The AP-1A and AP-1B clathrin adaptor complexes define biochemically and functionally distinct membrane domains

Most epithelial cells contain two AP-1 clathrin adaptor complexes. AP-1A is ubiquitously expressed and involved in transport between the TGN and endosomes. AP-1B is expressed only in epithelia and mediates the polarized targeting of membrane proteins to the basolateral surface. Both AP-1 complexes are heterotetramers and differ only in their 50-kD mu1A or mu1B subunits. Here, we show that AP-1A and AP-1B, together with their respective cargoes, define physically and functionally distinct membrane domains in the perinuclear region. Expression of AP-1B (but not AP-1A) enhanced the recruitment of at least two subunits of the exocyst complex (Sec8 and Exo70) required for basolateral transport. By immunofluorescence and cell fractionation, the exocyst subunits were found to selectively associate with AP-1B-containing membranes that were both distinct from AP-1A-positive TGN elements and more closely apposed to transferrin receptor-positive recycling endosomes. Thus, despite the similarity of the two AP-1 complexes, AP-1A and AP-1B exhibit great specificity for endosomal transport versus cell polarity.     

Distribution and function of AP-1 clathrin adaptor complexes in polarized epithelial cells

Expression of the epithelial cell-specific heterotetrameric adaptor complex AP-1B is required for the polarized distribution of many membrane proteins to the basolateral surface of LLC-PK1 kidney cells. AP-1B is distinguished from the ubiquitously expressed AP-1A by exchange of its single 50-kD mu subunit, mu1A, being replaced by the closely related mu1B. Here we show that this substitution is sufficient to couple basolateral plasma membrane proteins, such as a low-density lipoprotein receptor (LDLR), to the AP-1B complex and to clathrin. The interaction between LDLR and AP-1B is likely to occur in the trans-Golgi network (TGN), as was suggested by the localization of functional, epitope-tagged mu1 by immunofluorescence and immunoelectron microscopy. Tagged AP-1A and AP-1B complexes were found in the perinuclear region close to the Golgi complex and recycling endosomes, often in clathrin-coated buds and vesicles. Yet, AP-1A and AP-1B localized to different subdomains of the TGN, with only AP-1A colocalizing with furin, a membrane protein that uses AP-1 to recycle between the TGN and endosomes. We conclude that AP-1B functions by interacting with its cargo molecules and clathrin in the TGN, where it acts to sort basolateral proteins from proteins destined for the apical surface and from those selected by AP-1A for transport to endosomes and lysosomes.     

mu1A-adaptin-deficient mice: lethality, loss of AP-1 binding and rerouting of mannose 6-phosphate receptors

The heterotetrameric AP-1 complex is involved in the formation of clathrin-coated vesicles at the trans-Golgi network (TGN) and interacts with sorting signals in the cytoplasmic tails of cargo molecules. Targeted disruption of the mouse mu1A-adaptin gene causes embryonic lethality at day 13.5. In cells deficient in micro1A-adaptin the remaining AP-1 adaptins do not bind to the TGN. Polarized epithelial cells are the only cells of micro1A-adaptin-deficient embryos that show gamma-adaptin binding to membranes, indicating the formation of an epithelial specific AP-1B complex and demonstrating the absence of additional mu1A homologs. Mannose 6-phosphate receptors are cargo molecules that exit the TGN via AP-1-clathrin-coated vesicles. The steady-state distribution of the mannose 6-phosphate receptors MPR46 and MPR300 in mu1A-deficient cells is shifted to endosomes at the expense of the TGN. MPR46 fails to recycle back from the endosome to the TGN, indicating that AP-1 is required for retrograde endosome to TGN transport of the receptor.     

Clathrin Terminal Domain-Ligand Interactions Regulate Sorting of Mannose 6-Phosphate Receptors Mediated by AP-1 and GGA Adaptors

Clathrin plays important roles in intracellular membrane traffic including endocytosis of plasma membrane proteins and receptors and protein sorting between the trans-Golgi network (TGN) and endosomes. Whether clathrin serves additional roles in receptor recycling, degradative sorting, or constitutive secretion has remained somewhat controversial. Here we have used acute pharmacological perturbation of clathrin terminal domain (TD) function to dissect the role of clathrin in intracellular membrane traffic. We report that internalization of major histocompatibility complex I (MHCI) is inhibited in cells depleted of clathrin or its major clathrin adaptor complex 2 (AP-2), a phenotype mimicked by application of Pitstop® inhibitors of clathrin TD function. Hence, MHCI endocytosis occurs via a clathrin/AP-2-dependent pathway. Acute perturbation of clathrin also impairs the dynamics of intracellular clathrin/adaptor complex 1 (AP-1)- or GGA (Golgi-localized, γ-ear-containing, Arf-binding protein)-coated structures at the TGN/endosomal interface, resulting in the peripheral dispersion of mannose 6-phosphate receptors. By contrast, secretory traffic of vesicular stomatitis virus G protein, recycling of internalized transferrin from endosomes, or degradation of EGF receptor proceeds unperturbed in cells with impaired clathrin TD function. These data indicate that clathrin is required for the function of AP-1- and GGA-coated carriers at the TGN but may be dispensable for outward traffic en route to the plasma membrane.     

The clathrin adaptor AP-1A mediates basolateral polarity

Clathrin and the epithelial-specific clathrin adaptor AP-1B mediate basolateral trafficking in epithelia. However, several epithelia lack AP-1B, and mice knocked out for AP-1B are viable, suggesting the existence of additional mechanisms that control basolateral polarity. Here, we demonstrate a distinct role of the ubiquitous clathrin adaptor AP-1A in basolateral protein sorting. Knockdown of AP-1A causes missorting of basolateral proteins in MDCK cells, but only after knockdown of AP-1B, suggesting that AP-1B can compensate for lack of AP-1A. AP-1A localizes predominantly to the TGN, and its knockdown promotes spillover of basolateral proteins into common recycling endosomes, the site of function of AP-1B, suggesting complementary roles of both adaptors in basolateral sorting. Yeast two-hybrid assays detect interactions between the basolateral signal of transferrin receptor and the medium subunits of both AP-1A and AP-1B. The basolateral sorting function of AP-1A reported here establishes AP-1 as a major regulator of epithelial polarity.     

ADP-Ribosylation Factor 1 Transiently Activates High-Affinity Adaptor Protein Complex AP-1 Binding Sites On Golgi Membranes

Association of the Golgi-specific adaptor protein complex 1 (AP-1) with the membrane is a prerequisite for clathrin coat assembly on the trans-Golgi network (TGN). The AP-1 adaptor is efficiently recruited from cytosol onto the TGN by myristoylated ADP-ribosylation factor 1 (ARF1) in the presence of the poorly hydrolyzable GTP analog guanosine 5′-O-(3-thiotriphosphate) (GTPγS). Substituting GTP for GTPγS, however, results in only poor AP-1 binding. Here we show that both AP-1 and clathrin can be recruited efficiently onto the TGN in the presence of GTP when cytosol is supplemented with ARF1. Optimal recruitment occurs at 4 μM ARF1 and with 1 mM GTP. The AP-1 recruited by ARF1·GTP is released from the Golgi membrane by treatment with 1 M Tris-HCl (pH 7) or upon reincubation at 37°C, whereas AP-1 recruited with GTPγS or by a constitutively active point mutant, ARF1(Q71L), remains membrane bound after either treatment. An incubation performed with added ARF1, GTP, and AlF_n, used to block ARF GTPase-activating protein activity, results in membrane-associated AP-1, which is largely insensitive to Tris extraction. Thus, ARF1·GTP hydrolysis results in lower-affinity binding of AP-1 to the TGN. Using two-stage assays in which ARF1·GTP first primes the Golgi membrane at 37°C, followed by AP-1 binding on ice, we find that the high-affinity nucleating sites generated in the priming stage are rapidly lost. In addition, the AP-1 bound to primed Golgi membranes during a second-stage incubation on ice is fully sensitive to Tris extraction, indicating that the priming stage has passed the ARF1·GTP hydrolysis point. Thus, hydrolysis of ARF1·GTP at the priming sites can occur even before AP-1 binding. Our finding that purified clathrin-coated vesicles contain little ARF1 supports the concept that ARF1 functions in the coat assembly process rather than during the vesicle-uncoating step. We conclude that ARF1 is a limiting factor in the GTP-stimulated recruitment of AP-1 in vitro and that it appears to function in a stoichiometric manner to generate high-affinity AP-1 binding sites that have a relatively short half-life.     

Trafficking of yellow-fluorescent-protein-tagged mu1 subunit of clathrin adaptor AP-1 complex in living cells

Clathrin adaptor protein AP-1 complex is thought to function in forming clathrin-coated vesicles at the trans -Golgi network (TGN) and mediating transport of cargo between the TGN and endosomes. To study trafficking of AP-1 in living cells, yellow fluorescent protein (YFP) was inserted in the middle of µ1 A subunit of AP-1. When expressed in a tetracycline-dependent manner in HeLa cells, YFP-µ1 was efficiently incorporated into the AP-1 complex, replacing endogenous µ1 in most of cellular AP-1. Time-lapse imaging revealed that YFP-µ1/AP-1 departs from TGN as isolated vesicles and spherical structures, or varicosities, associated with fine tubular processes. Typically, several vesicles or varicosities were seen moving sequentially along the same 'tracks' from TGN to cell periphery. These data suggest that AP-1 may function after formation of Golgi transport intermediates in facilitating their intracellular movement. Mutagenesis of YFP-µ1 determined that the structural requirements for its binding to tyrosine-containing sequence motifs are similar to those previously defined in µ2 subunit of AP-2. Moreover, the carboxyl-terminal half of µ2 could replace the corresponding fragment of µ1 without loss of the ability of the resulting µ1-YFP-µ2 chimeric protein to incorporate into AP-1 and bind tyrosine-containing motifs. Mutations that abolish binding capacity for tyrosine motifs did not mistarget AP-1 in the cell, suggesting that AP-1 interactions with this type of sorting signals are not essential for membrane docking of AP-1 at the TGN. Altogether, this study demonstrates that YFP-tagged µ1 protein can serve as a useful tool for visualizing the dynamics of AP-1 in living cells and for the structure-function analysis of µ1–cargo interactions.     

Structural Basis for the Recognition of Tyrosine-based Sorting Signals by the μ3A Subunit of the AP-3 Adaptor Complex

Tyrosine-based signals fitting the YXXØ motif mediate sorting of transmembrane proteins to endosomes, lysosomes, the basolateral plasma membrane of polarized epithelial cells, and the somatodendritic domain of neurons through interactions with the homologous μ1, μ2, μ3, and μ4 subunits of the corresponding AP-1, AP-2, AP-3, and AP-4 complexes. Previous x-ray crystallographic analyses identified distinct binding sites for YXXØ signals on μ2 and μ4, which were located on opposite faces of the proteins. To elucidate the mode of recognition of YXXØ signals by other members of the μ family, we solved the crystal structure at 1.85 Å resolution of the C-terminal domain of the μ3 subunit of AP-3 (isoform A) in complex with a peptide encoding a YXXØ signal (SDYQRL) from the trans-Golgi network protein TGN38. The μ3A C-terminal domain consists of an immunoglobulin-like β-sandwich organized into two subdomains, A and B. The YXXØ signal binds in an extended conformation to a site on μ3A subdomain A, at a location similar to the YXXØ-binding site on μ2 but not μ4. The binding sites on μ3A and μ2 exhibit similarities and differences that account for the ability of both proteins to bind distinct sets of YXXØ signals. Biochemical analyses confirm the identification of the μ3A site and show that this protein binds YXXØ signals with 14–19 μm affinity. The surface electrostatic potential of μ3A is less basic than that of μ2, in part explaining the association of AP-3 with intracellular membranes having less acidic phosphoinositides.     

Phosphatidylinositol 3,4,5-trisphosphate Localization in Recycling Endosomes Is Necessary for AP-1B–dependent Sorting in Polarized Epithelial Cells

Polarized epithelial cells coexpress two almost identical AP-1 clathrin adaptor complexes: the ubiquitously expressed AP-1A and the epithelial cell–specific AP-1B. The only difference between the two complexes is the incorporation of the respective medium subunits μ1A or μ1B, which are responsible for the different functions of AP-1A and AP-1B in TGN to endosome or endosome to basolateral membrane targeting, respectively. Here we demonstrate that the C-terminus of μ1B is important for AP-1B recruitment onto recycling endosomes. We define a patch of three amino acid residues in μ1B that are necessary for recruitment of AP-1B onto recycling endosomes containing phosphatidylinositol 3,4,5-trisphosphate [PI(3,4,5)P₃]. We found this lipid enriched in recycling endosomes of epithelial cells only when AP-1B is expressed. Interfering with PI(3,4,5)P₃ formation leads to displacement of AP-1B from recycling endosomes and missorting of AP-1B–dependent cargo to the apical plasma membrane. In conclusion, PI(3,4,5)P₃ formation in recycling endosomes is essential for AP-1B function.     

Yeast Golgi-localized, gamma-Ear-containing, ADP-ribosylation factor-binding proteins are but adaptor protein-1 is not required for cell-free transport of membrane proteins from the trans-Golgi network to the prevacuolar compartment

Golgi-localized, γ-Ear–containing, ADP-ribosylation factor-binding proteins (GGAs) and adaptor protein-1 (AP-1) mediate clathrin-dependent trafficking of transmembrane proteins between the trans-Golgi network (TGN) and endosomes. In yeast, the vacuolar sorting receptor Vps10p follows a direct pathway from the TGN to the late endosome/prevacuolar compartment (PVC), whereas, the processing protease Kex2p partitions between the direct pathway and an indirect pathway through the early endosome. To examine the roles of the Ggas and AP-1 in TGN–PVC transport, we used a cell-free assay that measures delivery to the PVC of either Kex2p or a chimeric protein (K-V), in which the Vps10p cytosolic tail replaces the Kex2p tail. Either antibody inhibition or dominant-negative Gga2p completely blocked K-V transport but only partially blocked Kex2p transport. Deletion of APL2, encoding the β subunit of AP-1, did not affect K-V transport but partially blocked Kex2p transport. Residual Kex2p transport seen with apl2Δ membranes was insensitive to dominant-negative Gga2p, suggesting that the apl2Δ mutation causes Kex2p to localize to a compartment that precludes Gga-dependent trafficking. These results suggest that yeast Ggas facilitate the specific and direct delivery of Vps10p and Kex2p from the TGN to the PVC and that AP-1 modulates Kex2p trafficking through a distinct pathway, presumably involving the early endosome.     

Defective HIV-1 Particle Assembly in AP-3-Deficient Cells Derived from Patients with Hermansky-Pudlak Syndrome Type 2

Adaptor protein complex 3 (AP-3) is a heterotetramer that is involved in signal-mediated protein sorting to endosomal-lysosomal organelles. AP-3 deficiency in humans, induced by mutations in the AP3B1 gene, which encodes the β3A subunit of the AP-3 complex, results in Hermansky-Pudlak syndrome 2 (HPS2), which is a rare genetic disorder with defective lysosome-related organelles. In a previous study, we identified the AP-3 complex as an important contributor to HIV-1 assembly and release. We hypothesized that cells from patients affected by HPS2 should demonstrate abnormalities of HIV-1 assembly. Here we report that HIV-1 particle assembly and release are indeed diminished in HPS2 fibroblast cultures. Transient or stable expression of the full-length wild-type β3A subunit in HPS2 fibroblasts restored the impaired virus assembly and release. In contrast, virus-like particle release mediated by MA-deficient Gag mutants lacking the AP-3 binding site was not altered in HPS2 cells, indicating that the MA domain serves as the major viral determinant required for the recruitment of the AP-3 complex. AP-3 deficiency decreased HIV-1 Gag localization at the plasma membrane and late endosomes and increased the accumulation of HIV-1 Gag at an intermediate step between early and late endosomes. Blockage of the clathrin-mediated endocytic pathway in HPS2 cells did not reverse the inhibited virus assembly and release imposed by the AP-3 deficiency. These results demonstrate that the intact and stable AP-3 complex is required for HIV-1 assembly and release, and the involvement of the AP-3 complex in late stages of the HIV-1 replication cycle is independent of clathrin-mediated endocytosis.     

Mannose 6–Phosphate Receptors Are Sorted from Immature Secretory Granules via Adaptor Protein AP-1, Clathrin, and Syntaxin 6–positive Vesicles

The occurrence of clathrin-coated buds on immature granules (IGs) of the regulated secretory pathway suggests that specific transmembrane proteins are sorted into these buds through interaction with cytosolic adaptor proteins. By quantitative immunoelectron microscopy of rat endocrine pancreatic β cells and exocrine parotid and pancreatic cells, we show for the first time that the mannose 6–phosphate receptors (MPRs) for lysosomal enzyme sorting colocalize with the AP-1 adaptor in clathrin-coated buds on IGs. Furthermore, the concentrations of both MPR and AP-1 decline by ~90% as the granules mature. Concomitantly, in exocrine secretory cells lysosomal proenzymes enter and then are sorted out of IGs, just as was previously observed in β cells (Kuliawat, R., J. Klumperman, T. Ludwig, and P. Arvan. 1997. J. Cell Biol. 137:595–608). The exit of MPRs in AP-1/clathrin-coated buds is selective, indicated by the fact that the membrane protein phogrin is not removed from maturing granules. We have also made the first observation of a soluble N-ethylmaleimide–sensitive factor attachment protein receptor, syntaxin 6, which has been implicated in clathrin-coated vesicle trafficking from the TGN to endosomes (Bock, J.B., J. Klumperman, S. Davanger, and R.H. Scheller. 1997. Mol. Biol. Cell. 8:1261–1271) that enters and then exits the regulated secretory pathway during granule maturation. Thus, we hypothesize that during secretory granule maturation, MPR–ligand complexes and syntaxin 6 are removed from IGs by AP-1/clathrin-coated vesicles, and then delivered to endosomes.     

The Role of ADP-ribosylation Factor and Phospholipase D in Adaptor Recruitment

AP-1 and AP-2 adaptors are recruited onto the TGN and plasma membrane, respectively. GTPγS stimulates the recruitment of AP-1 onto the TGN but causes AP-2 to bind to an endosomal compartment (Seaman, M.N.J., C.L. Ball, and M.S. Robinson. 1993. J. Cell Biol. 123:1093–1105). We have used subcellular fractionation followed by Western blotting, as well as immunofluorescence and immunogold electron microscopy, to investigate both the recruitment of AP-2 adaptors onto the plasma membrane and their targeting to endosomes, and we have also examined the recruitment of AP-1 under the same conditions. Two lines of evidence indicate that the GTPγS-induced targeting of AP-2 to endosomes is mediated by ADP-ribosylation factor-1 (ARF1). First, GTPγS loses its effect when added to ARF-depleted cytosol, but this effect is restored by the addition of recombinant myristoylated ARF1. Second, adding constitutively active Q71L ARF1 to the cytosol has the same effect as adding GTPγS. The endosomal membranes that recruit AP-2 adaptors have little ARF1 or any of the other ARFs associated with them, suggesting that ARF may be acting catalytically. The ARFs have been shown to activate phospholipase D (PLD), and we find that addition of exogenous PLD has the same effect as GTPγS or Q71L ARF1. Neomycin, which inhibits endogenous PLD by binding to its cofactor phosphatidylinositol 4,5-bisphosphate, prevents the recruitment of AP-2 not only onto endosomes but also onto the plasma membrane, suggesting that both events are mediated by PLD. Surprisingly, however, neither PLD nor neomycin has any effect on the recruitment of AP-1 adaptors onto the TGN, even though AP-1 recruitment is ARF mediated. These results indicate that different mechanisms are used for the recruitment of AP-1 and AP-2.     

KIF16B delivers for transcytosis

EMBO J 32 15, 2125–2139 doi:10.1038/emboj.2013.130; published online June072013Protein sorting pathways control correct delivery of membrane proteins to specific compartments of the plasma membrane and are required to maintain the physiological functions in all epithelia. Most clathrin-dependent cargoes require the adaptor protein complexes AP-1A and AP-1B for proper sorting to the basolateral plasma membrane. In this issue of The EMBO Journal, Perez Bay et al (2013) shed light on the mechanism of basal-to-apical protein transport, or transcytosis, of the transferrin receptor in natively AP-1B-deficient epithelia. In AP-1B-deficient epithelia, the transferrin receptor transcytoses through the apical recycling endosome, and requires Rab11. Furthermore, they characterize a novel and specific role for the endosomal microtubule motor Kinesin KIF16B in transferrin receptor apical transport. These findings constitute the first characterization of a specific microtubule motor involved in basal-to-apical transcytosis in epithelia.Epithelial cells present a compartmentalized plasma membrane, where the composition of each compartment is tightly controlled by a precise protein and lipid sorting machinery (Folsch, 2008). The two most conspicuous compartments are the apical and basolateral domains, which generate and segregate from each other through the formation of apically localized junctional complexes. Protein sorting mechanisms ensure delivery of newly synthesized or recycled, protein components to their proper localization in either the apical or basolateral plasma membrane domains. Vectorial transport of proteins requires sorting determinants that are present in the cytoplasmic, transmembrane or extracellular domains. Most of the information that we have about these sorting determinants comes from the basolateral traffic, which depends on clathrin adaptor proteins (APs) AP-1A/B, AP-3 and AP-4 (Gonzalez and Rodriguez-Boulan, 2009). Specific APs bind to cytoplasmic sorting motifs in transmembrane proteins and recruit clathrin-coat components, which sequentially induce membrane curvature, clathrin oligomerization, vesicle budding and fission (Ohno, 2006; Hirst et al, 2011). Mammalian cells present five different AP complexes (AP1–5), each constituted by a heterotetramer of one α-, γ-, δ-, ɛ- or ζ-subunit, one β(1–5) subunit, one σ(1–5) subunit and one μ(1–5) subunit. How these clathrin-coated vesicles deliver membranes to precise compartments in the cell to regulate protein sorting is still poorly understood. The AP1 complex is a key regulator of basolateral polarity (Folsch et al, 1999; Gan et al, 2002; Gravotta et al, 2012). The AP1 complex μ-subunit presents two isoforms μ1A and μ1B, which define the formation of two different complexes, AP-1A and AP-1B, both required for basolateral polarity. AP-1A is ubiquitously expressed in different tissues and localizes mainly to the trans-Golgi network. In contrast, AP-1B is primarily localized to common recycling endosomes (CRE) and is specifically expressed in the majority of epithelial tissues, with the remarkable exception of retinal pigment epithelium and the proximal convoluted tubule in the nephron, which sort most of the basolateral cargo to the apical surface.A wide array of model membrane proteins requires AP-1B to properly localize to the basolateral membrane, including the low-density lipoprotein receptor (LDLR), the VSV-G protein and the transferrin receptor (TfR). Furthermore, the expression of μ1B in μ1B-deficient epithelial cell line LLC-PK1 is sufficient to prevent apical sorting of TfR, indicating that AP-1B is a main player in this clathrin-mediated basolateral sorting pathway. Interestingly, the results of the present study suggest that transcytosis (a membrane trafficking pathway that transports apical or basolateral proteins to the opposite domain in the plasma membrane) is the main mechanism for apical transport of clathrin-dependent cargoes in AP-1B-deficient cells. Basal-to-apical transcytosis of the polymeric IgA receptor (pIgAR) is the best-known transcytotic pathway, and requires several steps in which the receptor complex traverses multiple compartments before reaching a Rab11-positive apical recycling compartment, from where it is sorted to the apical plasma membrane (Golachowska et al, 2010). Polymeric IgA receptor transcytosis requires the function of cytoskeletal proteins for its correct delivery to the apical membrane, including microtubules and actin binding motors. However, no specific microtubule motor has ever been described associated with transcytosis.In the present study, Perez Bay et al (2013) analyse how the TfR is transported to the apical membrane in μ1B-deficient epithelia using as model system the retinal pigment epithelium cell line, which lacks AP-1B, and MDCK cells. They show that basolateral administration of labelled Tf results in its endocytosis and transcytosis towards the apical membrane in AP-1B-depleted MDCK cells, following a pathway that involves Rab11-positive apical recycling endosomes (AREs), and requires Rab11 for its correct delivery. Additionally, they find that TfR transport into AREs depends on microtubules and the kinesin KIF16B, a specific microtubule motor present in the CRE (Figure 1). KIF16B is a plus-end microtubule motor that binds to PtdIns(3)P and GTP-bound Rab14 and regulates the distribution of early endosomes (Hoepfner et al, 2005; Ueno et al, 2011). Surprisingly though, apical transport of pIgAR is not affected by the expression of a KIF16B-dominant negative mutant, which suggests that assembly of KIF16B/TfR carriers occurs downstream of cargo separation during transcytosis. It is also tempting to speculate that more than one transcytosis pathways are at play, and while TfR uses the KIF16B-dependent pathway, pIgAR is transported through a KIF16B independent mechanism. This article is the first study of KIF16B in epithelial cells, and the first showing involvement of a microtubule motor in transcytosis, more than 20 years after the pioneering studies that characterized the role of microtubules in this process (Hunziker et al, 1990).Open in a separate windowFigure 1KIF16B controls basal-to-apical transcytosis of transferrin receptor in AP-1B-deficient epithelia. In AP-1B-expressing epithelia (such as MDCK cells), transferrin receptor (TfR) is endocytosed and sorted to common recycling endosomes, where AP-1B-clathrin-vesicles assemble and transport the protein to the basolateral plasma membrane. In AP-1B-deficient epithelia (such as RPE cells), internalized TfR is instead sorted by the plus-end directed microtubule motor KIF16B towards the ARE, and then transcytosed to the apical plasma membrane through a Rab11-regulated pathway. Polymeric IgA receptor is internalized into the same basolateral endosomes, but it uses a KIF16B-independent pathway to reach the apical membrane.As a whole, this paper represents a significant advance in our understanding of the protein sorting machinery in epithelial cells, and importantly, opens new questions that will be addressed in future studies. First, is the KIF16B-dependent recycling/sorting pathway required for other cargoes, especially in AP-1B-positive epithelia? Second, why TfR, but not pIgAR, requires KIF16B for correct sorting? Although KIF16B is not required for pIgAR transcytosis, its transport route still requires microtubules, thus opening the possibility for discovery of additional microtubule motors involved in transcytosis. And finally, what is the mechanism of KIF16B binding to TfR-positive recycling endosomes? It is possible that the mechanism depends on the activation of Rab14, which has been characterized as a regulator of lipid-raft transport from the Golgi apparatus to recycling endosomes (Ueno et al, 2011).     

AP1/2β-mediated exocytosis of tapetum-specific transporters is required for pollen development in Arabidopsis thaliana

AP-1 and AP-2 adaptor protein (AP) complexes mediate clathrin-dependent trafficking at the trans-Golgi network (TGN) and the plasma membrane, respectively. Whereas AP-1 is required for trafficking to plasma membrane and vacuoles, AP-2 mediates endocytosis. These AP complexes consist of four subunits (adaptins): two large subunits (β1 and γ for AP-1 and β2 and α for AP-2), a medium subunit μ, and a small subunit σ. In general, adaptins are unique to each AP complex, with the exception of β subunits that are shared by AP-1 and AP-2 in some invertebrates. Here, we show that the two putative Arabidopsis thaliana AP1/2β adaptins co-assemble with both AP-1 and AP-2 subunits and regulate exocytosis and endocytosis in root cells, consistent with their dual localization at the TGN and plasma membrane. Deletion of both β adaptins is lethal in plants. We identified a critical role of β adaptins in pollen wall formation and reproduction, involving the regulation of membrane trafficking in the tapetum and pollen germination. In tapetal cells, β adaptins localize almost exclusively to the TGN and mediate exocytosis of the plasma membrane transporters such as ATP-binding cassette (ABC)G9 and ABCG16. This study highlights the essential role of AP1/2β adaptins in plants and their specialized roles in specific cell types.

Arabidopsis AP1/2β adaptins are shared by the AP-1 and AP-2 complexes and required for pollen development by mediating the trafficking of ABCG transporters in tapetal cells.

IN A NUTSHELL Background: Adaptor protein (AP) complexes are critical for the recruitment of cargo proteins during vesicle trafficking. AP-1 and AP-2 mediate clathrin-dependent trafficking at the trans-Golgi network (TGN) and the plasma membrane, respectively. Whereas AP-1 regulates trafficking to the plasma membrane (exocytosis) and vacuole, AP-2 mediates endocytosis. These AP complexes consist of four subunits (adaptins): two large subunits (β1 and γ for AP-1, β2, and α for AP-2), a medium subunit μ, and a small subunit σ. The general roles of some AP-1 and AP-2 adaptins in vegetative and reproductive development have been characterized in plants. However, the function of the large β subunits and whether they are shared by the two AP-1 and AP-2 complexes in plants is currently unknown. Questions: Are β adaptins shared by AP-1 and AP-2 complexes in Arabidopsis thaliana? What function do they play in plant development? Findings: We found that the two putative Arabidopsis AP1/2β adaptins co-assemble with both AP-1 and AP-2 subunits and regulate exocytosis and endocytosis in root cells, consistent with their dual localization to the TGN and the plasma membrane. However, in tapetal cells of developing anthers, AP1/2β adaptins localize almost exclusively to TGN. Mutations in AP1/2β adaptins result in collapsed pollen grains with abnormal walls and reduced pollen germination due to impaired exocytosis of the tapetum-specific plasma membrane transporters ABCG9 and ABCG16, highlighting the essential role of AP1/2β adaptins in plants and their specialized roles in specific cell types. Next steps: We will investigate the mechanism by which AP1/2β adaptins recognize cargo proteins and their role in female gametophyte and embryonic development.     

The epithelial-specific adaptor AP1B mediates post-endocytic recycling to the basolateral membrane

To perform vectorial secretory and transport functions that are critical for the survival of the organism, epithelial cells sort plasma membrane proteins into polarized apical and basolateral domains. Sorting occurs post-synthetically, in the trans Golgi network (TGN) or after internalization from the cell surface in recycling endosomes, and is mediated by apical and basolateral sorting signals embedded in the protein structure. Basolateral sorting signals include tyrosine motifs in the cytoplasmic domain that are structurally similar to signals involved in receptor internalization by clathrin-coated pits. Recently, an epithelial-specific adaptor protein complex, AP1B, was identified. AP-1B recognizes a subset of basolateral tyrosine motifs through its mu 1B subunit. Here, we characterized the post-synthetic and post-endocytic sorting of the fast recycling low density lipoprotein receptor (LDLR) and transferrin receptor (TfR) in LLC-PK1 cells, which lack mu 1B and mis-sort both receptors to the apical surface. Targeting and recycling assays in LLC-PK1 cells, before and after transfection with mu 1B, and in MDCK cells, which express mu 1B constitutively, suggest that AP1B sorts basolateral proteins post-endocytically.     

Differential use of two AP-3-mediated pathways by lysosomal membrane proteins

The adaptor protein complex AP-3 is involved in the sorting of lysosomal membrane proteins to late endosomes/lysosomes. It is unclear whether AP-3-containing vesicles form at the trans-Golgi network (TGN) or early endosomes. We have compared the trafficking routes of endolyn/CD164 and 'typical' lysosomal membrane glycoproteins (lgp120/lamp-1 and CD63/lamp-3) containing cytosolic YXXPhi-targeting motifs preceded by asparagine and glycine, respectively. Endolyn, which has a NYHTL-motif, is concentrated in lysosomes, but also occurs in endosomes and at the cell surface. We observed predominant interaction of the NYHTL-motif with the mu-subunits of AP-3 in the yeast two-hybrid system. Endolyn was mislocalized to the cell surface in AP-3-deficient pearl cells, confirming a major role of AP-3 in endolyn traffic. However, lysosomal delivery of endolyn (or a NYHTL-reporter), but not GYXXPhi-containing proteins, was practically abolished when AP-2-mediated endocytosis or traffic from early to late endosomes was inhibited in NRK and 3T3 cells. This indicates that endolyn is mostly transported along the indirect lysosomal pathway (via the cell surface), rather than directly from the TGN to late endosomes/lysosomes. Our results suggest that AP-3 mediates lysosomal sorting of some membrane proteins in early endosomes in addition to sorting of proteins with intrinsically strong AP-3-interacting lysosomal targeting motifs at the TGN.     

Sip1, a Conserved AP-1 Accessory Protein,Is Important for Golgi/Endosome Trafficking in Fission Yeast

We had previously identified the mutant allele of apm1⁺ that encodes a homolog of the mammalian μ 1A subunit of the clathrin-associated adaptor protein-1 (AP-1) complex and demonstrated that the AP-1 complex plays a role in Golgi/endosome trafficking, secretion, and vacuole fusion in fission yeast. Here, we isolated a mutant allele of its4⁺/sip1⁺, which encodes a conserved AP-1 accessory protein. The its4-1/sip1-i4 mutants and apm1 -deletion cells exhibited similar phenotypes, including sensitivity to the calcineurin inhibitor FK506, Cl⁻ and valproic acid as well as various defects in Golgi/endosomal trafficking and cytokinesis. Electron micrographs of sip1-i4 mutants revealed vacuole fragmentation and accumulation of abnormal Golgi-like structures and secretory vesicles. Overexpression of Apm1 suppressed defective membrane trafficking in sip1-i4 mutants. The Sip1-green fluorescent protein (GFP) co-localized with Apm1-mCherry at Golgi/endosomes, and Sip1 physically interacted with each subunit of the AP-1 complex. We found that Sip1 was a Golgi/endosomal protein and the sip1-i4 mutation affected AP-1 localization at Golgi/endosomes, thus indicating that Sip1 recruited the AP-1 complex to endosomal membranes by physically interacting with each subunit of this complex. Furthermore, Sip1 is required for the correct localization of Bgs1/Cps1, 1,3-β-D-glucan synthase to polarized growth sites. Consistently, the sip1-i4 mutants displayed a severe sensitivity to micafungin, a potent inhibitor of 1,3-β-D-glucan synthase. Taken together, our findings reveal a role for Sip1 in the regulation of Golgi/endosome trafficking in coordination with the AP-1 complex, and identified Bgs1, required for cell wall synthesis, as the new cargo of AP-1-dependent trafficking.     

The Adaptor Complex AP-4 Regulates Vacuolar Protein Sorting at the trans-Golgi Network by Interacting with VACUOLAR SORTING RECEPTOR1

Adaptor protein (AP) complexes play critical roles in protein sorting among different post-Golgi pathways by recognizing specific cargo protein motifs. Among the five AP complexes (AP-1–AP-5) in plants, AP-4 is one of the most poorly understood; the AP-4 components, AP-4 cargo motifs, and AP-4 functional mechanism are not known. Here, we identify the AP-4 components and show that the AP-4 complex regulates receptor-mediated vacuolar protein sorting by recognizing VACUOLAR SORTING RECEPTOR1 (VSR1), which was originally identified as a sorting receptor for seed storage proteins to target protein storage vacuoles in Arabidopsis (Arabidopsis thaliana). From the vacuolar sorting mutant library GREEN FLUORESCENT SEED (GFS), we isolated three gfs mutants that accumulate abnormally high levels of VSR1 in seeds and designated them as gfs4, gfs5, and gfs6. Their responsible genes encode three (AP4B, AP4M, and AP4S) of the four subunits of the AP-4 complex, respectively, and an Arabidopsis mutant (ap4e) lacking the fourth subunit, AP4E, also had the same phenotype. Mass spectrometry demonstrated that these four proteins form a complex in vivo. The four mutants showed defects in the vacuolar sorting of the major storage protein 12S globulins, indicating a role for the AP-4 complex in vacuolar protein transport. AP4M bound to the tyrosine-based motif of VSR1. AP4M localized at the trans-Golgi network (TGN) subdomain that is distinct from the AP-1-localized TGN subdomain. This study provides a novel function for the AP-4 complex in VSR1-mediated vacuolar protein sorting at the specialized domain of the TGN.Membrane trafficking in plants shares many fundamental features with those in yeast and animals (Bassham et al., 2008). In general, vacuolar proteins are synthesized on the rough endoplasmic reticulum and then transported to vacuoles via the Golgi apparatus (Xiang et al., 2013; Robinson and Pimpl, 2014). The vacuolar trafficking in plants has been studied by monitoring the transport of reporter proteins to lytic vacuoles in vegetative cells and tissues (Jin et al., 2001; Pimpl et al., 2003; Miao et al., 2008; Niemes et al., 2010). Recently, seed storage proteins became a model cargo for monitoring the transport of endogenous vacuolar proteins in plants (Shimada et al., 2003a; Sanmartín et al., 2007; Isono et al., 2010; Pourcher et al., 2010; Uemura et al., 2012; Shirakawa et al., 2014). During seed maturation, a large amount of storage proteins are synthesized and sorted to specialized vacuoles, the protein storage vacuoles (PSVs). To properly deliver vacuolar proteins, sorting receptors play a critical role in recognizing the vacuole-targeting signal of the proteins. VACUOLAR PROTEIN SORTING10 and Man-6-P receptor function as sorting receptors for vacuolar/lysosomal proteins in the trans-Golgi network (TGN) of yeast and mammals, respectively. The best-characterized sorting receptors in plants are VACUOLAR SORTING RECEPTOR (VSR) family proteins (De Marcos Lousa et al., 2012). VSRs have been shown to function in sorting both storage proteins to PSVs (Shimada et al., 2003a; Fuji et al., 2007) and lytic cargos to lytic vacuoles (Zouhar et al., 2010).To sort the receptors in the TGN into vacuoles/lysosomes, the adaptor protein (AP) complex binds the cytosolic domain of the receptors. The AP complexes form evolutionarily conserved machinery that mediates the post-Golgi trafficking in eukaryotic cells (Robinson, 2004). There are five types of AP complexes, AP-1 to AP-5. The functions of AP-1, AP-2, and AP-3 have been established. AP-1 appears to be involved in trafficking between the TGN and endosomes (Hirst et al., 2012), AP-2 is involved in clathrin-mediated endocytosis (McMahon and Boucrot, 2011), and AP-3 is involved in protein trafficking from the TGN/endosomes to the vacuole/lysosomes (Dell’Angelica, 2009). However, little is known about AP-4 and AP-5. Mammalian AP-4 may be involved in basolateral sorting in polarized cells and in the transport of specific cargo proteins, such as the amyloid precursor protein APP, from the TGN to endosomes (Burgos et al., 2010). The fifth AP complex, AP-5, was recently identified, and its orthologs are widely conserved in the eukaryotic genomes (Hirst et al., 2011). The AP complexes exist as heterotetrameric proteins that consist of two large subunits (β1-5 and one each of ɣ/α/δ/ε/ζ), one medium subunit (µ1-5), and one small subunit (σ1-5). The sorting mechanism is best characterized for the medium (µ) subunit, which is known to recognize the Tyr-based YXXФ motif (where Ф represents Leu, Ile, Phe, Met, or Val) that is present in the cytosolic domains of cargo proteins (Ohno et al., 1995). Mutations of the YXXФ motif abolish the interaction with µ and alter the subcellular localization of the cargo proteins.The genome of Arabidopsis (Arabidopsis thaliana) contains all five sets of putative AP genes (Bassham et al., 2008; Hirst et al., 2011). The function of AP-4 in membrane trafficking and its physiological roles in plants are largely unknown. In this study, we identified and characterized the AP-4 complex in Arabidopsis. Mutants lacking the AP-4 subunits exhibited defects in VSR1-mediated vacuolar sorting of storage proteins in seeds. Our results provide new insights into the receptor-mediated vacuolar trafficking in post-Golgi pathways.