More than just sugars: Conserved oligomeric Golgi complex deficiency causes glycosylation‐independent cellular defects

The conserved oligomeric Golgi (COG) complex controls membrane trafficking and ensures Golgi homeostasis by orchestrating retrograde vesicle trafficking within the Golgi. Human COG defects lead to severe multisystemic diseases known as COG‐congenital disorders of glycosylation (COG‐CDG). To gain better understanding of COG‐CDGs, we compared COG knockout cells with cells deficient to 2 key enzymes, Alpha‐1,3‐mannosyl‐glycoprotein 2‐beta‐N‐acetylglucosaminyltransferase and uridine diphosphate‐glucose 4‐epimerase (GALE), which contribute to proper N‐ and O‐glycosylation. While all knockout cells share similar defects in glycosylation, these defects only account for a small fraction of observed COG knockout phenotypes. Glycosylation deficiencies were not associated with the fragmented Golgi, abnormal endolysosomes, defective sorting and secretion or delayed retrograde trafficking, indicating that these phenotypes are probably not due to hypoglycosylation, but to other specific interactions or roles of the COG complex. Importantly, these COG deficiency specific phenotypes were also apparent in COG7‐CDG patient fibroblasts, proving the human disease relevance of our CRISPR knockout findings. The knowledge gained from this study has important implications, both for understanding the physiological role of COG complex in Golgi homeostasis in eukaryotic cells, and for better understanding human diseases associated with COG/Golgi impairment.      

Golgi‐mediated Glycosylation Determines Residency of the T2 RNase Rny1p in Saccharomyces cerevisiae

The role of glycosylation in the function of the T2 family of RNases is not well understood. In this work, we examined how glycosylation affects the progression of the T2 RNase Rny1p through the secretory pathway in Saccharomyces cerevisiae. We found that Rny1p requires entering into the ER first to become active and uses the adaptor protein Erv29p for packaging into COPII vesicles and transport to the Golgi apparatus. While inside the ER, Rny1p undergoes initial N‐linked core glycosylation at four sites, N37, N70, N103 and N123. Rny1p transport to the Golgi results in the further attachment of high‐glycans. Whereas modifications with glycans are dispensable for the nucleolytic activity of Rny1p, Golgi‐mediated modifications are critical for its extracellular secretion. Failure of Golgi‐specific glycosylation appears to direct Rny1p to the vacuole as an alternative destination and/or site of terminal degradation. These data reveal a previously unknown function of Golgi glycosylation in a T2 RNase as a sorting and secretion signal .      

Mutant SOD1 inhibits ER‐Golgi transport in amyotrophic lateral sclerosis

Cu/Zn‐superoxide dismutase is misfolded in familial and sporadic amyotrophic lateral sclerosis, but it is not clear how this triggers endoplasmic reticulum (ER) stress or other pathogenic processes. Here, we demonstrate that mutant SOD1 (mSOD1) is predominantly found in the cytoplasm in neuronal cells. Furthermore, we show that mSOD1 inhibits secretory protein transport from the ER to Golgi apparatus. ER‐Golgi transport is linked to ER stress, Golgi fragmentation and axonal transport and we also show that inhibition of ER‐Golgi trafficking preceded ER stress, Golgi fragmentation, protein aggregation and apoptosis in cells expressing mSOD1. Restoration of ER‐Golgi transport by over‐expression of coatomer coat protein II subunit Sar1 protected against inclusion formation and apoptosis, thus linking dysfunction in ER‐Golgi transport to cellular pathology. These findings thus link several cellular events in amyotrophic lateral sclerosis into a single mechanism occurring early in mSOD1 expressing cells.

     

Spatial Regulation of Golgi Phosphatidylinositol‐4‐Phosphate is Required for Enzyme Localization and Glycosylation Fidelity

The enrichment of phosphatidylinositol‐4‐phosphate (PI(4)P) at the trans Golgi network (TGN) is instrumental for proper protein and lipid sorting, yet how the restricted distribution of PI(4)P is achieved remains unknown. Here, we show that lipid phosphatase Suppressor of actin mutations 1 (SAC1) is crucial for the spatial regulation of Golgi PI(4)P. Ultrastructural analysis revealed that SAC1 is predominantly located at cisternal Golgi membranes but is absent from the TGN, thus confining PI(4)P to the TGN. RNAi‐mediated knockdown of SAC1 caused changes in Golgi morphology and mislocalization of Golgi enzymes. Enzymes involved in glycan processing such as mannosidase‐II (Man‐II) and N‐acetylglucosamine transferase‐I (GnT‐I) redistributed to aberrant intracellular structures and to the cell surface in SAC1 knockdown cells. SAC1 depletion also induced a unique pattern of Golgi‐specific defects in N‐and O‐linked glycosylation. These results indicate that SAC1 organizes PI(4)P distribution between the Golgi complex and the TGN, which is instrumental for resident enzyme partitioning and Golgi morphology.     

Targeting of tail‐anchored membrane proteins to subcellular organelles in Toxoplasma gondii

Proper protein localization is essential for critical cellular processes, including vesicle‐mediated transport and protein translocation. Tail‐anchored (TA) proteins are integrated into organellar membranes via the C‐terminus, orienting the N‐terminus towards the cytosol. Localization of TA proteins occurs posttranslationally and is governed by the C‐terminus, which contains the integral transmembrane domain (TMD) and targeting sequence. Targeting of TA proteins is dependent on the hydrophobicity of the TMD as well as the length and composition of flanking amino acid sequences. We previously identified an unusual homologue of elongator protein, Elp3, in the apicomplexan parasite Toxoplasma gondii as a TA protein targeting the outer mitochondrial membrane. We sought to gain further insight into TA proteins and their targeting mechanisms using this early‐branching eukaryote as a model. Our bioinformatics analysis uncovered 59 predicted TA proteins in Toxoplasma, 9 of which were selected for follow‐up analyses based on representative features. We identified novel TA proteins that traffic to specific organelles in Toxoplasma, including the parasite endoplasmic reticulum, mitochondrion, and Golgi apparatus. Domain swap experiments elucidated that targeting of TA proteins to these specific organelles was strongly influenced by the TMD sequence, including charge of the flanking C‐terminal sequence.      

A Sensor of Protein O‐Glycosylation Based on Sequential Processing in the Golgi Apparatus

Protein O‐glycosylation is important in numerous processes including the regulation of proteolytic processing sites by O‐glycan masking in select newly synthesized proteins. To investigate O‐glycan‐mediated masking using an assay amenable to large‐scale screens, we generated a fluorescent biosensor with an O‐glycosylation site situated to mask a furin cleavage site. The sensor is activated when O‐glycosylation fails to occur because furin cleavage releases a blocking domain allowing dye binding to a fluorogen activating protein. Thus, by design, glycosylation should block furin from activating the sensor only if it occurs first, which is predicted by the conventional view of Golgi organization. Indeed, and in contrast to the recently proposed rapid partitioning model, the sensor was non‐fluorescent under normal conditions but became fluorescent when the Golgi complex was decompartmentalized. To test the utility of the sensor as a screening tool, cells expressing the sensor were exposed to a known inhibitor of O‐glycosylation extension or siRNAs targeting factors known to alter glycosylation efficiency. These conditions activated the sensor substantiating its potential in identifying new inhibitors and cellular factors related to protein O‐glycosylation. In summary, these findings confirm sequential processing in the Golgi, establish a new tool for studying the regulation of proteolytic processing by O‐glycosylation, and demonstrate the sensor's potential usefulness for future screening projects .     

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 .     

A Conserved Structural Motif Mediates Retrograde Trafficking of Shiga Toxin Types 1 and 2

Shiga toxin‐producing Escherichia coli (STEC) produce two types of Shiga toxin (STx): STx1 and STx2. The toxin A‐subunits block protein synthesis, while the B‐subunits mediate retrograde trafficking. STEC infections do not have definitive treatments, and there is growing interest in generating toxin transport inhibitors for therapy. However, a comprehensive understanding of the mechanisms of toxin trafficking is essential for drug development. While STx2 is more toxic in vivo, prior studies focused on STx1 B‐subunit (STx1B) trafficking. Here, we show that, compared with STx1B, trafficking of the B‐subunit of STx2 (STx2B) to the Golgi occurs with slower kinetics. Despite this difference, similar to STx1B, endosome‐to‐Golgi transport of STx2B does not involve transit through degradative late endosomes and is dependent on dynamin II, epsinR, retromer and syntaxin5. Importantly, additional experiments show that a surface‐exposed loop in STx2B (β4–β5 loop) is required for its endosome‐to‐Golgi trafficking. We previously demonstrated that residues in the corresponding β4–β5 loop of STx1B are required for interaction with GPP130, the STx1B‐specific endosomal receptor, and for endosome‐to‐Golgi transport. Overall, STx1B and STx2B share a common pathway and use a similar structural motif to traffic to the Golgi, suggesting that the underlying mechanisms of endosomal sorting may be evolutionarily conserved.      

The Arl3 and Arl1 GTPases co‐operate with Cog8 to regulate selective autophagy via Atg9 trafficking

The Arl3‐Arl1 GTPase cascade plays important roles in vesicle trafficking at the late Golgi and endosomes. Subunits of the conserved oligomeric Golgi (COG) complex, a tethering factor, are important for endosome‐to‐Golgi transport and contribute to the efficient functioning of the cytoplasm‐to‐vacuole targeting (Cvt) pathway, a well‐known selective autophagy pathway. According to our findings, the Arl3‐Arl1 GTPase cascade co‐operates with Cog8 to regulate the Cvt pathway via Atg9 trafficking. arl3cog8Δ and arl1cog8Δ exhibit profound defects in aminopeptidase I maturation in rich medium. In addition, the Arl3‐Arl1 cascade acts on the Cvt pathway via dynamic nucleotide binding. Furthermore, Atg9 accumulates at the late Golgi in arl3cog8Δ and arl1cog8Δ cells under normal growth conditions but not under starvation conditions. Thus, our results offer insight into the requirement for multiple components in the Golgi‐endosome system to determine Atg9 trafficking at the Golgi, thereby regulating selective autophagy.      

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.      

Re'COG'nition at the Golgi

The conserved oligomeric Golgi (COG) complex co-ordinates retrograde vesicle transport within the Golgi. These vesicles maintain the distribution of glycosylation enzymes between the Golgi's cisternae, and therefore COG is intimately involved in glycosylation homeostasis. Recent years have greatly enhanced our knowledge of COG's composition, protein interactions, cellular function and most recently also its structure. The emergence of COG-dependent human glycosylation disorders gives particular relevance to these advances. The structural data have firmly placed COG in the family of multi-subunit tethering complexes that it shares with the exocyst, Dsl1 and Golgi-associated retrograde protein (GARP) complexes. Here, we review our knowledge of COG's involvement in vesicle tethering at the Golgi. In particular, we consider what this knowledge may add to our molecular understanding of vesicle tethering and how it impacts on the fine tuning of Golgi function, most notably glycosylation.     

Golgi α1,4‐fucosyltransferase of Arabidopsis thaliana partially localizes at the nuclear envelope

We analyzed plant‐derived α1,4‐fucosyltransferase (FucTc) homologs by reporter fusions and focused on representatives of the Brassicaceae and Solanaceae. Arabidopsis thaliana AtFucTc‐green fluorescent protein (GFP) or tomato LeFucTc‐GFP restored Lewis‐a formation in a fuctc mutant, confirming functionality in the trans‐Golgi. AtFucTc‐GFP partly accumulated at the nuclear envelope (NE) not observed for other homologs or truncated AtFucTc lacking the N‐terminus or catalytic domain. Analysis of At/LeFucTc‐GFP swap constructs with exchanged cytosolic, transmembrane and stalk (CTS), or only the CT regions, revealed that sorting information resides in the membrane anchor. Other domains of AtFuctc also contribute, since amino‐acid changes in the CT region strongly reduced but did not abolish NE localization. By contrast, two N‐terminal GFP copies did, indicating localization at the inner nuclear membrane (INM). Tunicamycin treatment of AtFucTc‐GFP abolished NE localization and enhanced overlap with an endosomal marker, suggesting involvement of N‐glycosylation. Yet neither expression in protoplasts of Arabidopsis N‐glycosylation mutants nor elimination of the N‐glycosylation site in AtFucTc prevented perinuclear accumulation. Disruption of endoplasmic reticulum (ER)‐to‐Golgi transport by co‐expression of Sar1(H74L) trapped tunicamycin‐released AtFucTc‐GFP in the ER, however, without NE localization. Since recovery after tunicamycin‐washout required de novo‐protein synthesis, our analyses suggest that AtFucTc localizes to the NE/INM due to interaction with an unknown (glyco)protein.      

Amyloid precursor protein traffics from the Golgi directly to early endosomes in an Arl5b‐ and AP4‐dependent pathway

The intracellular trafficking and proteolytic processing of the membrane‐bound amyloid precursor protein (APP) are coordinated events leading to the generation of pathogenic amyloid‐beta (Aβ) peptides. The membrane transport of newly synthesized APP from the Golgi to the endolysosomal system is not well defined, yet it is likely to be critical for regulating its processing by β‐secretase (BACE1) and γ‐secretase. Here, we show that the majority of newly synthesized APP is transported from the trans‐Golgi network (TGN) directly to early endosomes and then subsequently to the late endosomes/lysosomes with very little transported to the cell surface. We show that Arl5b, a small G protein localized to the TGN, and AP4 are essential for the post‐Golgi transport of APP to early endosomes. Arl5b is physically associated with AP4 and is required for the recruitment of AP4, but not AP1, to the TGN. Depletion of either Arl5b or AP4 results in the accumulation of APP, but not BACE1, in the Golgi, and an increase in APP processing and Aβ secretion. These findings demonstrate that APP is diverted from BACE1 at the TGN for direct transport to early endosomes and that the TGN represents a site for APP processing with the subsequent secretion of Aβ.      

Arabinogalactan Glycosyltransferases Target to a Unique Subcellular Compartment That May Function in Unconventional Secretion in Plants

We report that fluorescently tagged arabinogalactan glycosyltransferases target not only the Golgi apparatus but also uncharacterized smaller compartments when transiently expressed in Nicotiana benthamiana. Approximately 80% of AtGALT31A [Arabidopsis thaliana galactosyltransferase from family 31 (At1g32930)] was found in the small compartments, of which, 45 and 40% of AtGALT29A [Arabidopsis thaliana galactosyltransferase from family 29 (At1g08280)] and AtGlcAT14A [Arabidopsis thaliana glucuronosyltransferase from family 14 (At5g39990)] colocalized with AtGALT31A, respectively; in contrast, N‐glycosylation enzymes rarely colocalized (3–18%), implicating a role of the small compartments in a part of arabinogalactan (O‐glycan) biosynthesis rather than N‐glycan processing. The dual localization of AtGALT31A was also observed for fluorescently tagged AtGALT31A stably expressed in an Arabidopsis atgalt31a mutant background. Further, site‐directed mutagenesis of a phosphorylation site of AtGALT29A (Y144) increased the frequency of the protein being targeted to the AtGALT31A‐localized small compartments, suggesting a role of Y144 in subcellular targeting. The AtGALT31A localized to the small compartments were colocalized with neither SYP61 (syntaxin of plants 61), a marker for trans‐Golgi network (TGN), nor FM4‐64‐stained endosomes. However, 41% colocalized with EXO70E2 (Arabidopsis thaliana exocyst protein Exo70 homolog 2), a marker for exocyst‐positive organelles, and least affected by Brefeldin A and Wortmannin. Taken together, AtGALT31A localized to small compartments that are distinct from the Golgi apparatus, the SYP61‐localized TGN, FM4‐64‐stained endosomes and Wortmannin‐vacuolated prevacuolar compartments, but may be part of an unconventional protein secretory pathway represented by EXO70E2 in plants.      

PLCγ1 Participates in Protein Transport and Diacylglycerol Production Triggered by cargo Arrival at the Golgi

Diacylglycerol (DAG) is required for membrane traffic and structural organization at the Golgi. DAG is a lipid metabolite of several enzymatic reactions present at this organelle, but the mechanisms by which they are regulated are still unknown. Here, we show that cargo arrival at the Golgi increases the recruitment of the DAG‐sensing constructs C1‐PKCθ‐GFP and the PKD‐wt‐GFP. The recruitment of both constructs was reduced by PLCγ1 silencing. Post‐Golgi trafficking of transmembrane and soluble proteins was impaired in PLCγ1‐silenced cells. Under basal conditions, PLCγ1 contributed to the maintenance of the pool of DAG associated with the Golgi and to the structural organization of the organelle. Finally, we show that cytosolic phospholipase C (PLC) can hydrolyse phosphatidylinositol 4‐phosphate in isolated Golgi membranes. Our results indicate that PLCγ1 is part of the molecular mechanism that couples cargo arrival at the Golgi with DAG production to co‐ordinate the formation of transport carriers for post‐Golgi traffic.      

Requirement of the SH4 and tyrosine-kinase domains but not the kinase activity of Lyn for its biosynthetic targeting to caveolin-positive Golgi membranes

Background

The Src-family non-receptor-type tyrosine kinase Lyn, which is often associated with chemotherapeutic resistance in cancer, localizes not only to the plasma membrane but also Golgi membranes. Recently, we showed that Lyn, which is synthesized in the cytosol, is transported from the Golgi to the plasma membrane along the secretory pathway. However, it is still unclear how Golgi targeting of newly synthesized Lyn is regulated.

Methods

Subcellular localization of Lyn and its mutants was determined by confocal microscopy.

Results

We show that the kinase domain, but not the SH3 and SH2 domains, of Lyn is required for the targeting of Lyn to the Golgi, whereas the N-terminal lipids of the Lyn SH4 domain are not sufficient for its Golgi targeting. Although intact Lyn, which colocalizes with caveolin-positive Golgi membranes, can traffic toward the plasma membrane, kinase domain-deleted Lyn is immobilized on caveolin-negative Golgi membranes.

General significance

Besides the SH4 domain, the Lyn kinase domain is important for targeting of newly synthesized Lyn to the Golgi, especially caveolin-positive transport membranes. Our results provide a novel role of the Lyn catalytic domain in the Golgi targeting of newly synthesized Lyn in a manner independent of its kinase activity.     

Targeting and signaling of Rho of plants guanosine triphosphatases require synergistic interaction between guanine nucleotide inhibitor and vesicular trafficking

Most eukaryotic cells are polarized. Common toolbox regulating cell polarization includes Rho guanosine triphosphatases (GTPases), in which spatiotemporal activation is regulated by a plethora of regulators. Rho of plants (ROPs) are the only Rho GTPases in plants. Although vesicular trafficking was hinted in the regulation of ROPs, it was unclear where vesicle‐carried ROP starts, whether it is dynamically regulated, and which components participate in vesicle‐mediated ROP targeting. In addition, although vesicle trafficking and guanine nucleotide inhibitor (GDI) pathways in Rho signaling have been extensively studied in yeast, it is unknown whether the two pathways interplay. Unclear are also cellular and developmental consequences of their interaction in multicellular organisms. Here, we show that the dynamic targeting of ROP through vesicles requires coat protein complex II and ADP‐ribosylation factor 1‐mediated post‐Golgi trafficking. Trafficking of vesicle‐carried ROPs between the plasma membrane and the trans‐Golgi network is mediated through adaptor protein 1 and sterol‐mediated endocytosis. Finally, we show that GDI and vesicle trafficking synergistically regulate cell polarization and ROP targeting, suggesting that the establishment and maintenance of cell polarity is regulated by an evolutionarily conserved mechanism.     

Trafficking of Acetyl‐C16‐Ceramide‐NBD with Long‐Term Stability and No Cytotoxicity into the Golgi Complex

The Golgi complex plays a prominent role in the modification and sorting of lipids and proteins, and is a highly dynamic organelle that is dispersed and rearranged before and after mitosis. Several reagents including 4‐nitrobenzo‐2‐oxa‐1,3‐diazole‐labeled C6‐ceramide (NBD‐C6‐ceramide, a ceramide having an NBD‐bound C6‐N‐acyl chain) and Golgi‐specific proteins that emit fluorescence are used as Golgi markers. In the present study, we synthesized a new ceramide analog, acetyl‐C16‐ceramide‐NBD (a ceramide having an acetylated C‐1 hydroxyl group, C16‐N‐acyl chain, and NBD‐bound C15‐sphingosine), and showed that it preferentially accumulated in the Golgi complex without cytotoxicity for over 24 h. Pathways for cellular uptake and interorganelle trafficking of acetyl‐C16‐ceramide‐NBD were investigated. Acetyl‐C16‐ceramide‐NBD was transported to the Golgi complex via ceramide transport proteins. In contrast to NBD‐C6‐ceramide, acetyl‐C16‐ceramide‐NBD was resistant to ceramide metabolic enzymes such as sphingomyelin synthase and glucosylceramide synthase. Because of its weaker cytotoxicity and resistance to ceramide metabolic enzymes, the localization of the Golgi complex could be observed in acetyl‐C16‐ceramide‐NBD‐labeled cells before and after mitosis.      

Palmitoylation of stathmin family proteins domain A controls Golgi versus mitochondrial subcellular targeting

Background information. Precise localization of proteins to specialized subcellular domains is fundamental for proper neuronal development and function. The neural microtubule‐regulatory phosphoproteins of the stathmin family are such proteins whose specific functions are controlled by subcellular localization. Whereas stathmin is cytosolic, SCG10, SCLIP and RB3/RB3′/RB3″ are localized to the Golgi and vesicle‐like structures along neurites and at growth cones. We examined the molecular determinants involved in the regulation of this specific subcellular localization in hippocampal neurons in culture. Results. We show that their conserved N‐terminal domain A carrying two palmitoylation sites is dominant over the others for Golgi and vesicle‐like localization. Using palmitoylation‐deficient GFP (green fluorescent protein) fusion mutants, we demonstrate that domains A of stathmin proteins have the particular ability to control protein targeting to either Golgi or mitochondria, depending on their palmitoylation. This regulation involves the co‐operation of two subdomains within domain A, and seems also to be under the control of its SLD (stathmin‐like domain) extension. Conclusions. Our results unravel that, in specific biological conditions, palmitoylation of stathmin proteins might be able to control their targeting to express their functional activities at appropriate subcellular sites. They, more generally, open new perspectives regarding the role of palmitoylation as a signalling mechanism orienting proteins to their functional subcellular compartments.     

Kinetically Distinct Sorting Pathways through the Golgi Exhibit Different Requirements for Arf1

To investigate the role of cytoplasmic sequences in directing transmembrane protein trafficking through the Golgi, we analyzed the sorting of VSV tsO45 G fusions with either the native G cytoplasmic domain (G) or an alternative cytoplasmic tail derived from the chicken AE1‐4 anion exchanger (G^AE). At restrictive temperature G^AE and G accumulated in the ER, and upon shifting the cells to permissive temperature both proteins folded and underwent transport through the Golgi. However, G^AE and G did not form hetero‐oligomers upon the shift to permissive temperature and they progressed through the Golgi with distinct kinetics. In addition, the transport of G through the proximal Golgi was Arf1 and COPI‐dependent, while G^AE progression through the proximal Golgi was Arf1 and COPI‐independent. Although Arf1 did not regulate the sorting of G^AE in the cis‐Golgi, Arf1 did regulate the exit of G^AE from the TGN. The trafficking of G^AE through the Golgi was similar to that of the native AE1‐4 anion exchanger, in that the progression of both proteins through the proximal Golgi was Arf1‐independent, while both required Arf1 to exit the TGN. We propose that the differential recognition of cytosolic signals in membrane‐spanning proteins by the Arf1‐dependent sorting machinery may influence the rate at which cargo progresses through the Golgi.