Taking organelles apart, putting them back together and creating new ones: lessons from the endoplasmic reticulum

The endoplasmic reticulum (ER) is a highly dynamic organelle. It is composed of four subcompartments including nuclear envelope (NE), rough ER (rER), smooth ER (sER) and transitional ER (tER). The subcompartments are interconnected, can fragment and dissociate and are able to reassemble again. They coordinate with cell function by way of protein regulators in the surrounding cytosol. The activity of the many associated molecular machines of the ER as well as the fluid nature of the limiting membrane of the ER contribute extensively to the dynamics of the ER. This review examines the properties of the ER that permit its isolation and purification and the physiological conditions that permit reconstitution both in vitro and in vivo in normal and in disease conditions.     

Modulation of in vivo IgG crystallization in the secretory pathway by heavy chain isotype class switching and N-linked glycosylation

Crystalline bodies (CBs) can develop in the endoplasmic reticulum (ER) of antibody-producing cells. Although this phenotype is often reported in association with plasma cell dyscrasias and other hematological disorders, the details of CB biogenesis and CB's roles in pathophysiology remain poorly understood. Using an imaging-based screening method, we identified a secretion-competent human IgG2/λ clone that develops spindle-shaped intracellular crystals in transiently-transfected HEK293 cells upon Brefeldin A treatment. When stably overexpressed from CHO cells, the IgG2/λ clone spontaneously produced spindle-shaped CBs in the ER. Some CBs were released to the extracellular space while remaining enclosed by the membranes of secretory pathway origin. Structural modeling on the variable-region did not uncover prominent surface characteristics such as charge clusters. In contrast, alterations to the constant domain-encoded properties revealed their modulatory roles in CB-inducing propensities and CB morphology. For example, deletion of the entire Fc domain changed the morphology of CBs into thin filaments. Elimination of an N-linked glycan by a N297A mutation promoted Russell body biogenesis accompanied by marked reduction in IgG secretion. Isotype class switching from the original IgG2 to IgG1 and IgG4 changed the crystal morphology from spindle-shaped to long needle and acicular shaped, respectively. The IgG3 version, in contrast, suppressed the CB formation. Either the HC or LC alone or the Fc-domain alone did not trigger CB biogenesis. An IgG's in vivo crystal morphology and crystallization propensity can thus be modulated by the properties genetically and biochemically encoded in the HC constant region.     

Editorial: Defining the membrane precursor supporting the nucleation of the phagophore

How does the phagophore form? Which membrane acts as a platform for its biogenesis? Over the years, extensive use of microscopy techniques have led to the controversial identification of multiple potential membranes as precursors for phagophore nucleation and/or for the supply of lipids to the expanding compartment. Nevertheless, none of these studies has established a direct functional link between membrane sources and autophagosome biogenesis. Addressing this point, in a recent study highlighted by a punctum in this issue, Ge and coworkers developed an in vitro approach to determine the identity of the membranes responsible for the lipidation of LC3, thus identifying the ER-Golgi intermediate compartment (ERGIC) as a potential key determinant of phagophore biogenesis.     

SURF4-induced tubular ERGIC selectively expedites ER-to-Golgi transport

1. Download : Download high-res image (161KB)
2. Download : Download full-size image

     

Biogenesis of autophagosomal precursors for LC3 lipidation from the ER-Golgi intermediate compartment

Autophagosome biogenesis requires efficient mobilization and delivery of membranes from intracellular sources. How these membranes are mobilized remains poorly understood. Our recent work reported an autophagic signal-induced membrane mobilization event from the ER-Golgi intermediate compartment (ERGIC) to generate an early autophagosomal membrane precursor. We found that starvation activates the autophagic phosphatidylinositol 3-kinase, which promotes a relocation of COPII proteins from the ER-exit sites to the ERGIC. The relocation of COPII generates ERGIC-derived COPII vesicles as a membrane template for LC3 lipidation, a key step for autophagosome biogenesis.     

ARF-GAP-mediated interaction between the ER-Golgi v-SNAREs and the COPI coat

In eukaryotic cells, secretion is achieved by vesicular transport. Fusion of such vesicles with the correct target compartment relies on SNARE proteins on both vesicle (v-SNARE) and the target membranes (t-SNARE). At present it is not clear how v-SNAREs are incorporated into transport vesicles. Here, we show that binding of ADP-ribosylation factor (ARF)-GTPase-activating protein (GAP) to ER-Golgi v-SNAREs is an essential step for recruitment of Arf1p and coatomer, proteins that together form the COPI coat. ARF-GAP acts catalytically to recruit COPI components. Inclusion of v-SNAREs into COPI vesicles could be mediated by direct interaction with the coat. The mechanisms by which v-SNAREs interact with COPI and COPII coat proteins seem to be different and may play a key role in determining specificity in vesicle budding.     

Freeze-fracture and thin section study of the rough ER-Golgi interface in the pancreatic acinar cell. Resemblance between the intramembranal architecture of the outermost Golgi cisterna and the post-rough ER vesicular and tubular elements

Summary— Post-ER membranous structures are clearly observed in pancreases fixed with aldehydes and subsequently with reduced osmium. Close to the transitional rough ER, clusters of vesicles of ≈ 56 nm diameter are consistently present. In some cells, tortuous tubules appear enmeshed by the ≈ 56 nm vesicles and by irregular, vesicular formations. In freeze-fracture replicas, the membranes of the bulges and tubules that protrude from the transitional rough ER differ from those of the donor compartment. These protrusions are herein designated as the budding chamber of the transitional rough ER. Quantitative and qualitative observations performed previously and in the present study show that the P and E freeze-fracture faces of the outermost Golgi cisternal membrane possess patterns of texture that are unique among membranes. The P-face exhibits a very high density of intramembranous particles of dimensions among the smallest yet described; E-faces show rugosities and an unusually high density of intramembranous particles of normal size. The membranes of the budding chamber, the putative transport vesicles of ≈ 56 nm diameter, the sinuous tubules and the vesicles of irregular size and shape exhibit P and E fracture faces with textures indistinguishable from those of the corresponding P and E faces of the outermost Golgi cisterna.     

Depletion of vesicle-tethering factor p115 causes mini-stacked Golgi fragments with delayed protein transport

Depletion of p115 with small interfering RNA caused fragmentation of the Golgi apparatus, resulting in dispersed distribution of stacked short cisternae and a vesicular structure (mini-stacked Golgi). The mini-stacked Golgi with cis- and trans-organization is functional in protein transport and glycosylation, although secretion is considerably retarded in p115 knockdown cells. The fragmented Golgi was further disrupted by treatment with breferdin A and reassembled into the mini-stacked Golgi by removal of the drug, as observed in control cells. In addition, p115 knockdown cells maintained retrograde transport from the Golgi to the endoplasmic reticulum, although the rate was not as efficient as in control cells. While no alternation of microtubule networks was found in p115 knockdown cells, the fragmented Golgi resembled those in cells treated with anti-microtubule drugs. The results suggest that p115 is involved in vesicular transport between endoplasmic reticulum and the Golgi, along with microtubule networks.     

Synaptotagmin 11 interacts with components of the RNA-induced silencing complex RISC in clonal pancreatic β-cells

Synaptotagmins are two C₂ domain-containing transmembrane proteins. The function of calcium-sensitive members in the regulation of post-Golgi traffic has been well established whereas little is known about the calcium-insensitive isoforms constituting half of the protein family. Novel binding partners of synaptotagmin 11 were identified in β-cells. A number of them had been assigned previously to ER/Golgi derived-vesicles or linked to RNA synthesis, translation and processing. Whereas the C2A domain interacted with the Q-SNARE Vti1a, the C2B domain of syt11 interacted with the SND1, Ago2 and FMRP, components of the RNA-induced silencing complex (RISC). Binding to SND was direct via its N-terminal tandem repeats. Our data indicate that syt11 may provide a link between gene regulation by microRNAs and membrane traffic.     

Endomembrane remodeling in autophagic membrane formation

Autophagosomal membrane sources generate autophagic membrane precursors, which later assemble into the double-membrane autophagosome. The key events happening on the membrane sources during autophagic membrane generation remain poorly characterized. Our previous work found the ER-Golgi intermediate compartment (ERGIC) as a membrane source for the phagophore, the precursor to the autophagosome. A relocation of the COPII machinery from the ER-exit sites (ERES) to the ERGIC generates vesicles for LC3 lipidation. In recent work, we made a further step by showing that a starvation-induced remodeling of ERES facilitates the relocation of COPII to the ERGIC and the generation of the autophagic membrane.