Similar subunit interactions contribute to assembly of clathrin adaptor complexes and COPI complex: analysis using yeast three-hybrid system.

Clathrin adaptor protein (AP) complexes are heterotetramers composed of two large, one medium, and one small subunits. By exploiting the yeast three-hybrid system, we have found that an interaction between the two large subunits of the AP-1 complex, gamma-adaptin and beta1-adaptin, is markedly enhanced in the presence of the small subunit, sigma1. Similarly, two large subunits of the AP-4 complex, epsilon-adaptin and beta4-adaptin, are found to interact with each other only in the presence of the small subunit, sigma4. Furthermore, we have found that an interaction between two large subunits of the COPI F subcomplex, gamma-COP and beta-COP, is detectable only in the presence of zeta-COP. Because these COPI subunits have common ancestral origins to the corresponding AP subunits, these three-hybrid data, taken together with the previous two-hybrid data, suggest that the AP complexes and the COPI F subcomplex assemble by virtue of similar subunit interactions.     

COP I domains required for coatomer integrity, and novel interactions with ARF and ARF-GAP

We performed a systematic mapping of interaction domains on COP I subunits to gain novel insights into the architecture of coatomer. Using the two-hybrid system, we characterize the domain structure of the alpha-, beta'-, epsilon-COP and beta-, gamma-, delta-, zeta-COP coatomer subcomplexes and identify links between them that contribute to coatomer integrity. Our results demonstrate that the domain organization of the beta-, gamma-, delta-, zeta-COP subcomplex and AP adaptor complexes is related. Through in vivo analysis of alpha-COP truncation mutants, we characterize distinct functional domains on alpha-COP. Its N-terminal WD40 domain is dispensable for yeast cell viability and overall coatomer function, but is required for KKXX-dependent trafficking. The last approximately 170 amino acids of alpha-COP are also non-essential for cell viability, but required for epsilon-COP incorporation into coatomer and maintainance of normal epsilon-COP levels. Further, we demonstrate novel direct interactions of coatomer subunits with regulatory proteins: beta'- and gamma-COP interact with the ARF-GTP-activating protein (GAP) Glo3p, but not Gcs1p, and beta- and epsilon-COP interact with ARF-GTP. Glo3p also interacts with intact coatomer in vitro.     

Solution Structure of Human ζ-COP: Direct Evidences for Structural Similarity between COP I and Clathrin-Adaptor Coats

COP-I-coated vesicles are protein and lipid carriers that mediate intra-Golgi transport and transport from the cis-Golgi complex to the endoplasmic reticulum in cells. The coatomer of the vesicles coat is comprised of seven subunits: α-COP, ?-COP, β′-COP, β-COP, γ-COP, δ-COP, and ζ-COP. Here we report the solution structure of a truncated form (residues 1-149; ζ-COP149) of human ζ-COP (total 177 residues). It is the first three-dimensional structure of a “core” subunit of the COP I F-subcomplex. The structure of ζ-COP149 mainly consists of a disordered N-terminal tail, a five-stranded antiparallel β-sheet, a two-stranded antiparallel β-sheet, and five α-helices. The global folding of ζ-COP149 is very similar to the crystal structures of AP1-σ1 and AP2-σ2, directly demonstrating the structural similarity between the “core” subunits of the COP I F-subcomplex and adaptor protein complexes. Through structural comparison and mutagenesis study, we have also demonstrated that the heterodimers of ζ-COP149 and γ-COP have packing interfaces and relative subunit orientations similar to those of AP2-σ2 and AP2-α heterodimers. These results provide direct evidence supporting the previous proposal that the COP I F-subcomplex and adaptor protein complexes have similar tertiary and quaternary structures.     

Novel isotypic gamma/zeta subunits reveal three coatomer complexes in mammals

In early secretory transport, coat recruitment for the formation of coat protein I (COPI) vesicles involves binding to donor Golgi membranes of the small GTPase ADP-ribosylation factor 1 and subsequent attachment of the cytoplasmic heptameric complex coatomer. Various hypotheses exist as to the precise role of and possible routes taken by COPI vesicles in the mammalian cell. Here we report the ubiquitous expression of two novel isotypes of coatomer subunits gamma- and zeta-COP that are incorporated into coatomer, and show that three isotypes exist of the complex defined by the subunit combinations gamma 1/zeta 1, gamma 1/zeta 2, and gamma 2/zeta 1. In a liver cytosol, these forms make up the total coatomer in a ratio of about 2:1:2, respectively. The coatomer isotypes are located differentially within the early secretory pathway, and the gamma 2/zeta 1 isotype is preferentially incorporated into COPI vesicles. A population of COPI vesicles was characterized that almost exclusively contains gamma 2/zeta 1 coatomer. This existence of three structurally different forms of coatomer will need to be considered in future models of COPI-mediated transport.     

Multiple and stepwise interactions between coatomer and ADP-ribosylation factor-1 (Arf1)-GTP

The small GTPase ADP-ribosylation factor-1 (Arf1) plays a key role in the formation of coat protein I (COP I)-coated vesicles. Upon recruitment to the donor Golgi membrane by interaction with dimeric p24 proteins, Arf1's GDP is exchanged for GTP. Arf1-GTP then dissociates from p24, and together with other Golgi membrane proteins, it recruits coatomer, the heptameric coat protein complex of COP I vesicles, from the cytosol. In this process, Arf1 was shown to specifically interact with the coatomer beta and gamma-COP subunits through its switch I region, and with epsilon-COP. Here, we mapped the interaction of the Arf1-GTP switch I region to the trunk domains of beta and gamma-COP. Site-directed photolabeling at position 167 in the C-terminal helix of Arf1 revealed a novel interaction with coatomer via a putative longin domain of delta-COP. Thus, coatomer is linked to the Golgi through multiple interfaces with membrane-bound Arf1-GTP. These interactions are located within the core, adaptor-like domain of coatomer, indicating an organizational similarity between the COP I coat and clathrin adaptor complexes.     

Identification and localization of a beta-COP-like protein involved in the morphodynamics of the plant Golgi apparatus

This paper examines the molecular machinery involved in membrane exchange within the plant endomembrane system. A study has been undertaken on beta-COP-like proteins in plant cells using M3A5, an antibody raised against the conserved sequence of mammalian beta-COP proteins. In mammalian cells, beta-COP proteins are part of a complex named the coatomer, which probably recruits some specific areas of the endomembrane system. Immunofluorescence analyses by confocal laser scanning microscopy showed that beta-COP-like proteins marked predominantly the plant Golgi apparatus. Other proteins known to be part of a potential machinery for COPI vesicle formation (gamma-COP, beta'-COP and Arf1 proteins) were immunolocalized on the same membraneous structures as beta-COP. Moreover, beta-COP and other COPI antibodies stained the cell plate in dividing cells. It is further shown that, in maize root cells, and in contrast to observations upon mammalian cells, the drug Brefeldin A (BFA) does not induce the release of beta-COP and Arf1 proteins from the Golgi membrane into the cytosol. These data clearly demonstrate that the antibody M3A5 is a valuable marker for studies on trafficking events in plant cells. They also report for the first time the location of COP components in plant tissue at the light level, especially on a model well known for secretion, i.e. the maize root cells. They also suggest that the membrane recruitment machinery may function in a plant-specific way.     

zeta-COP, a subunit of coatomer, is required for COP-coated vesicle assembly

cDNA encoding the 20-kD subunit of coatomer, zeta-COP, predicts a protein of 177-amino acid residues, similar in sequence to AP17 and AP19, subunits of the clathrin adaptor complexes. Polyclonal antibody directed to zeta-COP blocks the binding of coatomer to Golgi membranes and prevents the assembly of COP-coated vesicles on Golgi cisternae. Unlike other coatomer subunits (beta-, beta'-, gamma-, and epsilon- COP), zeta-COP exists in both coatomer bound and free pools.     

GTP-dependent binding of ADP-ribosylation factor to coatomer in close proximity to the binding site for dilysine retrieval motifs and p23.

A site-directed photocross-linking approach was employed to determine components that act downstream of ADP-ribosylation factor (ARF). To this end, a photolabile phenylalanine analog was incorporated at various positions of the putative effector region of the ARF molecule. Depending on the position of incorporation, we find specific and GTP-dependent interactions of ARF with two subunits of the coatomer complex, beta-COP and gamma-COP, as well as an interaction with a cytosolic protein (approximately 185 kDa). In addition, we observe homodimer formation of ARF molecules at the Golgi membrane. These data suggest that the binding site of ARF to coatomer is at the interface of its beta- and gamma-subunits, and this is in close proximity to the second site of interaction of coatomer with the Golgi membrane, the binding site within gamma-COP for cytosolic dibasic/diphenylalanine motifs.     

Gamma-COP appendage domain - structure and function

COPI-coated vesicles mediate retrograde transport from the Golgi back to the ER and intra-Golgi transport. The cytosolic precursor of the COPI coat, the heptameric coatomer complex, can be thought of as composed of two subcomplexes. The first consists of the β-, γ-, δ- and ζ-COP subunits which are distantly homologous to AP clathrin adaptor subunits. The second consists of the α-, β'- and ε-COP subunits. Here, we present the structure of the appendage domain of γ-COP and show that it has a similar overall fold as the α-appendage of AP2. Again, like the α-appendage the γ-COP appendage possesses a single protein/protein interaction site on its platform subdomain. We show that in yeast this site binds to the ARFGAP Glo3p, and in mammalian γ-COP this site binds to a Glo3p orthologue, ARFGAP2. On the basis of mutations in the yeast homologue of γ-COP, Sec21p, a second binding site is proposed to exist on the γ-COP appendage that interacts with the α,β',ε COPI subcomplex.     

Ubiquitylation of ε-COP by PIRH2 and regulation of the secretion of PSA

Ubiquitylation appears to be involved in the membrane trafficking system including endocytosis, exocytosis, and ER-to-Golgi transport. We found that PIRH2, which was identified as an interacting protein for androgen receptor or p53, interacts with and ubiquitylates the ε-subunit of coatmer complex, ε-COP. PIRH2 promotes the ubiquitylation of ε-COP in vitro and in vivo and consequently promotes the degradation of ε-COP. The interaction between PIRH2 and ε-COP is affected by the presence of androgen, and PIRH2 in the presence of androgen promotes ubiquitylation of ε-COP in vivo. Furthermore, overexpression of the wild type of PIRH2 in prostate cancer cells causes downregulation of the secretion of prostate-specific antigen (PSA), a secretory protein in prostate epithelial cells and one of diagnostic markers for prostate cancer. Our results indicate that PIRH2 functions as a regulator for COP I complex.     

1H, 13C, and 15N resonance assignments of human ζ-COP

The ζ-COP is one subunit of the COP I coatomer, which mediates the protein trafficking from the cis-Golgi complex to the endoplasmic reticulum and also functions in the intra-Golgi trafficking. The NMR assignments of the ζ-COP are essential for its solution structure determination.     

A conformational change in the alpha-subunit of coatomer induced by ligand binding to gamma-COP revealed by single-pair FRET

Formation of transport vesicles involves polymerization of cytoplasmic coat proteins (COP). In COPI vesicle biogenesis, the heptameric complex coatomer is recruited to donor membranes by the interaction of multiple coatomer subunits with the budding machinery. Specific binding to the trunk domain of γ-COP by the Golgi membrane protein p23 induces a conformational change that causes polymerization of the complex. Using single-pair fluorescence resonance energy transfer, we find that this conformational change takes place in individual coatomer complexes, independent of each other, and that the conformational rearrangement induced in γ-COP is transmitted within the complex to its α-subunit. We suggest that capture of membrane protein machinery triggers cage formation in the COPI system.     

Silkworm coatomers and their role in tube expansion of posterior silkgland

Background

Coat protein complex I (COPI) vesicles, coated by seven coatomer subunits, are mainly responsible for Golgi-to-ER transport. Silkworm posterior silkgland (PSG), a highly differentiated secretory tissue, secretes fibroin for silk production, but many physiological processes in the PSG cells await further investigation.

Methodology/Principal Findings

Here, to investigate the role of silkworm COPI, we cloned six silkworm COPI subunits (α,β,β′, δ, ε, and ζ-COP), determined their peak expression in day 2 in fifth-instar PSG, and visualized the localization of COPI, as a coat complex, with cis-Golgi. By dsRNA injection into silkworm larvae, we suppressed the expression of α-, β′- and γ-COP, and demonstrated that COPI subunits were required for PSG tube expansion. Knockdown of α-COP disrupted the integrity of Golgi apparatus and led to a narrower glandular lumen of the PSG, suggesting that silkworm COPI is essential for PSG tube expansion.

Conclusions/Significance

The initial characterization reveals the essential roles of silkworm COPI in PSG. Although silkworm COPI resembles the previously characterized coatomers in other organisms, some surprising findings require further investigation. Therefore, our results suggest the silkworm as a model for studying intracellular transport, and would facilitate the establishment of silkworm PSG as an efficient bioreactor.     

Phylogenetic Relationships of the Seven Coat Protein Subunits of the Coatomer Complex, and Comparative Sequence Analysis of Murine Xenin and Proxenin

The coatomer complex is involved in intracellular protein transport and comprises an assembly of seven polypeptide subunits designated , , , , , , and COP. Rooted phylogenetic trees constructed from the full-length cDNA and amino acid sequences of 49 COP entities in different eukaryotes from yeast to man generally revealed striking conservation of each subunit through evolution. Both nucleotide and protein trees displayed close relationships between and subunits, between and subunits, and between and subunits, implying evolution from common ancestors as well as functional similarity. Interestingly, although 6 out of 7 -COP genes appeared to be grouped and related to the -COP genes, 4 out of 7 -COP gene products clustered with other groups of other COP subunit proteins. A 5 coding segment of the murine -COP gene was amplified by RT-PCR and cycle-sequenced. The partial predicted amino acid sequence of this murine homolog was exactly identical to the human and bovine counterparts. Of particular significance was the complete identity of the first 25 and 35 N-terminal residues which constitute the gastrointestinal hormone xenin and its precursor proxenin, thus emphasizing their strict evolutionary conservation and alluding to their physiological importance.     

Gamma-COP, a coat subunit of non-clathrin-coated vesicles with homology to Sec21p.

Constitutive secretory transport in eukaryotes is likely to be mediated by non-clathrin-coated vesicles, which have been isolated and characterized [(1989) Cell 58, 329-336; (1991) Nature 349, 215-220]. They contain a set of coat proteins (COPs) which are also likely to exist in a preformed cytosolic complex named coatomer [(1991) Nature 349, 248-250]. From peptide sequence and cDNA structure comparisons evidence is presented that one of the subunits of coatomer, gamma-COP, is a true constituent of non-clathrin-coated vesicles, and that gamma-COP is related to sec 21, a secretory mutant of the yeast Saccharomyces cervisiae.     

The high affinity Fc epsilon receptor gamma subunit (Fc epsilon RI gamma) facilitates T cell receptor expression and antigen/major histocompatibility complex-driven signaling in the absence of CD3 zeta and CD3 eta.

The T cell receptor (TCR) is a molecular complex formed by at least seven transmembrane proteins: the antigen/major histocompatibility complex recognition unit (Ti alpha-beta heterodimer) and the invariant CD3 chains (gamma, delta, epsilon, zeta, and eta). In addition to targeting partially assembled Ti alpha-beta CD3 gamma delta epsilon TCR complexes to the cell surface, CD3 zeta appears to be essential for interleukin-2 production after TCR stimulation with antigen/major histocompatibility complex. The gamma chain of the high affinity Fc receptor for IgE (Fc epsilon RI gamma) has significant structural homology to CD3 zeta and the related CD3 eta subunit. To identify the functional significance of sequence homologies between CD3 zeta and Fc epsilon RI gamma in T cells, we have transfected a Fc epsilon RI gamma cDNA into a T cell hybridoma lacking CD3 zeta and CD3 eta proteins. Herein we show that a Fc epsilon RI gamma-gamma homodimer associates with TCR components to up-regulate TCR surface expression. A TCR composed of Ti alpha-beta CD3 gamma delta epsilon Fc epsilon RI gamma-gamma is sufficient to restore the coupling of TCR antigen recognition to the interleukin-2 induction pathway, demonstrating the functional significance of structural homology between the above receptor subunits. These results, in conjunction with the recent finding that CD3 zeta, CD3 eta, and Fc epsilon RI gamma are coexpressed in certain T cells as subunits of an unusual TCR isoform, suggest that Fc epsilon RI gamma is likely to play a role in T cell lineage function.     

A structure-based mechanism for Arf1-dependent recruitment of coatomer to membranes

Budding of COPI-coated vesicles from Golgi membranes requires an Arf family G protein and the coatomer complex recruited from cytosol. Arf is also required with coatomer-related clathrin adaptor complexes to bud vesicles from the trans-Golgi network and endosomal compartments. To understand the structural basis for Arf-dependent recruitment of a vesicular coat to the membrane, we determined the structure of Arf1 bound to the γζ-COP subcomplex of coatomer. Structure-guided biochemical analysis reveals that a second Arf1-GTP molecule binds to βδ-COP at a site common to the γ- and β-COP subunits. The Arf1-binding sites on coatomer are spatially related to PtdIns4,5P(2)-binding sites on the endocytic AP2 complex, providing evidence that the orientation of membrane binding is general for this class of vesicular coat proteins. A bivalent GTP-dependent binding mode has implications for the dynamics of coatomer interaction with the Golgi and for the selection of cargo molecules.     

The role of the specificity-determining loop of the integrin beta subunit I-like domain in autonomous expression, association with the alpha subunit, and ligand binding

Integrin beta subunits contain a highly conserved I-like domain that is known to be important for ligand binding. Unlike integrin I domains, the I-like domain requires integrin alpha and beta subunit association for optimal folding. Pactolus is a novel gene product that is highly homologous to integrin beta subunits but lacks associating alpha subunits [Chen, Y., Garrison, S., Weis, J. J., and Weis, J. H. (1998) J. Biol. Chem. 273, 8711-8718] and a approximately 30 amino acid segment corresponding to the specificity-determining loop (SDL) in the I-like domain. We find that the SDL is responsible for the defects in integrin beta subunit expression and folding in the absence of alpha subunits. When transfected in the absence of alpha subunits into cells, extracellular domains of mutant beta subunits lacking SDL, but not wild-type beta subunits, were well secreted and contained immunoreactive I-like domains. The purified recombinant soluble beta1 subunit with the SDL deletion showed an elongated shape in electron microscopy, consistent with its structure in alphabeta complexes. The SDL segment is not required for formation of alpha5beta1, alpha4beta1, alphaVbeta3, and alpha6beta4 heterodimers, but is essential for fomation of alpha6beta1, alphaVbeta1, and alphaLbeta2 heterodimers, suggesting that usage of subunit interface residues is variable among integrins. The beta1 SDL is required for ligand binding and for the formation of the epitope for the alpha5 monoclonal antibody 16 that maps to loop segments connecting blades 2 and 3 of beta-propeller domain of alpha5, but is not essential for nearby beta-propeller epitopes.