Hyphal tip cells of the fungus
are useful for studying long-range intracellular traffic. Post-Golgi secretory vesicles (SVs) containing the RAB11 orthologue RabE engage myosin-5 as well as plus end- ...and minus end-directed microtubule motors, providing an experimental system with which to investigate the interplay between microtubule and actin motors acting on the same cargo. By exploiting the fact that depolymerization of F-actin unleashes SVs focused at the apex by myosin-5 to microtubule-dependent motors, we establish that the minus end-directed transport of SVs requires the dynein/dynactin supercomplex. This minus end-directed transport is largely unaffected by genetic ablation of the Hook complex adapting early endosomes (EEs) to dynein but absolutely requires p25 in dynactin. Thus dynein recruitment to two different membranous cargoes, namely EEs and SVs, requires p25, highlighting the importance of the dynactin pointed-end complex to scaffold cargoes. Finally, by studying the behavior of SVs and EEs in null and rigor mutants of kinesin-3 and kinesin-1 (UncA and KinA, respectively), we demonstrate that KinA is the major kinesin mediating the anterograde transport of SVs. Therefore SVs arrive at the apex of
by anterograde transport involving cooperation of kinesin-1 with myosin-5 and can move away from the apex powered by dynein.
A long-standing assumption is that the cisternae of the Golgi apparatus can be grouped into functionally distinct compartments, yet the molecular identities of those compartments have not been ...clearly described. The concept of a compartmentalized Golgi is challenged by the cisternal maturation model, which postulates that cisternae form
and then undergo progressive biochemical changes. Cisternal maturation can potentially be reconciled with Golgi compartmentation by defining compartments as discrete kinetic stages in the maturation process. These kinetic stages are distinguished by the traffic pathways that are operating. For example, a major transition occurs when a cisterna stops producing COPI vesicles and begins producing clathrin-coated vesicles. This transition separates one kinetic stage, the "early Golgi," from a subsequent kinetic stage, the "late Golgi" or "
-Golgi network (TGN)." But multiple traffic pathways drive Golgi maturation, and the periods of operation for different traffic pathways can partially overlap, so there is no simple way to define a full set of Golgi compartments in terms of kinetic stages. Instead, we propose that the focus should be on the series of transitions experienced by a Golgi cisterna as various traffic pathways are switched on and off. These traffic pathways drive changes in resident transmembrane protein composition. Transitions in traffic pathways seem to be the fundamental, conserved determinants of Golgi organization. According to this view, the initial goal is to identify the relevant traffic pathways and place them on the kinetic map of Golgi maturation, and the ultimate goal is to elucidate the logic circuit that switches individual traffic pathways on and off as a cisterna matures.
The pathways of membrane traffic within the Golgi apparatus are not fully known. This question was addressed using the yeast Saccharomyces cerevisiae, in which the maturation of individual Golgi ...cisternae can be visualized. We recently proposed that the AP-1 clathrin adaptor mediates intra-Golgi recycling late in the process of cisternal maturation. Here, we demonstrate that AP-1 cooperates with the Ent5 clathrin adaptor to recycle a set of Golgi transmembrane proteins, including some that were previously thought to pass through endosomes. This recycling can be detected by removing AP-1 and Ent5, thereby diverting the AP-1/Ent5-dependent Golgi proteins into an alternative recycling loop that involves traffic to the plasma membrane followed by endocytosis. Unexpectedly, various AP-1/Ent5-dependent Golgi proteins show either intermediate or late kinetics of residence in maturing cisternae. We infer that the AP-1/Ent5 pair mediates two sequential intra-Golgi recycling pathways that define two classes of Golgi proteins. This insight can explain the polarized distribution of transmembrane proteins in the Golgi.
Summary
Hyphal tip cells of Aspergillus nidulans are > 100 µm‐long, which challenges intracellular traffic. In spite of the basic and applied interest of the secretory pathway of filamentous fungi, ...only recently has it been investigated in detail. We used InuA, an inducible and highly glycosylated inulinase, and mutations affecting different intracellular membranous compartments, to investigate the route by which the enzyme traffics to the extracellular medium. InuA is core‐N‐glycosylated in the ER and hyperglycosylated during transit across the Golgi. Hyperglycosylation was prevented by ts mutations in sarASAR1 impeding ER exit, and in sedVSED5 and rabORAB1 dissipating the early Golgi, but not by mutations in the TGN regulators hypATRS120 and hypBSEC7, implicating the early Golgi in cargo glycosylation. podB1ts(cog2ts) affecting the COG complex also prevents glycosylation, without disassembling early Golgi cisternae. That InuA exocytosis is prevented by inactivation of any of the above genes shows that it follows a conventional secretory pathway. However, ablation of RabBRAB5 regulating early endosomes (EEs), but not of RabSRAB7, its equivalent in late endosomes, also prevents InuA accumulation in the medium, indicating that EEs are specifically required for InuA exocytosis. This work provides a framework to understand the secretion of enzyme cargoes by industrial filamentous fungi.
We used an Aspergillus nidulans inulinase denoted InuA and a panel of mutations affecting different steps of intracellular traffic to investigate the route by which a secreted enzyme is delivered to the extracellular medium. Although the enzyme follows a conventional secretory pathway involving the Golgi apparatus, its delivery outside cells requires functional early endosomes.
The Aspergillus nidulans Golgi is not stacked. Early and late Golgi equivalents (GEs) are intermingled but can be resolved by epifluorescence microscopy. RabC, the Aspergillus ortholog of mammalian ...Rab6, is present across the Golgi, preferentially associated with early GEs near the tip and with late GEs in tip‐distal regions. rabCΔ mutants, showing markedly impaired apical extension, have conspicuously fragmented, brefeldin A‐insensitive early and late GEs, indicating that the Golgi network organization requires RabC. rabCΔ Golgi fragmentation is paralleled by an increase in early endosome abundance. rabCΔ reduces extracellular levels of the major secretable protease, suggesting that it impairs secretion. Notably, the Spitzenkörper, an apical intracellular structure in which secretory carriers accumulate awaiting fusion with the adjacent plasma membrane (PM), contains RabC. rabCΔ leads to abnormally increased accumulation of carriers, detectable with secretory v‐SNARE GFP‐SynA and FM4‐64, in this structure. VpsTVps10, present across the Golgi, recycles between endosomes and Golgi and is mislocalized to a cytosolic haze by rabCΔ that, in contrast, does not affect SynA recycling between endosomes and the PM, indicating that SynA follows a RabC‐independent pathway. tlg2Δ mutants grow normally but are synthetically lethal with rabCΔ, indicating that RabC plays Tlg2‐independent roles.
Cargo passage through the Golgi, albeit an undoubtedly essential cellular function, is a mechanistically unresolved and much debated process. Although the main molecular players are conserved, ...diversification of the Golgi among different eukaryotic lineages is providing us with tools to resolve standing controversies. During the past decade the Golgi apparatus of model filamentous fungi, mainly Aspergillus nidulans, has been intensively studied. Here an overview of the most important findings in the field is provided. Golgi architecture and dynamics, as well as the novel cell biology tools that were developed in filamentous fungi in these studies, are addressed. An emphasis is placed on the central role the Golgi has as a crossroads in the endocytic and secretory-traffic pathways in hyphae. Finally the major advances that the A. nidulans Golgi biology has yielded so far regarding our understanding of key Golgi regulators, such as the Rab GTPases RabC
Rab6
and RabE
Rab11
, the oligomeric transport protein particle, TRAPPII, and the Golgi guanine nucleotide exchange factors of Arf1, GeaA
GBF1/Gea1
and HypB
BIG/Sec7
, are highlighted.
We exploit the ease with which highly motile early endosomes are distinguished from static late endosomes in order to study Aspergillus nidulans endosomal traffic. RabS(Rab7) mediates homotypic ...fusion of late endosomes/vacuoles in a homotypic fusion- and vacuole protein sorting/Vps41-dependent manner. Progression across the endocytic pathway involves endosomal maturation because the end products of the pathway in the absence of RabS(Rab7) are minivacuoles that are competent in multivesicular body sorting and cargo degradation but retain early endosomal features, such as the ability to undergo long-distance movement and propensity to accumulate in the tip region if dynein function is impaired. Without RabS(Rab7), early endosomal Rab5s-RabA and RabB-reach minivacuoles, in agreement with the view that Rab7 homologues facilitate the release of Rab5 homologues from endosomes. RabS(Rab7) is recruited to membranes already at the stage of late endosomes still lacking vacuolar morphology, but the transition between early and late endosomes is sharp, as only in a minor proportion of examples are RabA/RabB and RabS(Rab7) detectable in the same-frequently the less motile-structures. This early-to-late endosome/vacuole transition is coupled to dynein-dependent movement away from the tip, resembling the periphery-to-center traffic of endosomes accompanying mammalian cell endosomal maturation. Genetic studies establish that endosomal maturation is essential, whereas homotypic vacuolar fusion is not.
In fungal hyphal cells, intracellular membrane trafficking is constrained by the relatively long intracellular distances and the mode of growth, exclusively by apical extension. Endocytosis plays a ...key role in hyphal tip growth, which involves the coupling of secretory membrane delivery to the apical region with subapical compensatory endocytosis. However, the identity, dynamics and function of filamentous fungal endosomal compartments remain largely unexplored. Aspergillus nidulans RabARab⁵ localizes to a population of endosomes that show long range bidirectional movement on microtubule (MT) tracks and are labelled with FM4-64 shortly after dye internalization. RabARab⁵ membranes do not overlap with largely static mature endosomes/vacuoles. Impaired delivery of dynein to the MT plus ends or downregulation of cytoplasmic dynein using the dynein heavy chain nudA1tsmutation results in accumulation of RabARab⁵ endosomal membranes in an abnormal NudA1 compartment at the tip, strongly supporting the existence in A. nidulans hyphal tips of a dynein loading region. We show that the SynA synaptobrevin endocytic recycling cargo traffics through this region, which strongly supports the contention that polarized hyphal growth involves the association of endocytic recycling with the plus ends of MTs located at the tip, near the endocytic internalization collar.
The genetically amenable fungus Aspergillus nidulans is well suited for cell biology studies involving the secretory pathway and its relationship with hyphal tip growth by apical extension. We ...exploited live-cell epifluorescence microscopy of the ER labeled with the translocon component Sec63, endogenously tagged with GFP, to study the organization of 'secretory' ER domains. The Sec63 A. nidulans ER network includes brightly fluorescent peripheral strands and more faintly labeled nuclear envelopes. In hyphae, the most abundant peripheral ER structures correspond to plasma membrane-associated strands that are polarized, but do not invade the hyphal tip dome, at least in part because the subapical collar of endocytic actin patches constrict the cortical strands in this region. Thus the subapical endocytic ring might provide an attachment for ER strands, thereby ensuring that the growing tip remains 'loaded' with secretory ER. Acute disruption of secretory ER function by reductive stress-mediated induction of the unfolded protein response results in the reversible aggregation of ER strands, cessation of exocytosis and swelling of the hyphal tips. The secretory ER is insensitive to brefeldin A treatment and does not undergo changes during mitosis, in agreement with the reports that apical extension continues at normal rates during this period.
Celotno besedilo
Dostopno za:
DOBA, IZUM, KILJ, NUK, PILJ, PNG, SAZU, SIK, UILJ, UKNU, UL, UM, UPUK
The oligomeric complex transport protein particle I (TRAPPI) mediates nucleotide exchange on the RAB GTPase RAB1/Ypt1. TRAPPII is composed of TRAPPI plus three additional subunits, Trs120, Trs130, ...and Trs65. Unclear is whether TRAPPII mediates nucleotide exchange on RAB1/Ypt1, RAB11/Ypt31, or both. InAspergillus nidulans, RabORAB1resides in the Golgi, RabERAB11localizes to exocytic post-Golgi carriers undergoing transport to the apex, andhypAencodes Trs120. RabERAB11, but not RabORAB1, immunoprecipitates contain Trs120/Trs130/Trs65, demonstrating specific association of TRAPPII with RabERAB11in vivo.hypA1ts
rapidly shifts RabERAB11, but not RabORAB1, to the cytosol, consistent with HypATrs120being specifically required for RabERAB11activation. Missense mutations rescuing hypA1ts at 42 °C mapped torabE, affecting seven residues. Substitutions in six, of which four resulted in 7-to 36-fold accelerated GDP release, rescued lethality associated to TRAPPII deficiency, whereas equivalent substitutions in RabORAB1did not, establishing that the essential role of TRAPPII is facilitating RabERAB11nucleotide exchange. In vitro, TRAPPII purified with HypATrs120-S-tag accelerates nucleotide exchange on RabERAB11and, paradoxically, to a lesser yet substantial extent, on RabORAB1. Evidence obtained by exploitinghypA1-mediated destabilization of HypATrs120/HypCTrs130/Trs65 assembly onto the TRAPPI core indicates that these subunits sculpt a second RAB binding site on TRAPP apparently independent from that for RabORAB1, which would explain TRAPPII in vitro activity on two RABs. UsingA. nidulansin vivomicroscopy,we showthat HypATrs120colocalizes with RabERAB11, arriving at late Golgi cisternae as they dissipate into exocytic carriers. Thus, TRAPPII marks, and possibly determines, the Golgi–to–post-Golgi transition.
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