bims-lypmec Biomed News
on Lysosomal positioning and metabolism in cardiomyocytes
Issue of 2024‒10‒13
four papers selected by
Satoru Kobayashi, New York Institute of Technology
  1. KIF1C facilitates retrograde transport of lysosomes through Hook3 and dynein.
  2. Spatial and functional separation of mTORC1 signalling in response to different amino acid sources.
  3. The lysosomal lipid transporter LIMP-2/SCARB2 is part of lysosome-endoplasmic reticulum STARD3-VAPB-dependent contact sites.
  4. Biomolecular condensates mediate bending and scission of endosome membranes.
  1. Commun Biol. 2024 Oct 11. 7(1): 1305
    KIF1C facilitates retrograde transport of lysosomes through Hook3 and dynein.
    Takeshi Saji, Mitsuharu Endo, Yasushi Okada, Yasuhiro Minami, Michiru Nishita.
      Lysosomes, crucial cellular organelles, undergo bidirectional transport along microtubules, mediated by motor proteins such as cytoplasmic dynein-1 (dynein) and various kinesins. While the kinesin-3 family member KIF1C is established in mediating anterograde vesicle transport, its role in lysosomal transport remains unclear. Our study reveals that KIF1C unexpectedly supports the retrograde transport of lysosomes, driven by dynein, and contributes to their perinuclear localization. Notably, while KIF1C facilitates this perinuclear positioning, its motor activity is not required and, instead, exerts an inhibitory effect on this process. Mechanistically, KIF1C facilitates this process by interacting with the dynein-activating adaptor Hook3, which associates with the lysosome-anchored protein RUFY3. This regulatory mechanism is critical for the efficient degradation of cargo in autophagic and endocytic pathways. Our findings identify an unconventional, non-motor role for KIF1C in activating dynein-driven lysosomal transport, expanding our understanding of its functional diversity in cellular trafficking.
    DOI:  https://doi.org/10.1038/s42003-024-07023-6
  2. Nat Cell Biol. 2024 Oct 09.
    Spatial and functional separation of mTORC1 signalling in response to different amino acid sources.
    Stephanie A Fernandes, Danai-Dimitra Angelidaki, Julian Nüchel, Jiyoung Pan, Peter Gollwitzer, Yoav Elkis, Filippo Artoni, Sabine Wilhelm, Marija Kovacevic-Sarmiento, Constantinos Demetriades.
      Amino acid (AA) availability is a robust determinant of cell growth through controlling mechanistic/mammalian target of rapamycin complex 1 (mTORC1) activity. According to the predominant model in the field, AA sufficiency drives the recruitment and activation of mTORC1 on the lysosomal surface by the heterodimeric Rag GTPases, from where it coordinates the majority of cellular processes. Importantly, however, the teleonomy of the proposed lysosomal regulation of mTORC1 and where mTORC1 acts on its effector proteins remain enigmatic. Here, by using multiple pharmacological and genetic means to perturb the lysosomal AA-sensing and protein recycling machineries, we describe the spatial separation of mTORC1 regulation and downstream functions in mammalian cells, with lysosomal and non-lysosomal mTORC1 phosphorylating distinct substrates in response to different AA sources. Moreover, we reveal that a fraction of mTOR localizes at lysosomes owing to basal lysosomal proteolysis that locally supplies new AAs, even in cells grown in the presence of extracellular nutrients, whereas cytoplasmic mTORC1 is regulated by exogenous AAs. Overall, our study substantially expands our knowledge about the topology of mTORC1 regulation by AAs and hints at the existence of distinct, Rag- and lysosome-independent mechanisms that control its activity at other subcellular locations. Given the importance of mTORC1 signalling and AA sensing for human ageing and disease, our findings will probably pave the way towards the identification of function-specific mTORC1 regulators and thus highlight more effective targets for drug discovery against conditions with dysregulated mTORC1 activity in the future.
    DOI:  https://doi.org/10.1038/s41556-024-01523-7
  3. J Cell Sci. 2024 Oct 07. pii: jcs.261810. [Epub ahead of print]
    The lysosomal lipid transporter LIMP-2/SCARB2 is part of lysosome-endoplasmic reticulum STARD3-VAPB-dependent contact sites.
    Sönke Rudnik, Saskia Heybrock, Etienne Coyaud, Zizhen Xu, Dante Neculai, Brian Raught, Viola Oorschot, Cecilia Heus, Judith Klumperman, Paul Saftig.
      SCARB2/LIMP-2 is an abundant lysosomal membrane protein. Previous studies have shown LIMP-2 functions as a virus receptor, a chaperone for lysosomal enzyme targeting, and a lipid transporter. The large luminal domain of LIMP-2 contains a hydrophobic tunnel that enables transport of phospholipids, sphingosine and cholesterol from the lysosomal lumen to the membrane. The question about the fate of the lipids after LIMP-2-mediated transport is largely unexplored. To elucidate whether LIMP-2 is part of contact sites between lysosomes and the endoplasmic reticulum (ER), we performed a proximity-based interaction screen. This revealed that LIMP-2 interacts with the endosomal protein STARD3 and the ER-resident protein VAPB. Using imaging and co-immunoprecipitation, we demonstrated colocalization and physical interaction between LIMP-2 and these proteins. Moreover, we found that interaction of LIMP-2 with VAPB required the presence of STARD3. Our findings suggest that LIMP-2 is part of ER-lysosome contact sites, possibly facilitating cholesterol transport from the lysosomal to the ER membrane. This suggests a novel mechanism for inter-organelle communication and lipid trafficking mediated by LIMP-2.
    Keywords:  Endoplasmic reticulum; LIMP-2; Lysosome; Membrane contact sites; SCARB2; STARD3; VAPB
    DOI:  https://doi.org/10.1242/jcs.261810
  4. Nature. 2024 Oct 09.
    Biomolecular condensates mediate bending and scission of endosome membranes.
    Yanning Wang, Shulin Li, Marcel Mokbel, Alexander I May, Zizhen Liang, Yonglun Zeng, Weiqi Wang, Honghong Zhang, Feifei Yu, Katharina Sporbeck, Liwen Jiang, Sebastian Aland, Jaime Agudo-Canalejo, Roland L Knorr, Xiaofeng Fang.
      Multivesicular bodies are key endosomal compartments implicated in cellular quality control through their degradation of membrane-bound cargo proteins1-3. The ATP-consuming ESCRT protein machinery mediates the capture and engulfment of membrane-bound cargo proteins through invagination and scission of multivesicular-body membranes to form intraluminal vesicles4,5. Here we report that the plant ESCRT component FREE16 forms liquid-like condensates that associate with membranes to drive intraluminal vesicle formation. We use a minimal physical model, reconstitution experiments and in silico simulations to identify the dynamics of this process and describe intermediate morphologies of nascent intraluminal vesicles. Furthermore, we find that condensate-wetting-induced line tension forces and membrane asymmetries are sufficient to mediate scission of the membrane neck without the ESCRT protein machinery or ATP consumption. Genetic manipulation of the ESCRT pathway in several eukaryotes provides additional evidence for condensate-mediated membrane scission in vivo. We find that the interplay between condensate and machinery-mediated scission mechanisms is indispensable for osmotic stress tolerance in plants. We propose that condensate-mediated scission represents a previously undescribed scission mechanism that depends on the physicomolecular properties of the condensate and is involved in a range of trafficking processes. More generally, FREE1 condensate-mediated membrane scission in multivesicular-body biogenesis highlights the fundamental role of wetting in intracellular dynamics and organization.
    DOI:  https://doi.org/10.1038/s41586-024-07990-0
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