About

Susan Ferro-Novick is a Professor of Cellular and Molecular Medicine at UC San Diego. Her laboratory studies how the directionality and specificity of vesicle traffic between the endoplasmic reticulum (ER) and Golgi apparatus is achieved, with a focus on the role that the GTPase Rab1 plays in these processes and in autophagy. Her research also explores the structure and inheritance of the endoplasmic reticulum, contributing to the understanding of ER dynamics and its involvement in cellular homeostasis. Her work encompasses various aspects of membrane trafficking, autophagy, and ER quality control, including the connection between ER-phagy, ER structure, and hereditary spastic paraplegias. Ferro-Novick's research has significantly advanced knowledge of how ER tubules influence proteostasis, the mechanisms of ER autophagy, and the roles of specific proteins such as VPS13A and VPS13C in lipid droplet regulation. She has contributed to elucidating the molecular mechanisms underlying ER-related processes and their implications for disease, establishing her as a leading figure in cell biology and membrane trafficking.

Selected publications

• Endoplasmic reticulum tubule junctions are sites of autophagy

  Autophagy · 2025-05-26 · 3 citations

  articleOpen access1st authorCorresponding

  E3 ligase that ubiquitinates RTN3L targets ERAD-resistant misfolded protein condensates for degradation at ER-reticulophagy sites (ERPHS), autophagic sites that form at tubule junctions. Unexpectedly, we found that the Parkinson disease protein PINK1 regulates ER tubulation. Loss of PINK1 disrupts the formation of peripheral tubule junctions, and, as a consequence, reticulophagy is blocked and misfolded proteins accumulate in the ER. Overexpression of the ER tubulating domain of DNM1L/DRP1, a multifunctional PINK1 kinase substrate that localizes to ER-mitochondria contact sites, increases junctions and restores reticulophagy. Our findings show that PINK1 shapes the ER to target misfolded proteins for RTN3L-SEC24C-mediated macroreticulophagy at defined ER sites, peripheral tubule junctions.

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• Correction: PINK1 controls RTN3L-mediated ER autophagy by regulating peripheral tubule junctions

  The Journal of Cell Biology · 2025-05-19

  erratumOpen accessSenior author

  After publication, the authors discovered that an error bar had been erroneously omitted from the graph in Fig. 5 B. This graph shows that the lysosomal delivery of the ER junction marker, LNPK, was blocked in PINK1-depleted cells.An error bar has been added to the fourth column, siPINK1 + Baf.The original and corrected Fig. 5 are shown here.This error does not affect the conclusions of the study, and the figure legend remains unchanged.

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• RTN3L and CALCOCO1 function in parallel to maintain proteostasis in the endoplasmic reticulum

  Autophagy · 2024-05-31 · 6 citations

  articleOpen accessSenior authorCorresponding

  ; CALCOCO1: calcium binding and coiled-coil domain 1; Epr1: ER-phagy receptor 1; ER: endoplasmic reticulum; ERAD: ER-associated protein degradation; ERPHS: ER-reticulophagy sites; LAMP1: lysosomal associated membrane protein 1; PGRMC1: progesterone receptor membrane component 1; POMC: proopiomelanocortin; Pro-AVP: pro-arginine vasopressin; RETREG1: reticulophagy regulator 1; reticulophagy: endoplasmic reticulum selective autophagy; RTN3L: reticulon 3 long isoform; VAPA: VAMP associated protein A.

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• PINK1 controls RTN3L-mediated ER autophagy by regulating peripheral tubule junctions

  The Journal of Cell Biology · 2024-11-18 · 6 citations

  articleOpen accessSenior author

  Here, we report that the RTN3L-SEC24C endoplasmic reticulum autophagy (ER-phagy) receptor complex, the CUL3KLHL12 E3 ligase that ubiquitinates RTN3L, and the FIP200 autophagy initiating protein, target mutant proinsulin (Akita) condensates for lysosomal delivery at ER tubule junctions. When delivery was blocked, Akita condensates accumulated in the ER. In exploring the role of tubulation in these events, we unexpectedly found that loss of the Parkinson's disease protein, PINK1, reduced peripheral tubule junctions and blocked ER-phagy. Overexpression of the PINK1 kinase substrate, DRP1, increased junctions, reduced Akita condensate accumulation, and restored lysosomal delivery in PINK1-depleted cells. DRP1 is a dual-functioning protein that promotes ER tubulation and severs mitochondria at ER-mitochondria contact sites. DRP1-dependent ER tubulating activity was sufficient for suppression. Supporting these findings, we observed PINK1 associating with ER tubules. Our findings show that PINK1 shapes the ER to target misfolded proinsulin for RTN3L-SEC24C-mediated macro-ER-phagy at defined ER sites called peripheral junctions. These observations may have important implications for understanding Parkinson's disease.

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• Different ER–plasma membrane tethers play opposing roles in autophagy of the cortical ER

  Proceedings of the National Academy of Sciences · 2024-06-05 · 5 citations

  articleOpen access

  The endoplasmic reticulum (ER) undergoes degradation by selective macroautophagy (ER-phagy) in response to starvation or the accumulation of misfolded proteins within its lumen. In yeast, actin assembly at sites of contact between the cortical ER (cER) and endocytic pits acts to displace elements of the ER from their association with the plasma membrane (PM) so they can interact with the autophagosome assembly machinery near the vacuole. A collection of proteins tether the cER to the PM. Of these, Scs2/22 and Ist2 are required for cER-phagy, most likely through their roles in lipid transport, while deletion of the tricalbins, TCB1 / 2 /3, bypasses those requirements. An artificial ER–PM tether blocks cER-phagy in both the wild type (WT) and a strain lacking endogenous tethers, supporting the importance of cER displacement from the PM. Scs2 and Ist2 can be cross-linked to the selective cER-phagy receptor, Atg40. The COPII cargo adaptor subunit, Lst1, associates with Atg40 and is required for cER-phagy. This requirement is also bypassed by deletion of the ER–PM tethers, suggesting a role for Lst1 prior to the displacement of the cER from the PM during cER-phagy. Although pexophagy and mitophagy also require actin assembly, deletion of ER–PM tethers does not bypass those requirements. We propose that within the context of rapamycin-induced cER-phagy, Scs2/22, Ist2, and Lst1 promote the local displacement of an element of the cER from the cortex, while Tcb1/2/3 act in opposition, anchoring the cER to the plasma membrane.

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• VPS13A and VPS13C Influence Lipid Droplet Abundance

  Contact · 2022-01-01 · 22 citations

  articleOpen accessSenior authorCorresponding

  Lipid transfer proteins mediate the exchange of lipids between closely apposed membranes at organelle contact sites and play key roles in lipid metabolism, membrane homeostasis, and cellular signaling. A recently discovered novel family of lipid transfer proteins, which includes the VPS13 proteins (VPS13A-D), adopt a rod-like bridge conformation with an extended hydrophobic groove that enables the bulk transfer of membrane lipids for membrane growth. Loss of function mutations in VPS13A and VPS13C cause chorea acanthocytosis and Parkinson's disease, respectively. VPS13A and VPS13C localize to multiple organelle contact sites, including endoplasmic reticulum (ER) - lipid droplet (LD) contact sites, but the functional roles of these proteins in LD regulation remains mostly unexplored. Here we employ CRISPR-Cas9 genome editing to generate VPS13A and VPS13C knockout cell lines in U-2 OS cells via deletion of exon 2 and introduction of an early frameshift. Analysis of LD content in these cell lines revealed that loss of either VPS13A or VPS13C results in reduced LD abundance under oleate-stimulated conditions. These data implicate two lipid transfer proteins, VPS13A and VPS13C, in LD regulation.

  PublisherOA PDFDOI

• Architecture of the endoplasmic reticulum plays a role in proteostasis

  Autophagy · 2022-01-31 · 15 citations

  letterOpen accessSenior authorCorresponding

  The endoplasmic reticulum (ER) forms a contiguous network of tubules and sheets. When errors in protein folding occur, misfolded proteins accumulate in the ER. Proteostasis can be restored by ER quality control pathways. Reticulophagy is an ER quality control pathway that uses resident autophagy receptors to link an ER domain to the autophagy machinery. We recently showed that the reticulophagy receptor RTN3L recruits the COPII cargo adaptor SEC24C to target disease-causing mutant proinsulin INS2Akita puncta to the lysosome for degradation. When reticulophagy is disrupted and delivery to the lysosome is blocked, large INS2Akita puncta accumulate in the ER. Photobleach analysis revealed that these puncta behave like liquid condensates and not aggregates, as previously suggested. Other reticulophagy substrates that are segregated into tubules behave like INS2Akita, whereas a substrate of the ER sheets receptor, RETREG1/FAM134B, appears to be less fluid. Large INS2Akita puncta also accumulate when ER sheets are proliferated by the loss of LNPK, or by overproduction of the sheets-producing protein, CKAP4/CLIMP63. Restoring the tubular network by overexpressing reticulons reverses this phenotype. Our findings revealed that fluid-like deleterious cargoes are segregated into tubules to prevent them from expanding and affecting cell health while they are waiting to undergo reticulophagy.

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• Autophagy of the ER Requires Actin Assembly Driven by the Interaction of ER with Endocytic Pits

  Contact · 2022-01-01

  articleOpen accessSenior author

  Autophagy of the cortical ER in budding yeast was unexpectedly found to require End3, a component of the endocytic machinery that promotes the assembly of actin at endocytic pits on the plasma membrane. The cortical ER transiently interacts with invaginating endocytic pits through a linkage consisting of VAP proteins, oxysterol binding proteins and type I myosins. These proteins are required for actin assembly and for autophagy of the ER. Assembly of actin at these contact sites may direct the movement of ER away from the cortex towards sites of autophagosome assembly.

  PublisherDOI

• Actin assembly at sites of contact between the cortical ER and endocytic pits promotes ER autophagy

  Autophagy · 2022-05-09 · 2 citations

  articleOpen access

  deletion library implicated End3 in autophagy of the endoplasmic reticulum (ER). Together with Pan1, End3 coordinates endocytic site initiation with the localized assembly of branching actin filaments that promotes invagination of endocytic pits. Oxysterol binding proteins function as an inter-organelle bridge by interacting with VAP proteins on the cortical ER and type I myosins on the endocytic pit. These proteins not only promote localized actin assembly at contact sites, they are required for ER autophagy as well. We propose that localized actin polymerization can push the edge of an ER sheet from the cell cortex toward the site of autophagosome assembly near the vacuole.

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• VPS13A and VPS13C influence lipid droplet abundance

  bioRxiv (Cold Spring Harbor Laboratory) · 2022-06-23 · 3 citations

  preprintOpen accessSenior authorCorresponding

  ABSTRACT Lipid transfer proteins mediate the exchange of lipids between closely apposed membranes at organelle contact sites and play key roles in lipid metabolism, membrane homeostasis, and cellular signaling. A recently discovered novel family of lipid transfer proteins, which includes the VPS13 proteins (VPS13A-D), adopt a rod-like bridge conformation with an extended hydrophobic groove that enables the bulk transfer of membrane lipids for membrane growth. Loss of function mutations in VPS13A and VPS13C cause chorea acanthocytosis and Parkinson’s disease, respectively. VPS13A and VPS13C localize to multiple organelle contact sites, including endoplasmic reticulum (ER) – lipid droplet (LD) contact sites, but the functional roles of these proteins in LD regulation remains mostly unexplored. Here, we employ CRISPR-Cas9 genome editing to generate VPS13A and VPS13C knockout cell lines in U-2 OS cells via deletion of exon 2 and introduction of an early frameshift. Analysis of LD content in these cell lines revealed that loss of either VPS13A or VPS13C results in reduced LD abundance under oleate-stimulated conditions. These data implicate VPS13A and VPS13C in LD regulation and raise the intriguing possibility that VPS13A and VPS13C-mediated lipid transfer facilitates LD biogenesis.

  PublisherOA PDFDOI