1/2 regulates SV size.     

Syntaxin 17 cycles between the ER and ERGIC and is required to maintain the architecture of ERGIC and Golgi

Background information. Syntaxin 17 is a SNARE (soluble N‐ethylmaleimide‐sensitive‐factor‐attachment protein receptor) protein that predominantly localizes to the ER (endoplasmic reticulum) and to some extent in the ERGIC (ER—Golgi intermediate compartment). Syntaxin 17 has been suggested to function as a receptor at the ER membrane that mediates trafficking between the ER and post‐ER compartments. It has a unique 33 amino acid luminal tail whose function is not known. Here we have investigated the structural requirements for localization of syntaxin 17 to the ERGIC and its role in trafficking. Results. Deletion analysis showed that syntaxin 17 required its cytoplasmic domain to exit the ER and localize to the ERGIC. Mutation of a conserved tyrosine residue in the cytoplasmic domain resulted in reduced localization of syntaxin 17 in the ERGIC and ER‐exit sites, suggesting the presence of a tyrosine‐based ER export motif. Syntaxin 17 also required its C‐terminal tail to localize to the ERES (ER exit sites) and ERGIC. Knockdown of syntaxin 17 destabilized the ERGIC organization and also caused fragmentation of the Golgi complex. Syntaxin 17 showed direct interaction with transmembrane proteins p23 and p25 (cargo receptors that cycle between the ER and Golgi) with the help of its C‐terminal tail. Overexpression of syntaxin 17 redistributed β‐COP (β‐coatomer protein) which required its C‐terminal tail. Overexpression of syntaxin 17 also blocked the anterograde transport of VSVG (vesicular stomatitis virus G‐protein) in the ERGIC. Conclusions. We show that syntaxin 17 has a tyrosine‐based motif which is required for its incorporation into COPII (coatomer protein II) vesicles, exit from the ER and localization to the ERGIC. Our results suggest that syntaxin 17 cycles between the ER and ERGIC through classical trafficking pathways involving COPII and COPI (coatomer protein I) vesicles, which requires its unique C‐terminal tail. We also show that syntaxin 17 is essential for maintaining the architecture of ERGIC and Golgi.     

The transmembrane domain of N –acetylglucosaminyltransferase I is the key determinant for its Golgi subcompartmentation

Golgi‐resident type–II membrane proteins are asymmetrically distributed across the Golgi stack. The intrinsic features of the protein that determine its subcompartment‐specific concentration are still largely unknown. Here, we used a series of chimeric proteins to investigate the contribution of the cytoplasmic, transmembrane and stem region of Nicotiana benthamiana N–acetylglucosaminyltransferase I (GnTI) for its cis/medial‐Golgi localization and for protein–protein interaction in the Golgi. The individual GnTI protein domains were replaced with those from the well‐known trans‐Golgi enzyme α2,6–sialyltransferase (ST) and transiently expressed in Nicotiana benthamiana. Using co‐localization analysis and N–glycan profiling, we show that the transmembrane domain of GnTI is the major determinant for its cis/medial‐Golgi localization. By contrast, the stem region of GnTI contributes predominately to homomeric and heteromeric protein complex formation. Importantly, in transgenic Arabidopsis thaliana, a chimeric GnTI variant with altered sub‐Golgi localization was not able to complement the GnTI‐dependent glycosylation defect. Our results suggest that sequence‐specific features in the transmembrane domain of GnTI account for its steady‐state distribution in the cis/medial‐Golgi in plants, which is a prerequisite for efficient N–glycan processing in vivo.     

Analysis of COPII Vesicles Indicates a Role for the Emp47–Ssp120 Complex in Transport of Cell Surface Glycoproteins

Coat protein complex II (COPII) vesicle formation at the endoplasmic reticulum (ER) transports nascent secretory proteins forward to the Golgi complex. To further define the machinery that packages secretory cargo and targets vesicles to Golgi membranes, we performed a comprehensive proteomic analysis of purified COPII vesicles. In addition to previously known proteins, we identified new vesicle proteins including Coy1, Sly41 and Ssp120, which were efficiently packaged into COPII vesicles for trafficking between the ER and Golgi compartments. Further characterization of the putative calcium‐binding Ssp120 protein revealed a tight association with Emp47 and in emp47Δ cells Ssp120 was mislocalized and secreted. Genetic analyses demonstrated that EMP47 and SSP120 display identical synthetic positive interactions with IRE1 and synthetic negative interactions with genes involved in cell wall assembly. Our findings support a model in which the Emp47–Ssp120 complex functions in transport of plasma membrane glycoproteins through the early secretory pathway.      

Golgi structure correlates with transitional endoplasmic reticulum organization in Pichia pastoris and Saccharomyces cerevisiae

Golgi stacks are often located near sites of "transitional ER" (tER), where COPII transport vesicles are produced. This juxtaposition may indicate that Golgi cisternae form at tER sites. To explore this idea, we examined two budding yeasts: Pichia pastoris, which has coherent Golgi stacks, and Saccharomyces cerevisiae, which has a dispersed Golgi. tER structures in the two yeasts were visualized using fusions between green fluorescent protein and COPII coat proteins. We also determined the localization of Sec12p, an ER membrane protein that initiates the COPII vesicle assembly pathway. In P. pastoris, Golgi stacks are adjacent to discrete tER sites that contain COPII coat proteins as well as Sec12p. This arrangement of the tER-Golgi system is independent of microtubules. In S. cerevisiae, COPII vesicles appear to be present throughout the cytoplasm and Sec12p is distributed throughout the ER, indicating that COPII vesicles bud from the entire ER network. We propose that P. pastoris has discrete tER sites and therefore generates coherent Golgi stacks, whereas S. cerevisiae has a delocalized tER and therefore generates a dispersed Golgi. These findings open the way for a molecular genetic analysis of tER sites.     

The Fine Structure of Four “Species” of Amoeba*

The fine structure of Amoeba discoides, Amoeba dubia, and Amoeba amazonas was studied and compared with that of Amoeba proteus. The different kinds of amebas showed general similarities but differed in the ultrastructural details of their organelles. With respect to fine structure, A. discoides was indistinguishable from A. proteus, while both A. dubia and A. amazonas had distinctive features. The nuclei of all had a prominent honeycomb-like fibrous lamina, but A. dubia differed from the others in the distribution of nucleoli within the nucleus. The mitochondria of A. amazonas were unusual in having a variable pattern of cristae, some being plate-like and others tubular. Golgi bodies in A. amazonas had a greater proportion of vesicles and a smaller number of cisternae than those of the others, while Golgi bodies in A. dubia had highly flattened cisternae without a lining of filamentous material such as is found in the other types. The plasma membrane of A. dubia also lacked the prominent filamentous cell coat common to A. proteus and other amebas. The relation between the Golgi apparatus and the cell coat and the significance of the degree of development of the cell coat for pinocytosis and other phenomena is considered. The experimental use of these cells, including the formation of hybrids by nuclear transplantation is discussed.     

Structure,differentiation, and multiplication of Golgi apparatus in fungal hyphae

Summary Golgi apparatus in subapical regions of hyphae consist of paranuclear dictyosomes with 4–5 cisternae each. Transverse and tangential sections provide ultrastructural evidence for a three-dimensional architectural model of the Golgi apparatus and a stepwise mechanism for dictyosome multiplication. The dictyosomes are polarized, with progressive morphological and developmental differentiation of cisternae from the cis to the trans pole. Small membrane blebs and transition vesicles provide developmental continuity between the nuclear envelope and the adjacent dictyosome cisterna at the cis face. Cisternae are formed as fenestrated plates with extended tubular peripheries. The morphology of each cisterna depends on its position in the stack, consistent with a developmental gradient of progressive maturation and turnover of cisternae. Mature cisternae at the trans face are dissociated to produce spheroid and tubular vesicles. Evidence in support of a schematic sequence for increasing the numbers of dictyosomes comes from images of distinctive and unusual forms of Golgi apparatus in hyphal regions where nuclei and dictyosomes multiply, as follows: (a) The area of the nuclear envelope exhibiting forming-face activity next to a dictyosome expands, which in turn increases the size of cisternae subsequently assembled at the cis face of the dictyosome. (b) As subsequent large cisternae are formed and mature as they pass through the dictyosome, an entire dictyosome about twice normal size is built up. The number of cisternae per stack remains the same because of continuing turnover and loss of cisternae at the trans face, (c) This enlarged dictyosome becomes separated into two by a small region of the nuclear envelope next to the cis face that acquires polyribosomes and no longer generates transition vesicles, (d) As a consequence, assembly of new dictyosomes is physically separated into two adjacent regions, (e) As.the enlarged cisternae are lost to vesiculation at the trans pole, they are replaced by two separate stacks of cisternae with typical normal diameters, (f) The net result is two adjacent dictyosomes where one existed previously. Dictyosome multiplication is thus accomplished as part of the normal developmental turnover of cisternae, without interrupting the functioning of the Golgi apparatus as it continues to produce new secretory vesicles from mature cisternae at the trans face. Coordination of Golgi apparatus multiplication with nuclear division ensures that each daughter nucleus receives a complement of paranuclear dictyosomes.     

Localization of fucosyl residues in cellular compartments of rat duodenal absorptive enterocytes and goblet cells

We have determined the subcellular distribution of fucosyl residues in rat duodenal absorptive enterocytes and goblet cells, using the binding affinity of the lectin I of Ulex europaeus (UEA I). In absorptive enterocytes, UEA I-lectin gold complexes were detected at the brush border and at the basolateral plasma membrane; pits of the plasma membrane were labeled, as were small vesicles, multivesicular bodies, lysosomes, and the Golgi apparatus. In the Golgi stacks, about half of the cisternae showed gold marker particles: accessible fucosyl residues were sparse in the cis subcompartment, the cismost cisterna mostly remaining negative; more intense label was found in medial cisternae; reactions were concentrated in the trans and transmost Golgi subcompartments. Cisternae, tubules and vesicles located at the trans Golgi side were the most constantly and intensely stained Golgi elements. In goblet cells, mucin granules and trans Golgi cisternae were labeled. Rarely, UEA I-gold bound to cisternae of the medial subcompartment; the cis subcompartment remained unstained. In part, UEA I-gold particles were restricted to dilated portions of the transmost Golgi cisterna and to secretory granules.