Role of Erv29p in collecting soluble secretory proteins into ER-derived transport vesicles

Cargo selection in vesicular transport: the making and breaking of a coat

Intracellular traffic is mediated by vesicular/tubular carriers. The carriers are formed by the activity of cytosolic coat proteins that are recruited to their target membranes and deform these membranes into buds and vesicles. Specific interactions between recruited coat subunits and short peptide sequences (transport motifs) on cargo proteins direct the incorporation of cargo into budded vesicles. Here, we focus on cargo selection reactions mediated by COPII and AP-2/clathrin vesicle coat complexes to explore common mechanisms by which coat assembly support localized and selective cargo sorting. Recent findings suggest that multiple, low-affinity interactions are employed in a cooperative manner to support coat assembly and enable cargo recognition. Thus low-binding affinities between coat subunits and transport motifs are transiently transformed into high-avidity, multivalent and selective interactions at vesicle bud sites. The temporal and regulated nature of the interactions provide the key to cargo selection.

Lumenal protein multimerization in the distal secretory pathway/secretory granules

Differences in protein solubility appear to play an important role in lumenal protein trafficking through Golgi/post-Golgi compartments. Recent advances indicate that multimeric protein assembly is one of the factors regulating the efficiency of protein storage within secretory granules, by mechanisms that, with slight modification, might be considered to represent the culmination of a process of Golgi cisternal maturation.

COPII-dependent transport from the endoplasmic reticulum

The coat protein complex II (COPII) forms transport vesicles from the endoplasmic reticulum and segregates biosynthetic cargo from ER-resident proteins. Recent high-resolution structural studies on individual COPII subunits and on the polymerized coat reveal the molecular architecture of COPII vesicles. Other advances have shown that integral membrane accessory proteins act with the COPII coat to collect specific cargo molecules into ER-derived transport vesicles.

An HRD/DER-independent ER quality control mechanism involves Rsp5p-dependent ubiquitination and ER-Golgi transport

We have identified a new pathway of ER-associated degradation in Saccharomyces cerevisiae that functions separately from the HRD/DER pathway comprised of Hrd1p, Hrd3p, Der1p, and Ubc7p. This pathway, termed Hrd1p independent-proteolysis (HIP), is capable of recognizing and degrading both lumenal (CPY* and PrA*), and integral membrane proteins (Sec61-2p) that misfold in the ER. CPY* overexpression likely saturates the HRD/DER pathway and activates the HIP pathway, so the slowed degradation kinetics of CPY* in a hrd1 Delta strain is restored to a wild-type rate when CPY* is overexpressed. Substrates of HIP require vesicular trafficking between the ER and Golgi apparatus before degradation by the ubiquitin-proteasome system. Ubiquitination of HIP substrates does not involve the HRD/DER pathway ubiquitin ligase Hrd1p, but instead uses another ubiquitin ligase, Rsp5p. HIP is regulated by the unfolded protein response as Ire1p is necessary for the degradation of CPY* when overexpressed, but not when CPY* is expressed at normal levels. Both the HIP and HRD/DER pathways contribute to the degradation of CPY*, and only by eliminating both is CPY* degradation completely blocked.

Emp47p and its close homolog Emp46p have a tyrosine-containing endoplasmic reticulum exit signal and function in glycoprotein secretion in Saccharomyces cerevisiae

The yeast open reading frame YLR080w/EMP46 encodes a homolog of the Golgi protein Emp47p. These two proteins are 45% identical and have a single transmembrane domain in their C-terminal regions and a carbohydrate recognition domain signature in the N-terminal region. The C-terminal tail of Emp46p includes a dilysine signal. This protein is localized to Golgi membranes at steady state by subcellular fractionation and green fluorescent protein labeling. On block of forward transport in sec12-4 cells, redistribution of Emp46p from the Golgi to the endoplasmic reticulum is observed. These localization features are similar to those previously reported for Emp47p. In addition, mutagenesis of the C-terminal region identified a tyrosine-containing motif as a critical determinant of the Golgi-localization and interaction with both COPI and COPII components. Similar motifs are also observed in the C-terminal tail of Emp47p and other mammalian homologs. Disruption of Emp47p displays a growth defect at a high temperature or on Ca(2+)-containing medium, which is rescued by overexpression of Emp46p, suggesting a partially overlapping function between Emp46p and Emp47p. In addition, we found that the disruption of both Emp46p and Emp47p show a marked defect in the secretion of a subset of glycoproteins. Analysis of the C-terminal mutants for Ca(2+) sensitivity revealed that the forward transport of Emp46/47p is essential for their function, whereas the retrograde transport is not. We propose that Emp46p and Emp47p are required for the export of specific glycoprotein cargo from the endoplasmic reticulum.