Endomembrane Trafficking Protein SEC24A Regulates Cell Size Patterning in Arabidopsis

Size is a critical property of a cell, but how it is determined is still not well understood. The sepal epidermis of Arabidopsis (Arabidopsis thaliana) contains cells with a diversity of sizes ranging from giant cells to small cells. Giant cells have undergone endoreduplication, a specialized cell cycle in which cells replicate their DNA but fail to divide, becoming polyploid and enlarged. Through forward genetics, we have identified a new mutant with ectopic giant cells covering the sepal epidermis. Surprisingly, the mutated gene, SEC24A, encodes a coat protein complex II vesicle coat subunit involved in endoplasmic reticulum-to-Golgi trafficking in the early secretory pathway. We show that the ectopic giant cells of sec24a-2 are highly endoreduplicated and that their formation requires the activity of giant cell pathway genes LOSS OF GIANT CELLS FROM ORGANS, DEFECTIVE KERNEL1, and Arabidopsis CRINKLY4. In contrast to other trafficking mutants, cytokinesis appears to occur normally in sec24a-2. Our study reveals an unexpected yet specific role of SEC24A in endoreduplication and cell size patterning in the Arabidopsis sepal.Size is a fundamental characteristic of a cell, but how cell size is determined is still not well understood in most living organisms (Marshall et al., 2012). Cells of different types typically have characteristic sizes, indicating that size is carefully regulated to fit cell functions during differentiation. At the simplest level, cell size is determined by growth and division. Although many factors regulating these two processes have been studied, how they are comprehensively regulated to achieve specific size outcomes remains unclear.The sepal of Arabidopsis (Arabidopsis thaliana) is an excellent model to study the regulation of cell size because it exhibits a characteristic pattern of giant cells interspersed in between small cells. The giant cells are large cells that span about one-fifth the length of the sepal (approximately 360 μm), while the smallest cells only reach to about 10 μm (Roeder et al., 2010). Previously, we have shown that variability in cell division times is sufficient to produce the cell size pattern (Roeder et al., 2010). The giant cells stop dividing and enter endoreduplication, a specialized cell cycle in which the cell replicates its DNA but skips mitosis to continue growing (Edgar and Orr-Weaver, 2001; Sugimoto-Shirasu and Roberts, 2003; Inzé and De Veylder, 2006; Breuer et al., 2010). Alongside the giant cells, the smaller cells continue dividing mitotically. Giant cells and small cells are different cell types, as they can be distinguished by the expression pattern of two independent enhancers. Furthermore, mutant screens have shown that genes involved in epidermal specification and cell cycle regulation are crucial for sepal cell size patterning. DEFECTIVE KERNEL1 (DEK1), Arabidopsis thaliana MERISTEM LAYER1 (ATML1), Arabidopsis CRINKLY4 (ACR4), and HOMEODOMAIN GLABROUS11 first establish the identity of giant cells, and then the cyclin dependent kinase inhibitor LOSS OF GIANT CELLS FROM ORGANS (LGO) influences the probability with which cells enter endoreduplication. Endoreduplication can further suppress the identity of small cells through an unknown mechanism (Roeder et al., 2010, 2012). The number of giant cells influences the curvature of the sepal, which is important for protecting the flower (Roeder et al., 2012). Therefore, cell size patterning ensures the protective role of sepals at the physiological level.The secretory pathway in eukaryotes is crucial for cells to maintain membrane homeostasis and protein localization. Proteins destined for the cell surface are first translated on the rough endoplasmic reticulum (ER) and then incorporated into coat protein complex II (COPII) vesicles that bud from ER membranes on the way to the Golgi apparatus. COPII machinery is highly conserved in eukaryotes, and each COPII component acts sequentially on the surface of the ER (Bickford et al., 2004; Marti et al., 2010; Zanetti et al., 2012). Vesicle coat assembly is initiated by SEC12, an ER membrane-anchored guanine nucleotide exchange factor (Barlowe and Schekman, 1993). SEC12 exchanges GDP with GTP on the small GTPase Secretion-associated RAS-related protein1 (SAR1), which increases the membrane affinity of SAR1. The ER membrane-bound SAR1 subsequently brings the SEC23/SEC24 subunits to form the prebudding complex, and eventually SEC13/SEC31 are recruited to increase rigidity of the COPII vesicle coat (Nakano and Muramatsu, 1989; Barlowe et al., 1994; Shaywitz et al., 1997; Aridor et al., 1998; Kuehn et al., 1998; Stagg et al., 2006; Copic et al., 2012). For COPII vesicles to fuse with the target membrane, superfamily N-ethylmaleimide-sensitive factor adaptor protein receptors (SNAREs) must be incorporated by SEC24 (Mossessova et al., 2003; Lipka et al., 2007; Mancias and Goldberg, 2008). In addition to its role in SNARE packaging, SEC24 also binds and loads secretory cargo proteins (Miller et al., 2003). Both the cargo and SNARE specificities are determined by the correspondence between the SEC24 isoform and the various ER export signals of cargoes and SNAREs (Barlowe., 2003; Miller et al., 2003; Mossessova et al., 2003; Mancias and Goldberg, 2008). The Arabidopsis genome encodes four SEC24 isoforms, SEC24A to SEC24D; how they differentially regulate trafficking is unknown (Bassham et al., 2008). Likewise, SEC24-cargo/SNARE interactions remain elusive in plants.Secretion defects in plants often lead to cell division defects due to the unique mechanisms of plants cytokinesis (Sylvester, 2000; Jürgens, 2005). In many eukaryotes other than plants, cytokinesis is accomplished by contraction of the cleavage furrow at the division plane. By contrast, cytokinesis in plants requires de novo secretion of vesicles to the division plane, after formation of the phragmoplast as the scaffold for delivery. Homotypic vesicle fusion sets up the early cell plate, which then expands laterally by fusing with other arriving vesicles (Balasubramanian et al., 2004; Jürgens, 2005; Reichardt et al., 2007). Hence, disruption of secretion in plants can often result in cytokinesis defects. For instance, a mutation in the SNARE KNOLLE leads to enlarged embryo cells with multiple nuclei (Lukowitz et al., 1996).Another common phenotype observed in secretion-deficient plants is abnormal auxin responses. The phytohormone auxin acts as a prominent signal in Arabidopsis development, and auxin influx/efflux carriers are essential in directing auxin transport and creating local maxima in an auxin gradient (Reinhardt et al., 2003; Heisler et al., 2005; Jönsson et al., 2006; Smith et al., 2006; Vanneste and Friml, 2009). To maintain appropriate auxin gradients, the subcellular localization of auxin carriers must be delicately regulated. Thus, auxin responses are highly sensitive to trafficking perturbations in plants (Geldner et al., 2003; Grunewald and Friml, 2010).Here, we have identified a new mutant with ectopic giant cells. Through positional cloning, we determined that the mutation occurs in the SEC24A gene, which encodes the cargo-binding subunit of the COPII vesicle complex. In addition to altered cell size, this unique sec24a-2 allele shows pleiotropic defects, including dwarfism, which have not been reported previously for other SEC24A alleles (Faso et al., 2009; Nakano et al., 2009; Conger et al., 2011). Although the mutant is developmentally aberrant, both cytokinesis and auxin response appear normal in sec24a-2, unlike other transport mutants. Instead, we find SEC24A regulates cell size specifically via the giant cell development pathway. Thus, our data reveal an unexpected role of SEC24A in endoreduplication and cell size patterning in the Arabidopsis sepal.     

Auxin-Mediated Ribosomal Biogenesis Regulates Vacuolar Trafficking in Arabidopsis

In plants, the mechanisms that regulate the transit of vacuolar soluble proteins containing C-terminal and N-terminal vacuolar sorting determinants (VSDs) to the vacuole are largely unknown. In a screen for Arabidopsis thaliana mutants affected in the trafficking of C-terminal VSD containing proteins, we isolated the ribosomal biogenesis mutant rpl4a characterized by its partial secretion of vacuolar targeted proteins and a plethora of developmental phenotypes derived from its aberrant auxin responses. In this study, we show that ribosomal biogenesis can be directly regulated by auxins and that the exogenous application of auxins to wild-type plants results in vacuolar trafficking defects similar to those observed in rpl4a mutants. We propose that the influence of auxin on ribosomal biogenesis acts as a regulatory mechanism for auxin-mediated developmental processes, and we demonstrate the involvement of this regulatory mechanism in the sorting of vacuolar targeted proteins in Arabidopsis.     

The KEEP ON GOING Protein of Arabidopsis Regulates Intracellular Protein Trafficking and Is Degraded during Fungal Infection

In plants, the trans-Golgi network and early endosomes (TGN/EE) function as the central junction for major endomembrane trafficking events, including endocytosis and secretion. Here, we demonstrate that the KEEP ON GOING (KEG) protein of Arabidopsis thaliana localizes to the TGN/EE and plays an essential role in multiple intracellular trafficking processes. Loss-of-function keg mutants exhibited severe defects in cell expansion, which correlated with defects in vacuole morphology. Confocal microscopy revealed that KEG is required for targeting of plasma membrane proteins to the vacuole. This targeting process appeared to be blocked at the step of multivesicular body (MVB) fusion with the vacuolar membrane as the MVB-associated small GTPase ARA6 was also blocked in vacuolar delivery. In addition, loss of KEG function blocked secretion of apoplastic defense proteins, indicating that KEG plays a role in plant immunity. Significantly, KEG was degraded specifically in cells infected by the fungus Golovinomyces cichoracearum, suggesting that this pathogen may target KEG to manipulate the host secretory system as a virulence strategy. Taking these results together, we conclude that KEG is a key component of TGN/EE that regulates multiple post-Golgi trafficking events in plants, including vacuole biogenesis, targeting of membrane-associated proteins to the vacuole, and secretion of apoplastic proteins.     

Rabex-5 Protein Regulates the Endocytic Trafficking Pathway of Ubiquitinated Neural Cell Adhesion Molecule L1

Ubiquitination of integral membrane proteins is a common posttranslational modification used to mediate endocytosis and endocytic sorting of cell surface proteins in eukaryotic cells. Ubiquitin (Ub)-binding proteins (UBPs) regulate the stability, function, and localization of ubiquitinated cell surface proteins in the endocytic pathway. Here, I report that the immunoglobulin superfamily cell adhesion molecule L1 undergoes ubiquitination and dephosphorylation on the plasma membrane upon L1 antibody-induced clustering, which mimics L1-L1 homophilic binding, and that these modifications are critical for obtaining the maximal rate of internalization and trafficking to the lysosome, but not to the proteasome. Notably, L1 antibody-induced clustering leads to the association of ubiquitinated L1 with Rabex-5, a UBP and guanine nucleotide exchange factor for Rab5, via interaction with the motif interacting with Ub (MIU) domain, but not the A20-type zinc finger domain. This interaction specifically depends on the presence of an Ub moiety on lysine residues in L1. Rabex-5 expression accelerates the internalization rates of L1^WT and L1^Y1176A, a tyrosine-based motif mutant, but not L1^K11R, an ubiquitination-deficient mutant, leading to the accumulation of ubiquitinated L1 on endosomes. In contrast, RNA interference-mediated knockdown of Rabex-5 impairs the internalizations of L1^WT and L1^Y1176A, but not L1^K11R from the plasma membrane. Overall, these results provide a novel mechanistic insight into how Rabex-5 regulates internalization and postendocytic trafficking of ubiquitinated L1 destined for lysosomal degradation.     

ECHIDNA Protein Impacts on Male Fertility in Arabidopsis by Mediating trans-Golgi Network Secretory Trafficking during Anther and Pollen Development

The trans-Golgi network (TGN) plays a central role in cellular secretion and has been implicated in sorting cargo destined for the plasma membrane. Previously, the Arabidopsis (Arabidopsis thaliana) echidna (ech) mutant was shown to exhibit a dwarf phenotype due to impaired cell expansion. However, ech also has a previously uncharacterized phenotype of reduced male fertility. This semisterility is due to decreased anther size and reduced amounts of pollen but also to decreased pollen viability, impaired anther opening, and pollen tube growth. An ECH translational fusion (ECHPro:ECH-YELLOW FLUORESCENT PROTEIN) revealed developmentally regulated tissue-specific expression, with expression in the tapetum during early anther development and microspore release and subsequent expression in the pollen, pollen tube, and stylar tissues. Pollen viability and production, along with germination and pollen tube growth, were all impaired. The ech anther endothecium secondary wall thickening also appeared reduced and disorganized, resulting in incomplete anther opening. This did not appear to be due to anther secondary thickening regulatory genes but perhaps to altered secretion of wall materials through the TGN as a consequence of the absence of the ECH protein. ECH expression is critical for a variety of aspects of male reproduction, including the production of functional pollen grains, their effective release, germination, and tube formation. These stages of pollen development are fundamentally influenced by TGN trafficking of hormones and wall components. Overall, this suggests that the fertility defect is multifaceted, with the TGN trafficking playing a significant role in the process of both pollen formation and subsequent fertilization.Pollen production and release is a critical stage in plant development that typically involves gene expression from over half of the genome. The extent of genomic involvement in pollen development is illustrated by the high frequency of mutations that result in a failure of male fertility; these can be a consequence of the failure of pollen development or pollen release, dehiscence. Detailed analysis of male-sterile mutants in Arabidopsis (Arabidopsis thaliana) and rice (Oryza sativa) has improved the basic understanding of pollen and anther development (Scott et al., 2004; Ma, 2005; Wilson and Zhang, 2009; Cui et al., 2012); however, there are multiple aspects of pollen formation that are still unclear, and many defects result in uncharacterized effects of reduced fertility or complete sterility.The ECHIDNA (ECH) gene was initially identified from expression profiling of the vascular cambium in poplar (Populus spp.) and associated with secondary xylem formation (Hertzberg et al., 2001). The Arabidopsis ech mutant was shown to have a bushy stature with defects in root and hypocotyl elongation, which was linked to defective cell expansion and elongation (Gendre et al., 2011). Analysis of roots in the ech mutant and complementation analyses in yeast showed that the ECH protein impacts on cell expansion by mediating trans-Golgi network (TGN) secretory trafficking but does not affect endocytosis (Gendre et al., 2011). However, in addition to the defects associated with plant stature, the ech mutant also displays a previously unreported phenotype of reduced fertility.Pollen development occurs in a specialized organ, the stamen, which comprises anthers that hold the developing pollen supported by a filament containing the vasculature connections. Stamen primordia arise from divisions in the L1, L2, and L3 layers in the floral meristem. Divisions in the L2 layer result in four clusters of archesporial cells that subsequently form the central sporogenous cells, which are surrounded by four maternal cell layers: the tapetum, middle cell layer, endothecium, and outer epidermis (Scott et al., 2004). The structure of the maternal anther cell layers has been shown to be critical for the production and release of functional pollen, as demonstrated in a number of male-sterile mutants, which have defects in cell division and early stages of differentiation of the tapetum and sporogenous cells. For example, mutants of the Leu-rich repeat receptor kinase EXTRA SPOROGENOUS CELLS (EXS)/EXCESS MICROSPOROCYTES1 (Canales et al., 2002; Zhao et al., 2002) and its ligand TAPETAL DETERMINANT1 (Jia et al., 2008) result in sterility due to the formation of additional male sporocytes and a lack of tapetal cells.The tapetum has been shown to be critical for functional pollen formation, with many of the characterized male-sterile mutants exhibiting abnormal tapetal development, including DYSFUNCTIONAL TAPETUM1 (DYT1; Zhang et al., 2006; Zhu et al., 2008), TAPETAL DEVELOPMENT AND FUNCTION1 (TDF1; Zhu et al., 2008), ABORTED MICROSPORES (AMS; Sorensen et al., 2003; Xu et al., 2010), and MALE STERILITY1 (MS1; Wilson et al., 2001; Ito and Shinozaki, 2002). After differentiation, the tapetum layer becomes metabolically highly active and plays an essential role in the biosynthesis and secretion of sporopollenin and other wall materials for the developing pollen, prior to breakdown via programmed cell death (Ariizumi and Toriyama, 2011). A frequently observed phenotype in male-sterile mutants is enlarged tapetal cells that show defects in secretion and subsequent alterations in programmed cell death breakdown (Wilson and Zhang, 2009). This indicates the important role that the tapetum plays in the regulation of pollen development and, in particular, the passage of materials to the central locule for viable pollen production.Male-sterile phenotypes have also been identified due to a failure of pollen release, dehiscence. Secondary thickening occurs specifically in the endothecium layer of the anther; this layer and the presence of selective thickening within it are critical to generate the differential forces that are required for anther dehiscence and pollen release (Wilson et al., 2011; Nelson et al., 2012). The importance of this secondary thickening is demonstrated in the myb26 mutant (Yang et al., 2007) and in the double NAC SECONDARY WALL THICKENING PROMOTING FACTOR1 NAC SECONDARY WALL THICKENING PROMOTING FACTOR2 (nst1 nst2) mutant (Mitsuda et al., 2005), which lack endothecium thickening and, as a result, fail to dehisce (Nelson et al., 2012).Previous investigations of the ech mutation indicated that it is impaired in TGN secretion, resulting in dwarf plants with defects in root and hypocotyl cell elongation. The ech mutant also has an uncharacterized phenotype of impaired male fertility; therefore, a detailed analysis of reproduction in the ech mutant was conducted. ECH expression was seen in the anther tapetum during the early stages of tapetal development and microspore release but was subsequently detected in the pollen, pollen tube, and stylar tissues. The reduced fertility was linked to decreased anther size and pollen production but also to reductions in pollen viability, anther opening, and pollen tube growth. The anther wall thickening was reduced and disorganized in ech, possibly as a consequence of altered secretion of wall materials through the TGN. The male-sterile myb26 mutant has defects in anther endothecium wall thickening resulting in a failure of dehiscence; the ech myb26 double mutant exhibits the phenotypes of both mutants and fails to produce secondary thickening, indicating that the ECH-mediated pathway is acting independently of or upstream through MYB26, possibly by providing the components required for secondary cell wall thickening. The reduction in male fertility, therefore, is likely to be a consequence of multiple effects due to altered secretion in the anther because of impaired TGN transport in the ech mutant; the resulting defects are associated with tapetum and pollen wall development but also anther dehiscence and pollen tube formation.     

The Vesicle Trafficking Protein Sar1 Lowers Lipid Membrane Rigidity

The sculpting of membranes into dynamic, curved shapes is central to intracellular cargo trafficking. Though the generation of membrane curvature during trafficking necessarily involves both lipids and membrane-associated proteins, current mechanistic views focus primarily on the formation of rigid cages and curved scaffolds by protein assemblies. Here we report on a different mechanism for the control of membrane deformation, unrelated to the imposition of predefined curvature, involving modulation of membrane material properties: Sar1, a GTPase that regulates vesicle trafficking from the endoplasmic reticulum, lowers the rigidity of the lipid bilayer membrane to which it binds. In vitro assays in which optically trapped microspheres create controlled membrane deformations revealed a monotonic decline in bending modulus as a function of Sar1 concentration, down to nearly zero rigidity, indicating a dramatic lowering of the energetic cost of curvature generation. This is the first demonstration that a vesicle trafficking protein lowers the rigidity of its target membrane, leading to a new conceptual framework for vesicle biogenesis.     

MODIFIED VACUOLE PHENOTYPE1 Is an Arabidopsis Myrosinase-Associated Protein Involved in Endomembrane Protein Trafficking

We identified an Arabidopsis (Arabidopsis thaliana) ethyl methanesulfonate mutant, modified vacuole phenotype1-1 (mvp1-1), in a fluorescent confocal microscopy screen for plants with mislocalization of a green fluorescent protein-δ tonoplast intrinsic protein fusion. The mvp1-1 mutant displayed static perinuclear aggregates of the reporter protein. mvp1 mutants also exhibited a number of vacuole-related phenotypes, as demonstrated by defects in growth, utilization of stored carbon, gravitropic response, salt sensitivity, and specific susceptibility to the fungal necrotroph Alternaria brassicicola. Similarly, crosses with other endomembrane marker fusions identified mislocalization to aggregate structures, indicating a general defect in protein trafficking. Map-based cloning showed that the mvp1-1 mutation altered a gene encoding a putative myrosinase-associated protein, and glutathione S-transferase pull-down assays demonstrated that MVP1 interacted specifically with the Arabidopsis myrosinase protein, THIOGLUCOSIDE GLUCOHYDROLASE2 (TGG2), but not TGG1. Moreover, the mvp1-1 mutant showed increased nitrile production during glucosinolate hydrolysis, suggesting that MVP1 may play a role in modulation of myrosinase activity. We propose that MVP1 is a myrosinase-associated protein that functions, in part, to correctly localize the myrosinase TGG2 and prevent inappropriate glucosinolate hydrolysis that could generate cytotoxic molecules.The plant endomembrane system is a complex network of subcellular compartments that includes the endoplasmic reticulum (ER), Golgi apparatus, vacuole, plasma membrane, secretory vesicles, and numerous intermediary compartments. Protein trafficking through the endomembrane system requires specific cargo recognition and delivery mechanisms that are mediated by a series of highly specific targeting signals (Surpin and Raikhel, 2004), whose proper recognition is critical for the function of numerous downstream processes, such as floral development (Sohn et al., 2007), gravitropism (Kato et al., 2002; Surpin et al., 2003; Yano et al., 2003), abiotic stress tolerance (Zhu et al., 2002), autophagy (Surpin et al., 2003; Bassham., 2007), pathogen defense (Robatzek, 2007), and turgor pressure and growth (De, 2000).The importance of protein trafficking for plant survival was demonstrated by the identification of the essential Arabidopsis (Arabidopsis thaliana) gene VACUOLELESS1 (VCL1; Rojo et al., 2001). VCL1 was identified as a homolog of Saccharomyces cerevisiae VPS16, which is critical for yeast vacuole biogenesis. Knockouts of yeast VPS16 lack discernible vacuoles but survive despite their severe phenotype. The absence of vacuoles in Arabidopsis vcl1-1 mutants results in embryo lethality (Rojo et al., 2001). The essential nature of trafficking in plants was also demonstrated by insertional mutagenesis of syntaxin genes, where lethality was observed after disruption of single genes in families with highly homologous members (Lukowitz et al., 1996; Sanderfoot et al., 2001). Thus, despite large families of endomembrane components with many homologous genes, many are not redundant in Arabidopsis.Although embryo-lethal mutations provide critical data, it is difficult to obtain additional information. Less severe mutations have proven successful for functional genetics studies of endomembrane trafficking proteins. For example, point mutations in the KATAMARI1/MURUS3 (KAM1/MUR3; Tamura et al., 2005) and KATAMARI2/GRAVITROPISM DEFECTIVE2 (KAM2/GRV2; Tamura et al., 2007; Silady et al., 2008) genes lead to disruption of endomembranes, resulting in the formation of perinuclear aggregates containing organelles. Nonlethal trafficking disruptions have also been generated using chemical genomics, where small molecules were used to perturb trafficking of a soluble cargo protein (Zouhar et al., 2004) and localization of endomembrane markers (Surpin et al., 2005; Robert et al., 2008). Such studies have provided valuable clues about these essential cellular processes.In order to obtain less severe, viable mutants with defects in endomembrane protein trafficking, we previously identified point mutants with defects in localization of a tonoplast reporter protein, GFP:δ-TIP (Avila et al., 2003). Two hundred one putative mutants were grouped into four categories based on the nature of their defects. One unique mutant, cell shape phenotype1, was recently characterized as a trehalose-6-phosphate synthase with roles in regulation of plant architecture, epidermal pavement cell shape, and trichome branching (Chary et al., 2008).Here, we describe an endomembrane trafficking mutant categorized by perinuclear aggregates of GFP:δ-TIP fluorescence (Avila et al., 2003). We refer to this mutant as modified vacuole phenotype1-1 (mvp1-1). At least five endomembrane fusion proteins are partially relocalized to these structures. Positional cloning identified MVP1 as a myrosinase-associated protein (MyAP) localized previously to the tonoplast by proteomics (Carter et al., 2004). mvp1-1 mutants showed reduced endomembrane system functionality, as demonstrated by defects in growth, utilization of stored carbon, gravitropic responsiveness, salt sensitivity, and increased susceptibility to a fungal necrotroph. MVP1 interacted specifically with THIOGLUCOSIDE GLUCOHYDROLASE2 (TGG2), a known myrosinase protein in Arabidopsis, and the mvp1-1 mutation had a significant effect on nitrile production during glucosinolate hydrolysis, suggesting a role in myrosinase function. Furthermore, MVP1 may function in quality control of glucosinolate hydrolysis by contributing to the proper tonoplast localization of TGG2.     

Varp Is a Novel Rab32/38-binding Protein That Regulates Tyrp1 Trafficking in Melanocytes

Two small GTPase Rabs, Rab32 and Rab38, have recently been proposed to regulate trafficking of melanogenic enzymes to melanosomes in mammalian epidermal melanocytes; however, the exact molecular mechanism of Rab32/38-mediated transport of melanogenic enzymes has never been clarified, because no Rab32/38-specific effector has ever been identified. In this study, we screened for a Rab32/38-specific effector by a yeast two-hybrid assay using a guanosine triphosphate (GTP)-locked Rab32/38 as bait and found that VPS9-ankyrin-repeat protein (Varp)/Ankrd27, characterized previously as a guanine nucleotide exchange factor (GEF) for Rab21, functions as a specific Rab32/38-binding protein in mouse melanocyte cell line melan-a. Deletion analysis showed that the first ankyrin-repeat (ANKR1) domain functions as a GTP-dependent Rab32/38-binding domain, but that the N-terminal VPS9 domain (i.e., Rab21-GEF domain) does not. Small interfering RNA-mediated knockdown of endogenous Varp in melan-a cells caused a dramatic reduction in Tyrp1 (tyrosinase-related protein 1) signals from melanosomes but did not cause any reduction in Pmel17 signals. Furthermore, expression of the ANKR1 domain in melan-a cells also caused a dramatic reduction of Tyrp1 signals, whereas the VPS9 domain had no effect. Based on these findings, we propose that Varp functions as the Rab32/38 effector that controls trafficking of Tyrp1 in melanocytes.     

A New Dynamin-Like Protein, ADL6, Is Involved in Trafficking from the trans-Golgi Network to the Central Vacuole in Arabidopsis

Dynamin, a high-molecular-weight GTPase, plays a critical role in vesicle formation at the plasma membrane during endocytosis in animal cells. Here we report the identification of a new dynamin homolog in Arabidopsis named Arabidopsis dynamin-like 6 (ADL6). ADL6 is quite similar to dynamin I in its structural organization: a conserved GTPase domain at the N terminus, a pleckstrin homology domain at the center, and a Pro-rich motif at the C terminus. In the cell, a majority of ADL6 is associated with membranes. Immunohistochemistry and in vivo targeting experiments revealed that ADL6 is localized to the Golgi apparatus. Expression of the dominant negative mutant ADL6[K51E] in Arabidopsis protoplasts inhibited trafficking of cargo proteins destined for the lytic vacuole and caused them to accumulate at the trans-Golgi network. In contrast, expression of ADL6[K51E] did not affect trafficking of a cargo protein, H(+)-ATPase:green fluorescent protein, destined for the plasma membrane. These results suggest that ADL6 is involved in vesicle formation for vacuolar trafficking at the trans-Golgi network but not for trafficking to the plasma membrane in plant cells.     

miR-17-5p Regulates Endocytic Trafficking through Targeting TBC1D2/Armus

miRNA cluster miR-17-92 is known as oncomir-1 due to its potent oncogenic function. miR-17-92 is a polycistronic cluster that encodes 6 miRNAs, and can both facilitate and inhibit cell proliferation. Known targets of miRNAs encoded by this cluster are largely regulators of cell cycle progression and apoptosis. Here, we show that miRNAs encoded by this cluster and sharing the seed sequence of miR-17 exert their influence on one of the most essential cellular processes – endocytic trafficking. By mRNA expression analysis we identified that regulation of endocytic trafficking by miR-17 can potentially be achieved by targeting of a number of trafficking regulators. We have thoroughly validated TBC1D2/Armus, a GAP of Rab7 GTPase, as a novel target of miR-17. Our study reveals regulation of endocytic trafficking as a novel function of miR-17, which might act cooperatively with other functions of miR-17 and related miRNAs in health and disease.     

Phospholipase A2 Is Required for PIN-FORMED Protein Trafficking to the Plasma Membrane in the Arabidopsis Root

Phospholipase A₂ (PLA₂), which hydrolyzes a fatty acyl chain of membrane phospholipids, has been implicated in several biological processes in plants. However, its role in intracellular trafficking in plants has yet to be studied. Here, using pharmacological and genetic approaches, the root hair bioassay system, and PIN-FORMED (PIN) auxin efflux transporters as molecular markers, we demonstrate that plant PLA₂s are required for PIN protein trafficking to the plasma membrane (PM) in the Arabidopsis thaliana root. PLA₂α, a PLA₂ isoform, colocalized with the Golgi marker. Impairments of PLA₂ function by PLA₂α mutation, PLA₂-RNA interference (RNAi), or PLA₂ inhibitor treatments significantly disrupted the PM localization of PINs, causing internal PIN compartments to form. Conversely, supplementation with lysophosphatidylethanolamine (the PLA₂ hydrolytic product) restored the PM localization of PINs in the pla₂α mutant and the ONO-RS-082–treated seedling. Suppression of PLA₂ activity by the inhibitor promoted accumulation of trans-Golgi network vesicles. Root hair–specific PIN overexpression (PINox) lines grew very short root hairs, most likely due to reduced auxin levels in root hair cells, but PLA₂ inhibitor treatments, PLA₂α mutation, or PLA₂-RNAi restored the root hair growth of PINox lines by disrupting the PM localization of PINs, thus reducing auxin efflux. These results suggest that PLA₂, likely acting in Golgi-related compartments, modulates the trafficking of PIN proteins.     

拟南芥AtJ3通过核质转运调控植物质膜H~+-ATPase活性与ABA响应

拟南芥AtJ3(Arabidopsis thaliana Dna J homolog 3)为一蛋白分子伴侣,在植物体内可通过与PKS5(SOS2-like protein kinase 5)蛋白激酶形成复合物来抑制PKS5的活性;同时AtJ3-PKS5复合物可对质膜上H~+-ATPase质子转运活性进行正向调节,并参与对外源ABA的响应。为揭示AtJ3-PKS5复合物参与质膜H~+-ATPase活性调节及对外源ABA响应中的作用,本研究以拟南芥AtJ3、PKS5不同突变体为材料,在盐及ABA共同处理下对AtJ3-PKS5复合物的功能及作用机制进行了探讨。结果显示,在2种因素共同处理下,AtJ3-PKS5复合物可同时对处理因素进行响应。即AtJ3-PKS5复合物可对质膜上H~+-ATPase质子转运活性进行调节,并使细胞内p H值发生变化,同时还可诱导ABI5下游ABA响应基因的表达;外源ABA可引起AtJ3从细胞核向细胞质的转运,从而增强了AtJ3对H~+-ATPase活性的调节。说明AtJ3-PKS5复合物在对H~+-ATPase活性调节及对外源ABA响应的交互代谢途径中起着关键调节子的作用。     

The Ca2+ Channel TRPML3 Regulates Membrane Trafficking and Autophagy

TRPML3 is an inward rectifying Ca²⁺ channel that is regulated by extracytosolic H⁺. Although gain-of-function mutation in TRPML3 causes the varitint-waddler phenotype, the role of TRPML3 in cellular physiology is not known. In this study, we report that TRPML3 is a prominent regulator of endocytosis, membrane trafficking and autophagy. Gradient fractionation and confocal localization reveal that TRPML3 is expressed in the plasma membrane and multiple intracellular compartments. However, expression of TRPML3 is dynamic, with accumulation of TRPML3 in the plasma membrane upon inhibition of endocytosis, and recruitment of TRPML3 to autophagosomes upon induction of autophagy. Accordingly, overexpression of TRPML3 leads to reduced constitutive and regulated endocytosis, increased autophagy and marked exacerbation of autophagy evoked by various cell stressors with nearly complete recruitment of TRPML3 into the autophagosomes. Importantly, both knockdown of TRPML3 by siRNA and expression of the channel-dead dominant negative TRPML3(D458K) have a reciprocal effect, reducing endocytosis and autophagy. These findings reveal a prominent role for TRPML3 in regulating endocytosis, membrane trafficking and autophagy, perhaps by controlling the Ca²⁺ in the vicinity of cellular organelles that is necessary to regulate these cellular events.     

Rab17 Regulates Membrane Trafficking through Apical Recycling Endosomes in Polarized Epithelial Cells

A key feature of polarized epithelial cells is the ability to maintain the specific biochemical composition of the apical and basolateral plasma membrane domains while selectively allowing transport of proteins and lipids from one pole to the opposite by transcytosis. The small GTPase, rab17, a member of the rab family of regulators of intracellular transport, is specifically induced during cell polarization in the developing kidney. We here examined its intracellular distribution and function in both nonpolarized and polarized cells. By confocal immunofluorescence microscopy, rab17 colocalized with internalized transferrin in the perinuclear recycling endosome of BHK-21 cells. In polarized Eph4 cells, rab17 associated with the apical recycling endosome that has been implicated in recycling and transcytosis. The localization of rab17, therefore, strengthens the proposed homology between this compartment and the recycling endosome of nonpolarized cells. Basolateral to apical transport of two membrane-bound markers, the transferrin receptor and the FcLR 5-27 chimeric receptor, was specifically increased in Eph4 cells expressing rab17 mutants defective in either GTP binding or hydrolysis. Furthermore, the mutant proteins stimulated apical recycling of FcLR 5-27. These results support a role for rab17 in regulating traffic through the apical recycling endosome, suggesting a function in polarized sorting in epithelial cells.     

Annexin5 Plays a Vital Role in Arabidopsis Pollen Development via Ca2+-Dependent Membrane Trafficking

The regulation of pollen development and pollen tube growth is a complicated biological process that is crucial for sexual reproduction in flowering plants. Annexins are widely distributed from protists to higher eukaryotes and play multiple roles in numerous cellular events by acting as a putative “linker” between Ca²⁺ signaling, the actin cytoskeleton and the membrane, which are required for pollen development and pollen tube growth. Our recent report suggested that downregulation of the function of Arabidopsis annexin 5 (Ann5) in transgenic Ann5-RNAi lines caused severely sterile pollen grains. However, little is known about the underlying mechanisms of the function of Ann5 in pollen. This study demonstrated that Ann5 associates with phospholipid membrane and this association is stimulated by Ca²⁺ in vitro. Brefeldin A (BFA) interferes with endomembrane trafficking and inhibits pollen germination and pollen tube growth. Both pollen germination and pollen tube growth of Ann5-overexpressing plants showed increased resistance to BFA treatment, and this effect was regulated by calcium. Overexpression of Ann5 promoted Ca²⁺-dependent cytoplasmic streaming in pollen tubes in vivo in response to BFA. Lactrunculin (LatB) significantly prohibited pollen germination and tube growth by binding with high affinity to monomeric actin and preferentially targeting dynamic actin filament arrays and preventing actin polymerization. Overexpression of Ann5 did not affect pollen germination or pollen tube growth in response to LatB compared with wild-type, although Ann5 interacts with actin filaments in a manner similar to some animal annexins. In addition, the sterile pollen phenotype could be only partially rescued by Ann5 mutants at Ca²⁺-binding sites when compared to the complete recovery by wild-type Ann5. These data demonstrated that Ann5 is involved in pollen development, germination and pollen tube growth through the promotion of endomembrane trafficking modulated by calcium. Our results provide reliable molecular mechanisms that underlie the function of Ann5 in pollen.