Identification of motifs that are conserved in 12 Drosophila species and regulate midline glia vs. neuron expression

Functional complexity of the central nervous system (CNS) is reflected by the large number and diversity of genes expressed in its many different cell types. Understanding the control of gene expression within cells of the CNS will help reveal how various neurons and glia develop and function. Midline cells of Drosophila differentiate into glial cells and several types of neurons and also serve as a signaling center for surrounding tissues. Here, we examine regulation of the midline gene, wrapper, required for both neuron–glia interactions and viability of midline glia. We identify a region upstream of wrapper required for midline expression that is highly conserved (87%) between 12 Drosophila species. Site-directed mutagenesis identifies four motifs necessary for midline glial expression: (1) a Single-minded/Tango binding site, (2) a motif resembling a pointed binding site, (3) a motif resembling a Sox binding site, and (4) a novel motif. An additional highly conserved 27 bp are required to restrict expression to midline glia and exclude it from midline neurons. These results suggest short, highly conserved genomic sequences flanking Drosophila midline genes are indicative of functional regulatory regions and that small changes within these sequences can alter the expression pattern of a gene.     

Developmental regulation of glial cell phagocytic function during Drosophila embryogenesis

The proper removal of superfluous neurons through apoptosis and subsequent phagocytosis is essential for normal development of the central nervous system (CNS). During Drosophila embryogenesis, a large number of apoptotic neurons are efficiently engulfed and degraded by phagocytic glia. Here we demonstrate that glial proficiency to phagocytose relies on expression of phagocytic receptors for apoptotic cells, SIMU and DRPR. Moreover, we reveal that the phagocytic ability of embryonic glia is established as part of a developmental program responsible for glial cell fate determination and is not triggered by apoptosis per se. Explicitly, we provide evidence for a critical role of the major regulators of glial identity, gcm and repo, in controlling glial phagocytic function through regulation of SIMU and DRPR specific expression. Taken together, our study uncovers molecular mechanisms essential for establishment of embryonic glia as primary phagocytes during CNS development.     

The cytoplasmic region of alpha-1,6-mannosyltransferase Mnn9p is crucial for retrograde transport from the Golgi apparatus to the endoplasmic reticulum in Saccharomyces cerevisiae

In Saccharomyces cerevisiae, Och1p and Mnn9p mannosyltransferases are localized in the cis-Golgi. Attempts to live image Och1p and Mnn9p tagged with green fluorescent protein or red fluorescent protein, respectively, using a high-performance confocal laser scanning microscope system resulted in simultaneous visualization of the native proteins in a living cell. Our observations revealed that Och1p and Mnn9p are not always colocalized to the same cisternae. The difference in the dynamics of these mannosyltransferases may reflect differences in the mechanisms for their retention in the cis-Golgi, since it has been reported that Mnn9p cycles between the endoplasmic reticulum and the cis-Golgi whereas Och1p does not (Z. Todorow, A. Spang, E. Carmack, J. Yates, and R. Schekman, Proc. Natl. Acad. Sci. USA 97:13643-13648, 2000). We investigated the localization of chimeric proteins of Mnn9p and Och1p in sec12 and erd1 mutant cells. A chimeric protein, M16/O16, which consists of the N-terminal cytoplasmic region of Mnn9p and the transmembrane and luminal region of Och1p, behaved like Mnn9p, suggesting that the N-terminal cytoplasmic region is important for the intracellular dynamics of Mnn9p. This observation is supported by results from subcellular-fractionation experiments. Mutational analysis revealed that two arginine residues in the N-terminal region of Mnn9p are important for the chimeric protein to cycle between the endoplasmic reticulum and the Golgi apparatus.     

The Yeast v-SNARE Vti1p Mediates Two Vesicle Transport Pathways through Interactions with the t-SNAREs Sed5p and Pep12p

Membrane traffic in eukaryotic cells requires that specific v-SNAREs on transport vesicles interact with specific t-SNAREs on target membranes. We identified a novel Saccharomyces cerevisiae v-SNARE (Vti1p) encoded by the essential gene, VTI1. Vti1p interacts with the prevacuolar t-SNARE Pep12p to direct Golgi to prevacuolar traffic. vti1-1 mutant cells missorted and secreted the soluble vacuolar hydrolase carboxypeptidase Y (CPY) rapidly and reversibly when vti1-1 cells were shifted to the restrictive temperature. However, overexpression of Pep12p suppressed the CPY secretion defect exhibited by vti1-1 cells at 36°C. Characterization of a second vti1 mutant, vti1-11, revealed that Vti1p also plays a role in membrane traffic at a cis-Golgi stage. vti1-11 mutant cells displayed a growth defect and accumulated the ER and early Golgi forms of both CPY and the secreted protein invertase at the nonpermissive temperature. Overexpression of the yeast cis-Golgi t-SNARE Sed5p suppressed the accumulation of the ER form of CPY but did not lead to CPY transport to the vacuole in vti1-11 cells. Overexpression of Sed5p allowed growth in the absence of Vti1p. In vitro binding and coimmunoprecipitation studies revealed that Vti1p interacts directly with the two t-SNAREs, Sed5p and Pep12p. These data suggest that Vti1p plays a role in cis-Golgi membrane traffic, which is essential for yeast viability, and a nonessential role in the fusion of Golgi-derived vesicles with the prevacuolar compartment. Therefore, a single v-SNARE can interact functionally with two different t-SNAREs in directing membrane traffic in yeast.     

Entry and Exit Mechanisms at the cis-Face of the Golgi Complex

Vesicular transport of protein and lipid cargo from the endoplasmic reticulum (ER) to cis-Golgi compartments depends on coat protein complexes, Rab GTPases, tethering factors, and membrane fusion catalysts. ER-derived vesicles deliver cargo to an ER-Golgi intermediate compartment (ERGIC) that then fuses with and/or matures into cis-Golgi compartments. The forward transport pathway to cis-Golgi compartments is balanced by a retrograde directed pathway that recycles transport machinery back to the ER. How trafficking through the ERGIC and cis-Golgi is coordinated to maintain organelle structure and function is poorly understood and highlights central questions regarding trafficking routes and organization of the early secretory pathway.Newly synthesized secretory proteins and lipids are transported to early Golgi compartments in dissociative carrier vesicles that are formed from the ER (Palade 1975). Through the development of biochemical, genetic and morphological approaches, outlines for the molecular machinery that catalyze this transport step and the membrane structures that comprise the early secretory compartments have been developed (Rothman 1994; Schekman and Orci 1996). Initial images and studies suggested the early secretory pathway consisted of stable compartments with ER-derived carrier vesicles shuttling cargo to pre-Golgi and Golgi compartments. However, live cell and time-lapse imaging revealed highly dynamic structures with both secretory cargo and compartment residents detected in pleiomorphic intermediates (Presley et al. 1997; Scales et al. 1997; Shima et al. 1999; Ben-Tekaya et al. 2005). Several lines of evidence now indicate that active bidirectional transport cycles between the ER, ERGIC, and cis-Golgi compartments are balanced to maintain compartment structure and function (Lee et al. 2004). The coat protein complex II (COPII) produces vesicles for forward transport from the ER whereas the coat protein complex I (COPI) buds vesicles for retrograde transport from cis-Golgi compartments to the ER (Fig. 1). Indeed inhibition of either the forward or retrograde pathways results in a rapid loss of normal ER and Golgi organization (Lippincott-Schwartz et al. 1989; Rambourg et al. 1994; Morin-Ganet et al. 2000; Ward et al. 2001). Yet, under steady-state conditions, the cis-Golgi compartments retain a characteristic composition and structure as secretory cargo passes through. These observations indicate that the structure and function of early secretory compartments are maintained at dynamic equilibrium through coordination of multiple pathways.Open in a separate windowFigure 1.Trafficking in the early secretory pathway. A simplified model depicting bidirectional transport routes between the endoplasmic reticulum (ER), the ER-Golgi intermediate compartment (ERGIC), and cis-Golgi cisternae. COPII vesicles bud from the ER and transport cargo in an anterograde direction for tethering and fusion with the ERGIC. The ERGIC then matures into the cis-Golgi compartment and/or fuses with the cis-Golgi. COPI vesicles bud from the ERGIC and cis-Golgi compartments in a retrograde transport pathway back to the ER to recycle transport machinery.Although much of the molecular machinery required for transport to and from cis-Golgi membranes has been identified, the current challenges are to understand the sequence of molecular events that underlie the observed structural organization. Moreover, the mechanisms that govern entry and exit rates to-from cis-Golgi membranes to maintain organization at dynamic equilibrium are poorly understood. In this perspective the known key machinery required for anterograde transport to, and retrograde exit from, cis-Golgi compartments will be described, and then current models for how compartmental structure is maintained while protein and lipid cargo fluxes through will be examined. This review will survey core machinery and principles from several experimental models although it is becoming clear that different species and different cell types within a species may employ variations on a basic theme depending on cellular function. For example, in many animal cells secretory cargo passes through a well-characterized ER-Golgi intermediate compartment (ERGIC) en route to cis-Golgi cisternae. The ERGIC may be necessary to span the distance between ER export sites and the Golgi stack; however, the relationship of this intermediate compartment to the cis-Golgi remains unclear (Appenzeller-Herzog and Hauri 2006). In other species including yeast, Golgi organization appears less coherent and may be considered more simply as a series of intermediate compartments. Here COPII vesicles are thought to fuse directly with the cis-Golgi or this first intermediate compartment (Fig. 2) (Mogelsvang et al. 2003). Despite these quite varied structural organizations, there is a remarkable level of conservation in molecular machinery. After consideration of this conserved molecular machinery, we will return to organizational issues in transport to and from the cis-Golgi compartment.Open in a separate windowFigure 2.ER/Golgi organization in the yeast P. pastoris. Three-dimensional models reconstructed from electron microscope tomography showing proximity of ER and cis-most cisterna of the Golgi complex. Putative COPII vesicles are detected in a narrow region between the ER and cis-Golgi. For further information, see Mogelsvang et al. (2003). Bar = 100 nm. (Reprinted, with permission, from Mogelsvang et al. 2003 [American Society for Cell Biology].)     

Manganese-induced Trafficking and Turnover of the cis-Golgi Glycoprotein GPP130

Manganese is an essential element that is also neurotoxic at elevated exposure. However, mechanisms regulating Mn homeostasis in mammalian cells are largely unknown. Because increases in cytosolic Mn induce rapid changes in the localization of proteins involved in regulating intracellular Mn concentrations in yeast, we were intrigued to discover that low concentrations of extracellular Mn induced rapid redistribution of the mammalian cis-Golgi glycoprotein Golgi phosphoprotein of 130 kDa (GPP130) to multivesicular bodies. GPP130 was subsequently degraded in lysosomes. The Mn-induced trafficking of GPP130 occurred from the Golgi via a Rab-7–dependent pathway and did not require its transit through the plasma membrane or early endosomes. Although the cytoplasmic domain of GPP130 was dispensable for its ability to respond to Mn, its lumenal stem domain was required and it had to be targeted to the cis-Golgi for the Mn response to occur. Remarkably, the stem domain was sufficient to confer Mn sensitivity to another cis-Golgi protein. Our results identify the stem domain of GPP130 as a novel Mn sensor in the Golgi lumen of mammalian cells.     

The plant-unique cis-element that mediates signaling from multiple endoplasmic reticulum stress sensors

The accumulation of unfolded proteins in the ER lumen induces intracellular signaling mediated by the ER stress sensor protein IRE1. Our recent study identified a new common cis-element of ER stress-responsive genes (such as rice BiP paralogs and WRKY45) that were regulated via an IRE1-dependent pathway. ER stress-responsive cis-elements had been expected to be conserved between plants and mammals. However, contrary to expectations, sequences of the plant cis-element, pUPRE-II, were not identical to those of its mammalian counterpart. Additionally, pUPRE-II also interacted with another ER stress sensor protein and mediated multiple signaling pathways. Here, we provide a summary of the results that suggest the complicated mechanism underlying the regulation of ER stress-responsive gene expression in plants.     

Identification of Potential Regulatory Elements for the Transport of Emp24p

To examine the possibility of active recycling of Emp24p between the endoplasmic reticulum (ER) and the Golgi, we sought to identify transport signal(s) in the carboxyl-terminal region of Emp24p. Reporter molecules were constructed by replacing parts of a control invertase-Wbp1p chimera with those of Emp24p, and their transport rates were assessed. The transport of the reporter was found to be accelerated by the presence of the cytoplasmic domain of Emp24p. Mutational analyses revealed that the two carboxyl-terminal residues, leucine and valine (LV), were necessary and sufficient to accelerate the transport. The acceleration was sequence specific, and the terminal valine appeared to be more important. The LV residues accelerated not only the overall transport to the vacuole but also the ER to cis-Golgi transport, suggesting its function in the ER export. Hence the LV residues are a novel anterograde transport signal. The double-phenylalanine residues did not affect the transport by itself but attenuated the effect of the anterograde transport signal. On the other hand, the transmembrane domain significantly slowed down the ER to cis-Golgi transport and effectively counteracted the anterograde transport signal at this step. It may also take part in the retrieval of the protein, because the overall transport to the vacuole was more evidently slowed down. Consistently, the mutation of a conserved glutamine residue in the transmembrane domain further slowed down the transport in a step after arriving at the cis-Golgi. Taken together, the existence of the anterograde transport signal and the elements that regulate its function support the active recycling of Emp24p.     

Cation diffusion facilitator Cis4 is implicated in Golgi membrane trafficking via regulating zinc homeostasis in fission yeast

We screened for mutations that confer sensitivities to the calcineurin inhibitor FK506 and to a high concentration of MgCl₂ and isolated the cis4-1 mutant, an allele of the gene encoding a cation diffusion facilitator (CDF) protein that is structurally related to zinc transporters. Consistently, the addition of extracellular Zn²⁺ suppressed the phenotypes of the cis4 mutant cells. The cis4 mutants and the mutant cells of another CDF-encoding gene SPBC16E9.14c (we named zrg17⁺) shared common and nonadditive zinc-suppressible phenotypes, and Cis4 and Zrg17 physically interacted. Cis4 localized at the cis-Golgi, suggesting that Cis4 is responsible for Zn²⁺ uptake to the cis-Golgi. The cis4 mutant cells showed phenotypes such as weak cell wall and decreased acid phosphatase secretion that are thought to be resulting from impaired membrane trafficking. In addition, the cis4 deletion cells showed synthetic growth defects with all the four membrane-trafficking mutants tested, namely ypt3-i5, ryh1-i6, gdi1-i11, and apm1-1. Interestingly, the addition of extracellular Zn²⁺ significantly suppressed the phenotypes of the ypt3-i5 and apm1-1 mutant cells. These results suggest that Cis4 forms a heteromeric functional complex with Zrg17 and that Cis4 is implicated in Golgi membrane trafficking through the regulation of zinc homeostasis in fission yeast.     

YIPF5 and YIF1A recycle between the ER and the Golgi apparatus and are involved in the maintenance of the Golgi structure

Yip1p/Yif1p family proteins are five-span transmembrane proteins localized in the Golgi apparatus and the ER. There are nine family members in humans, and YIPF5 and YIF1A are the human orthologs of budding yeast Yip1p and Yif1p, respectively. We raised antisera against YIPF5 and YIF1A and examined the localization of endogenous proteins in HeLa cells. Immunofluorescence, immunoelectron microscopy and subcellular fractionation analysis suggested that YIPF5 and YIF1A are not restricted to ER exit sites but also localized in the ER-Golgi intermediate compartment (ERGIC) and some in the cis-Golgi at steady state. Along with ERGIC53, YIPF5 and YIF1A remained in the cytoplasmic punctate structures after brefeldin A treatment, accumulated in the ERGIC and the cis-Golgi after treatment with AlF₄^- and accumulated in the ER when ER to Golgi transport was inhibited by Sar1(H79G). These results supported the localization of YIPF5 and YIF1A in the ERGIC and the cis-Golgi, and strongly suggested that they are recycling between the ER and the Golgi apparatus. Analysis by blue native PAGE and co-immunoprecipitation showed that YIPF5 and YIF1A form stable complexes of three different sizes. Interestingly, the knockdown of YIPF5 or YIF1A caused partial disassembly of the Golgi apparatus suggesting that YIPF5 and YIF1A are involved in the maintenance of the Golgi structure.     

The β-alanyl-monoamine synthase ebony is regulated by schizophrenia susceptibility gene dysbindin in Drosophila

The Drosophila homolog of schizophrenia susceptibility gene dysbindin(Ddysb)affects a range of behaviors through regulation of multiple neurotransmitter signals,including dopamine activity.To gain insights into mechanisms underlying Ddysb-dependent regulation of dopamine signal,we investigated interaction between Ddysb and Ebony,the Drosophilaβ-alanyl-monoamine synthase involved in dopamine recycling.We found that Ddysb was capable of regulating expression of Ebony in a bi-directional manner and its subcellular distribution.Such regulation is confined to glial cells.The expression level of ebony and its accumulation in glial soma depend positively on Ddysb activity,whereas its distribution in glial processes is bound to be reduced in response to any alterations of Ddysb from the normal control level,either an increase or decrease.An optimal binding ratio between Dysb and Ebony might contribute to such non-linear effects.Thus,Ddysb-dependent regulation of Ebony could be one of the mechanisms that mediate dopamine signal.     

Glial Hedgehog signalling and lipid metabolism regulate neural stem cell proliferation in Drosophila

The final size and function of the adult central nervous system (CNS) are determined by neuronal lineages generated by neural stem cells (NSCs) in the developing brain. In Drosophila, NSCs called neuroblasts (NBs) reside within a specialised microenvironment called the glial niche. Here, we explore non‐autonomous glial regulation of NB proliferation. We show that lipid droplets (LDs) which reside within the glial niche are closely associated with the signalling molecule Hedgehog (Hh). Under physiological conditions, cortex glial Hh is autonomously required to sustain niche chamber formation. Upon FGF‐mediated cortex glial overgrowth, glial Hh non‐autonomously activates Hh signalling in the NBs, which in turn disrupts NB cell cycle progression and its ability to produce neurons. Glial Hh’s ability to signal to NB is further modulated by lipid storage regulator lipid storage droplet‐2 (Lsd‐2) and de novo lipogenesis gene fatty acid synthase 1 (Fasn1). Together, our data suggest that glial‐derived Hh modified by lipid metabolism mechanisms can affect the neighbouring NB’s ability to proliferate and produce neurons.     

DYF-4 regulates patched-related/DAF-6-mediated sensory compartment formation in C. elegans

Coordination of neurite extension with surrounding glia development is critical for neuronal function, but the underlying molecular mechanisms remain poorly understood. Through a genome-wide mutagenesis screen in C. elegans, we identified dyf-4 and daf-6 as two mutants sharing similar defects in dendrite extension. DAF-6 encodes a glia-specific patched-related membrane protein that plays vital roles in glial morphogenesis. We cloned dyf-4 and found that DYF-4 encodes a glia-secreted protein. Further investigations revealed that DYF-4 interacts with DAF-6 and functions in a same pathway as DAF-6 to regulate sensory compartment formation. Furthermore, we demonstrated that reported glial suppressors of daf-6 could also restore dendrite elongation and ciliogenesis in both dyf-4 and daf-6 mutants. Collectively, our data reveal that DYF-4 is a regulator for DAF-6 which promotes the proper formation of the glial channel and indirectly affects neurite extension and ciliogenesis.