Sean Munro

An hsp70-like protein in the ER: Identity with the 78 kd glucose-regulated protein and immunoglobulin heavy chain binding protein

We have characterized a cDNA clone that encodes a protein related to the 70 kd heat shock protein, but is expressed in normal rat liver. This protein has a hydrophobic leader and is secreted into the endoplasmic reticulum. We show that it is identical with two previously described proteins: GRP78, whose synthesis is induced by glucose starvation, and BiP, which is found bound to immunoglobulin heavy chains in pre-B cells. This protein, which is abundant in antibody-secreting cells, can be released from heavy chains by ATP, a reaction analogous to the release of hsp70 from heat shocked nuclear structures. We propose a specific role for this protein in the assembly of secreted and membrane-bound proteins.

Organelle identity and the signposts for membrane traffic

Eukaryotic cells have systems of internal organelles to synthesize lipids and membrane proteins, to release secreted proteins, to take up nutrients and to degrade membrane-bound and internalized molecules. Proteins and lipids move from organelle to organelle using transport vesicles. The accuracy of this traffic depends upon organelles being correctly recognized. In general, organelles are identified by the activated GTPases and specific lipid species that they display. These short-lived determinants provide organelles with an identity that is both unique and flexible. Recent studies have helped to establish how cells maintain and restrict these determinants and explain how this system is exploited by invading pathogens.

Targeting of Golgi-Specific Pleckstrin Homology Domains Involves Both PtdIns 4-Kinase-Dependent and -Independent Components

BACKGROUND Phosphoinositides are required for the recruitment of many proteins to both the plasma membrane and the endosome; however, their role in protein targeting to other organelles is less clear. The pleckstrin homology (PH) domains of oxysterol binding protein (OSBP) and its relatives have been shown to bind to the Golgi apparatus in yeast and mammalian cells. Previous in vitro binding studies identified phosphatidylinositol (PtdIns) (4)P and PtdIns(4,5)P(2) as candidate ligands, but it is not known which is recognized in vivo and whether phosphoinositide specificity can account for Golgi-specific targeting. RESULTS We have examined the distribution of GFP fusions to the PH domain of OSBP and to related PH domains in yeast strains carrying mutations in individual phosphoinositide kinases. We find that Golgi targeting requires the activity of the PtdIns 4-kinase Pik1p but not phosphorylation of PtdIns at the 3 or 5 positions and that a PH domain specific for PtdIns(4,5)P(2) is targeted exclusively to the plasma membrane. However, a mutant version of the OSBP PH domain that does not bind phosphoinositides in vitro still shows some targeting in vivo. This targeting is independent of Pik1p but dependent on the Golgi GTPase Arf1p. CONCLUSIONS Phosphorylation of PtdIns at the 4 position but not conversion to PtdIns(4,5)P(2) contributes to recruitment of PH domains to the Golgi apparatus. However, potential phosphoinositide ligands for these PH domains are not restricted to the Golgi, and the OSBP PH domain also recognizes a second determinant that is ARF dependent, indicating that organelle specificity reflects a combinatorial interaction.

A Comprehensive Comparison of Transmembrane Domains Reveals Organelle-Specific Properties

Summary The various membranes of eukaryotic cells differ in composition, but it is at present unclear if this results in differences in physical properties. The sequences of transmembrane domains (TMDs) of integral membrane proteins should reflect the physical properties of the bilayers in which they reside. We used large datasets from both fungi and vertebrates to perform a comprehensive comparison of the TMDs of proteins from different organelles. We find that TMDs are not generic but have organelle-specific properties with a dichotomy in TMD length between the early and late parts of the secretory pathway. In addition, TMDs from post-ER organelles show striking asymmetries in amino acid compositions across the bilayer that is linked to residue size and varies between organelles. The pervasive presence of organelle-specific features among the TMDs of a particular organelle has implications for TMD prediction, regulation of protein activity by location, and sorting of proteins and lipids in the secretory pathway.

The PACT domain, a conserved centrosomal targeting motif in the coiled-coil proteins AKAP450 and pericentrin

AKAP450 (also known as AKAP350, CG‐NAP or Hyperion) and pericentrin are large coiled‐coil proteins found in mammalian centrosomes that serve to recruit structural and regulatory components including dynein and protein kinase A. We find that these proteins share a well conserved 90 amino acid domain near their C‐termini that is also found in coiled‐coil proteins of unknown function from Drosophila and fission yeast. Fusion of the C‐terminal region from either protein to a reporter protein confers a centrosomal localization, and overexpression of the domain from AKAP450 displaces endogenous pericentrin, suggesting recruitment to a shared site. When isolated from transfected cells the C‐terminal domain of AKAP450 was associated with calmodulin, suggesting that this protein could contribute to centrosome assembly.

Localization of proteins to the Golgi apparatus

For the Golgi apparatus to perform its various unique roles it must maintain a population of resident proteins. These residents include the enzymes that modify the proteins and lipids passing through the Golgi, as well as the proteins involved in vesicle formation and protein sorting. For several of these residents, it has been possible to identify regions that are crucial for specifying a Golgi localization. Consideration of how these targeting domains could function has provided insights into the organization of the Golgi and its protein and lipid content.

The Sec34/35 Golgi transport complex is related to the exocyst, defining a family of complexes involved in multiple steps of membrane traffic.

The specificity of intracellular vesicle transport is mediated in part by tethering factors that attach the vesicle to the destination organelle prior to fusion. We have identified a protein, Dor1p, that is involved in vesicle targeting to the yeast Golgi apparatus and found it to be associated with seven further proteins. Identification of these revealed that they include Sec34p and Sec35p, the two known components of the Sec34/35 complex previously proposed to tether vesicles to the Golgi. Of the six previously uncharacterized components, four have homologs in higher eukaryotes, including a subunit of a mammalian Golgi transport complex. Furthermore, several of the proteins show distant homology to components of two other putative tethering complexes, the exocyst and the Vps52/53/54 complex, revealing that tethering factors involved in different membrane traffic steps are structurally related.

A Common Motif of Eukaryotic Glycosyltransferases Is Essential for the Enzyme Activity of Large Clostridial Cytotoxins

A fragment of the N-terminal 546 amino acid residues of Clostridium sordellii lethal toxin possesses full enzyme activity and glucosylates Rho and Ras GTPases in vitro. Here we identified several amino acid residues in C. sordellii lethal toxin that are essential for the enzyme activity of the active toxin fragment. Exchange of aspartic acid at position 286 or 288 with alanine or asparagine decreased glucosyltransferase activity by about 5000-fold and completely blocked glucohydrolase activity. No enzyme activity was detected with the double mutant D286A/D288A. Whereas the wild-type fragment of C. sordelliilethal toxin was labeled by azido-UDP-glucose after UV irradiation, mutation of the DXD motif prevented radiolabeling. At high concentrations (10 mm) of manganese ions, the transferase activities of the D286A and D288A mutants but not that of wild-type fragment were increased by about 20-fold. The exchange of Asp270 and Arg273 reduced glucosyltransferase activity by about 200-fold and blocked glucohydrolase activity. The data indicate that the DXD motif, which is highly conserved in all large clostridial cytotoxins and also in a large number of glycosyltransferases, is functionally essential for the enzyme activity of the toxins and may participate in coordination of the divalent cation and/or in the binding of UDP-glucose.

The pleckstrin homology domain of oxysterol-binding protein recognises a determinant specific to Golgi membranes.

BACKGROUND Peripheral membrane proteins are targeted to the cytoplasmic face of specific intracellular membranes. The organelle-specific ligands recognised by peripheral proteins include other proteins and lipids. Oxysterol-binding protein (OSBP) translocates from the cytoplasm to the Golgi apparatus on binding oxygenated derivatives of cholesterol. The mechanism by which OSBP recognises the Golgi is unknown. It does, however, contain a pleckstrin homology (PH) domain, which in other proteins has been found to mediate regulated membrane binding, although in all previously studied examples the binding is to the plasma membrane. RESULTS The PH domain of OSBP and of a yeast homologue, Osh1p, were sufficient to target proteins specifically to mammalian Golgi membranes. In addition, high level expression disrupted Golgi architecture and prevented forward traffic of cargo protein. In vitro, the OSBP PH domain bound to Golgi membranes in a manner apparently dependent on phosphatidylinositol-4,5-bisphosphate (PI(4,5)P2) or a related phosphatidylinositide. The OSBP PH domain bound to PI(4,5)P2 in liposomes with a submicromolar dissociation constant. CONCLUSIONS The PH domains of OSBP and its yeast homologue recognise a determinant which is specific to Golgi membranes and important for Golgi function. The determinant appears to be a combination or a phosphatidylinositol polyphosphate and a second, Golgi-specific feature.

Multi-protein complexes in the cis Golgi of Saccharomyces cerevisiae with alpha-1,6-mannosyltransferase activity.

Anp1p, Van1p and Mnn9p constitute a family of membrane proteins required for proper Golgi function in Saccharomyces cerevisiae. We demonstrate that these proteins colocalize within the cis Golgi, and that they are physically associated in two distinct complexes, both of which contain Mnn9p. Furthermore, we identify two new proteins in the Anp1p–Mnn9p‐containing complex which have homology to known glycosyltransferases. Both protein complexes have α‐1,6‐mannosyltransferase activity, forming a series of poly‐mannose structures. These reaction products also contain some α‐1,2‐linked mannose residues. Our data suggest that these two multi‐protein complexes are responsible for the synthesis and initial branching of the long α‐1,6‐linked backbone of the hypermannose structure attached to many yeast glycoproteins.