Showing papers in "Journal of Cell Biology in 2023"
TL;DR: In this article , the authors analyzed the abundance, single-molecule dynamics, and autophagosome association kinetics of autophagy proteins involved in autophagome biogenesis.
Abstract: Autophagy is a catabolic pathway required for the recycling of cytoplasmic materials. To define the mechanisms underlying autophagy it is critical to quantitatively characterize the dynamic behavior of autophagy factors in living cells. Using a panel of cell lines expressing HaloTagged autophagy factors from their endogenous loci, we analyzed the abundance, single-molecule dynamics, and autophagosome association kinetics of autophagy proteins involved in autophagosome biogenesis. We demonstrate that autophagosome formation is inefficient and ATG2-mediated tethering to donor membranes is a key commitment step in autophagosome formation. Furthermore, our observations support the model that phagophores are initiated by the accumulation of autophagy factors on mobile ATG9 vesicles, and that the ULK1 complex and PI3-kinase form a positive feedback loop required for autophagosome formation. Finally, we demonstrate that the duration of autophagosome biogenesis is ∼110 s. In total, our work provides quantitative insight into autophagosome biogenesis and establishes an experimental framework to analyze autophagy in human cells.
6 citations
TL;DR: In this paper , it was shown that microglia contribute to the removal of aberrant structures and may be an important mechanism to generate properly functioning myelin in mouse optic nerve.
Abstract: Djannatian et al. show by ultrastructural analysis of mouse optic nerves and in vivo imaging of zebrafish spinal cords that developmental myelination is an error-prone process and microglia contribute to the removal of aberrant structures. This may be an important mechanism to generate properly functioning myelin.
6 citations
TL;DR: In this article, an open-source suite of ultrastructural quantifications, integrated into a single pipeline called the surface morphometrics pipeline, is proposed to quantify changes in membrane ultrastructure on a single-cell level using cryo-electron tomography (cryo-ET).
Abstract: Cellular cryo-electron tomography (cryo-ET) enables three-dimensional reconstructions of organelles in their native cellular environment at subnanometer resolution. However, quantifying ultrastructural features of pleomorphic organelles in three dimensions is challenging, as is defining the significance of observed changes induced by specific cellular perturbations. To address this challenge, we established a semiautomated workflow to segment organellar membranes and reconstruct their underlying surface geometry in cryo-ET. To complement this workflow, we developed an open-source suite of ultrastructural quantifications, integrated into a single pipeline called the surface morphometrics pipeline. This pipeline enables rapid modeling of complex membrane structures and allows detailed mapping of inter- and intramembrane spacing, curvedness, and orientation onto reconstructed membrane meshes, highlighting subtle organellar features that are challenging to detect in three dimensions and allowing for statistical comparison across many organelles. To demonstrate the advantages of this approach, we combine cryo-ET with cryo-fluorescence microscopy to correlate bulk mitochondrial network morphology (i.e., elongated versus fragmented) with membrane ultrastructure of individual mitochondria in the presence and absence of endoplasmic reticulum (ER) stress. Using our pipeline, we demonstrate ER stress promotes adaptive remodeling of ultrastructural features of mitochondria including spacing between the inner and outer membranes, local curvedness of the inner membrane, and spacing between mitochondrial cristae. We show that differences in membrane ultrastructure correlate to mitochondrial network morphologies, suggesting that these two remodeling events are coupled. Our pipeline offers opportunities for quantifying changes in membrane ultrastructure on a single-cell level using cryo-ET, opening new opportunities to define changes in ultrastructural features induced by diverse types of cellular perturbations.
6 citations
TL;DR: The authors showed that in the absence of lipid transport, ATG9 vesicles are already competent to collect proteins found on mature autophagosomes, including LC3-II.
Abstract: As the autophagosome forms, its membrane surface area expands rapidly, while its volume is kept low. Protein-mediated transfer of lipids from another organelle to the autophagosome likely drives this expansion, but as these lipids are only introduced into the cytoplasmic-facing leaflet of the organelle, full membrane growth also requires lipid scramblase activity. ATG9 harbors scramblase activity and is essential to autophagosome formation; however, whether ATG9 is integrated into mammalian autophagosomes remains unclear. Here we show that in the absence of lipid transport, ATG9 vesicles are already competent to collect proteins found on mature autophagosomes, including LC3-II. Further, we use styrene–maleic acid lipid particles to reveal the nanoscale organization of protein on LC3-II membranes; ATG9 and LC3-II are each fully integrated into expanding autophagosomes. The ratios of these two proteins at different stages of maturation demonstrate that ATG9 proteins are not continuously integrated, but rather are present on the seed vesicles only and become diluted in the expanding autophagosome membrane.
5 citations
TL;DR: In this article , a role for yeast Svf1 in ceramide transport between the endoplasmic reticulum and the Golgi is identified, and it is shown that Svf 1 is a ceramide binding protein that contributes to sphingolipid metabolism at Golgi compartments.
Abstract: Ceramides are essential precursors of complex sphingolipids and act as potent signaling molecules. Ceramides are synthesized in the endoplasmic reticulum (ER) and receive their head-groups in the Golgi apparatus, yielding complex sphingolipids (SPs). Transport of ceramides between the ER and the Golgi is executed by the essential ceramide transport protein (CERT) in mammalian cells. However, yeast cells lack a CERT homolog, and the mechanism of ER to Golgi ceramide transport remains largely elusive. Here, we identified a role for yeast Svf1 in ceramide transport between the ER and the Golgi. Svf1 is dynamically targeted to membranes via an N-terminal amphipathic helix (AH). Svf1 binds ceramide via a hydrophobic binding pocket that is located in between two lipocalin domains. We showed that Svf1 membrane-targeting is important to maintain flux of ceramides into complex SPs. Together, our results show that Svf1 is a ceramide binding protein that contributes to sphingolipid metabolism at Golgi compartments.
4 citations
TL;DR: Sassano et al. as discussed by the authors reveal that EMCS-associated PERK recruits the lipid transfer protein E-Syt1 at EMCS facilitating lipid transport to sustain mitochondrial homeostasis and respiration.
Abstract: ER–mitochondria contact sites (EMCS) regulate non-vesicular phospholipid transport between these organelles, but the molecular entities involved in lipid translocation remain undefined. Sassano et al. reveal that EMCS-associated PERK recruits the lipid transfer protein E-Syt1 at EMCS facilitating lipid transport to sustain mitochondrial homeostasis and respiration.
3 citations
TL;DR: In this article , the authors identified a new mechanism of monocyte activation that is mediated by the interaction of TIMP-1 with APP and provided evidence for a TIMP1-mediated proinflammatory activation of human monocytes in clinical cancer samples.
Abstract: The authors identified a new mechanism of monocyte activation that is mediated by the interaction of TIMP-1 with APP. Furthermore, they provide evidence for a TIMP-1-mediated proinflammatory activation of human monocytes in clinical cancer samples.
3 citations
TL;DR: In this article , a Cooperative Curvature Model (CCM) was proposed to accurately describe the changes in shapes and dynamics during endocytic clathrin remodeling, which can reveal the three-dimensional shapes of CLYCLINES.
Abstract: Mund and Tschanz et al. reveal the three-dimensional shapes of clathrin coats during endocytosis, which partially preassemble and then bend progressively. They further introduce the novel Cooperative Curvature Model, which accurately describes the changes in shapes and dynamics during endocytic clathrin remodeling.
3 citations
TL;DR: In this paper , Atg2-mediated non-vesicular phospholipid transfer (PLT) is shown to be non-rate limiting for autophagosome biogenesis because membrane tether and the PLT protein Vps13 localizes to the rim and promotes the expansion of phagophores in parallel with atg2.
Abstract: During autophagy, rapid membrane assembly expands small phagophores into large double-membrane autophagosomes. Theoretical modeling predicts that the majority of autophagosomal phospholipids are derived from highly efficient non-vesicular phospholipid transfer (PLT) across phagophore-ER contacts (PERCS). Currently, the phagophore-ER tether Atg2 is the only PLT protein known to drive phagophore expansion in vivo. Here, our quantitative live-cell imaging analysis reveals a poor correlation between the duration and size of forming autophagosomes and the number of Atg2 molecules at PERCS of starving yeast cells. Strikingly, we find that Atg2-mediated PLT is non-rate limiting for autophagosome biogenesis because membrane tether and the PLT protein Vps13 localizes to the rim and promotes the expansion of phagophores in parallel with Atg2. In the absence of Vps13, the number of Atg2 molecules at PERCS determines the duration and size of forming autophagosomes with an apparent in vivo transfer rate of ∼200 phospholipids per Atg2 molecule and second. We propose that conserved PLT proteins cooperate in channeling phospholipids across organelle contact sites for non-rate-limiting membrane assembly during autophagosome biogenesis.
3 citations
TL;DR: A feed-forward mechanism, whereby dynein-dependent accumulation of staufen mRNA and protein in the oocyte enables motor switching during oskar mRNA transport by downregulating dyneIn activity, is identified.
Abstract: Regulated recruitment and activity of motor proteins is essential for intracellular transport of cargoes, including messenger ribonucleoprotein complexes (RNPs). Here we show that orchestration of oskar RNP transport in the Drosophila germline relies on the interplay of two double-stranded RNA binding proteins, Staufen and the dynein adaptor Egalitarian (Egl). We find that Staufen antagonizes Egl-mediated transport of oskar mRNA by dynein both in vitro and in vivo. Following delivery of nurse cell-synthesized oskar mRNA into the oocyte by dynein, recruitment of Staufen to the RNPs results in dissociation of Egl and a switch to kinesin-1-mediated translocation of the mRNA to its final destination at the posterior pole of the oocyte. We additionally show that Egl associates with staufen (stau) mRNA in the nurse cells, mediating its enrichment and translation in the ooplasm. Our observations identify a novel feed-forward mechanism, whereby dynein-dependent accumulation of stau mRNA, and thus protein, in the oocyte enables motor switching on oskar RNPs by downregulating dynein activity.
3 citations
TL;DR: In this article, the authors find that the poorly characterized mitochondrial protein TMEM11 forms a complex with BNIP3/BNIP3L and co-enriches at sites of mitophagosome formation.
Abstract: Mitochondria play critical roles in cellular metabolism and to maintain their integrity, they are regulated by several quality control pathways, including mitophagy. During BNIP3/BNIP3L-dependent receptor-mediated mitophagy, mitochondria are selectively targeted for degradation by the direct recruitment of the autophagy protein LC3. BNIP3 and/or BNIP3L are upregulated situationally, for example during hypoxia and developmentally during erythrocyte maturation. However, it is not well understood how they are spatially regulated within the mitochondrial network to locally trigger mitophagy. Here, we find that the poorly characterized mitochondrial protein TMEM11 forms a complex with BNIP3 and BNIP3L and co-enriches at sites of mitophagosome formation. We find that mitophagy is hyper-active in the absence of TMEM11 during both normoxia and hypoxia-mimetic conditions due to an increase in BNIP3/BNIP3L mitophagy sites, supporting a model that TMEM11 spatially restricts mitophagosome formation.
TL;DR: In this paper , it was found that luminal Cl- influx, driven by the 2Cl-/H+ exchanger ClC-7, is necessary for the resolution of phagolysosomes formed by macrophages.
Abstract: Degradative organelles contain enzymes that function optimally at the acidic pH generated by the V-ATPase. The resulting transmembrane H+ gradient also energizes the secondary transport of several solutes, including Cl-. We report that Cl- influx, driven by the 2Cl-/H+ exchanger ClC-7, is necessary for the resolution of phagolysosomes formed by macrophages. Cl- transported via ClC-7 had been proposed to provide the counterions required for electrogenic H+ pumping. However, we found that deletion of ClC-7 had a negligible effect on phagosomal acidification. Instead, luminal Cl- was found to be required for activation of a wide range of phagosomal hydrolases including proteases, nucleases, and glycosidases. These findings argue that the primary role of ClC-7 is the accumulation of (phago)lysosomal Cl- and that the V-ATPases not only optimize the activity of degradative hydrolases by lowering the pH but, importantly, also play an indirect role in their activation by providing the driving force for accumulation of luminal Cl- that stimulates hydrolase activity allosterically.
TL;DR: Moore, Bhaskar, Gao, et al. as mentioned in this paper combine live imaging of the mouse epidermis and machine learning to study the role and regulation of calcium signaling within the stem cell layer.
Abstract: Moore, Bhaskar, Gao, et al. combine live imaging of the mouse epidermis and machine learning to study the role and regulation of calcium signaling within the stem cell layer. They find that cells in G2 are necessary for coordinated tissue-wide communication and reveal a feedback loop between cell cycle and calcium signaling.
TL;DR: This paper showed that precursors of specific GPI-anchored proteins, such as CD55, function with an ER-resident lipid homeostasis regulator ARV1 to upregulate GPI biosynthesis in the ER.
Abstract: Liu et al. show that precursors of specific GPI-anchored proteins, such as CD55, function with an ER-resident lipid homeostasis regulator ARV1 to upregulate GPI biosynthesis in the ER. This may be an important mechanism to increase GPI when needed.
TL;DR: Fujiwara et al. as discussed by the authors developed an ultrafast camera that allows single fluorescent-molecule imaging every 33 µs with a localization precision of 34 nm (every 100 µs; 20 nm) and enables ultrafast PALM imaging of whole live cells.
Abstract: An ultrafast camera developed by Fujiwara et al. allows single fluorescent-molecule imaging every 33 µs with a localization precision of 34 nm (every 100 µs; 20 nm) and enables ultrafast PALM imaging of whole live cells.
TL;DR: Parker and Karbstein this article reviewed the current understanding of the quality control mechanisms governing ribosome assembly and showed that these mechanisms can be used to improve the quality of ribosomes.
Abstract: Melissa Parker and Katrin Karbstein review our current understanding of the quality control mechanisms governing ribosome assembly.
TL;DR: This paper showed that all human atlastins are sufficient to induce fusion when reconstituted into liposomes with a lipid composition mimicking that of the endoplasmic reticulum (ER) membrane.
Abstract: The dynamin-like GTPase atlastin is believed to be the minimal machinery required for homotypic endoplasmic reticulum (ER) membrane fusion, mainly because Drosophila atlastin is sufficient to drive liposome fusion. However, it remains unclear whether mammalian atlastins, including the three human atlastins, are sufficient to induce liposome fusion, raising doubts about their major roles in mammalian cells. Here, we show that all human atlastins are sufficient to induce fusion when reconstituted into liposomes with a lipid composition mimicking that of the ER. Although the fusogenic activity of ATL1, which is predominantly expressed in neuronal cells, was weaker than that of ATL2 or ATL3, the addition of M1-spastin, a neuron-specific factor, markedly increased ATL1-mediated liposome fusion. Although we observed efficient fusion between ER microsomes isolated from cultured, non-neuronal cells that predominantly express ATL2-1, an autoinhibited isoform of ATL2, ATL2-1 failed to support liposome fusion by itself as reported previously, indicating that cellular factors enable ATL2-1 to mediate ER fusion in vivo.
TL;DR: In this article , a testis-specific protein, ADAD2, interacts with a TDRD family member protein RNF17 and is associated with P-bodies.
Abstract: Pachytene piRNA biogenesis is a hallmark of the germline, distinct from another wave of pre-pachytene piRNA biogenesis with regard to the lack of a secondary amplification process known as the Ping-pong cycle. However, the underlying molecular mechanism and the venue for the suppression of the Ping-pong cycle remain elusive. Here, we showed that a testis-specific protein, ADAD2, interacts with a TDRD family member protein RNF17 and is associated with P-bodies. Importantly, ADAD2 directs RNF17 to repress Ping-pong activity in pachytene piRNA biogenesis. The P-body localization of RNF17 requires the intrinsically disordered domain of ADAD2. Deletion of Adad2 or Rnf17 causes the mislocalization of each other and subsequent Ping-pong activity derepression, secondary piRNAs overproduced, and disruption of P-body integrity at the meiotic stage, thereby leading to spermatogenesis arrested at the round spermatid stage. Collectively, by identifying the ADAD2-dependent mechanism, our study reveals a novel function of P-bodies in suppressing Ping-pong activity in pachytene piRNA biogenesis.
TL;DR: The LIM homeodomain transcription factors LMX1A and LMX 1B are essential mediators of midbrain dopaminergic neuronal (mDAN) differentiation and survival as discussed by the authors .
Abstract: The LIM homeodomain transcription factors LMX1A and LMX1B are essential mediators of midbrain dopaminergic neuronal (mDAN) differentiation and survival. Here we show that LMX1A and LMX1B are autophagy transcription factors that provide cellular stress protection. Their suppression dampens the autophagy response, lowers mitochondrial respiration, and elevates mitochondrial ROS, and their inducible overexpression protects against rotenone toxicity in human iPSC-derived mDANs in vitro. Significantly, we show that LMX1A and LMX1B stability is in part regulated by autophagy, and that these transcription factors bind to multiple ATG8 proteins. Binding is dependent on subcellular localization and nutrient status, with LMX1B interacting with LC3B in the nucleus under basal conditions and associating with both cytosolic and nuclear LC3B during nutrient starvation. Crucially, ATG8 binding stimulates LMX1B-mediated transcription for efficient autophagy and cell stress protection, thereby establishing a novel LMX1B-autophagy regulatory axis that contributes to mDAN maintenance and survival in the adult brain.
TL;DR: Fujiwara et al. as discussed by the authors improved the time resolution of single-molecule localization microscopy, revealing the focal adhesion's dynamic nano-architecture and leading to the model of compartmentalized archipelago of focal-adhesion protein islands.
Abstract: The ultrafast camera with single fluorescent-molecule sensitivities developed by Fujiwara et al. has greatly improved the time resolution of single-molecule localization microscopy, revealing the focal adhesion’s dynamic nano-architecture and leading to the model of compartmentalized archipelago of focal-adhesion protein islands.
TL;DR: In this paper , the authors used single-molecule localization microscopy to visualize individual kinetochore complexes in situ in budding yeast and measured their abundance and position within the metaphase kineto-chromosome.
Abstract: Proper chromosome segregation is crucial for cell division. In eukaryotes, this is achieved by the kinetochore, an evolutionarily conserved multiprotein complex that physically links the DNA to spindle microtubules and takes an active role in monitoring and correcting erroneous spindle-chromosome attachments. Our mechanistic understanding of these functions and how they ensure an error-free outcome of mitosis is still limited, partly because we lack a complete understanding of the kinetochore structure in the cell. In this study, we use single-molecule localization microscopy to visualize individual kinetochore complexes in situ in budding yeast. For major kinetochore proteins, we measured their abundance and position within the metaphase kinetochore. Based on this comprehensive dataset, we propose a quantitative model of the budding yeast kinetochore. While confirming many aspects of previous reports based on bulk imaging, our results present a unifying nanoscale model of the kinetochore in budding yeast.
TL;DR: Maiato and Silva as discussed by the authors discuss the origin and fate of chromosome segregation errors that satisfy the spindle assembly checkpoint, focusing on anaphase surveillance/correction mechanisms and post-mitotic clearance pathways.
Abstract: Maiato and Silva discuss the origin and fate of chromosome segregation errors that satisfy the spindle assembly checkpoint, focusing on anaphase surveillance/correction mechanisms and post-mitotic clearance pathways.
TL;DR: Neuzil et al. as discussed by the authors reviewed the processes and mechanisms that underlie horizontal mitochondrial transfer and the metabolic consequences of HMT in cells, and showed that HMT is beneficial.
Abstract: Jiri Neuzil and colleagues review the processes and mechanisms that underlie horizontal mitochondrial transfer (HMT) and the metabolic consequences of HMT in cells.
TL;DR: In this article , the authors show that impairment of endolysosomal fusion by disruption of a pathway involving the BLOC-one-related complex (BORC), the small GTPase ARL8, and the tethering factor HOPS increases exosome secretion by preventing the delivery of intraluminal vesicles to lysosomes.
Abstract: Exosomes are small vesicles that are secreted from cells to dispose of undegraded materials and mediate intercellular communication. A major source of exosomes is intraluminal vesicles within multivesicular endosomes that undergo exocytic fusion with the plasma membrane. An alternative fate of multivesicular endosomes is fusion with lysosomes, resulting in degradation of the intraluminal vesicles. The factors that determine whether multivesicular endosomes fuse with the plasma membrane or with lysosomes are unknown. In this study, we show that impairment of endolysosomal fusion by disruption of a pathway involving the BLOC-one-related complex (BORC), the small GTPase ARL8, and the tethering factor HOPS increases exosome secretion by preventing the delivery of intraluminal vesicles to lysosomes. These findings demonstrate that endolysosomal fusion is a critical determinant of the amount of exosome secretion and suggest that suppression of the BORC-ARL8-HOPS pathway could be used to boost exosome yields in biotechnology applications.
TL;DR: In this paper , a duplication event within the CDC11 locus in Ashbya gossypii gave rise to two similar but distinct septin proteins: Cdc11a and Cdc1b.
Abstract: Septins are a family of conserved filament-forming proteins that function in multiple cellular processes. The number of septin genes within an organism varies, and higher eukaryotes express many septin isoforms due to alternative splicing. It is unclear if different combinations of septin proteins in complex alter the polymers' biophysical properties. We report that a duplication event within the CDC11 locus in Ashbya gossypii gave rise to two similar but distinct Cdc11 proteins: Cdc11a and Cdc1b. CDC11b transcription is developmentally regulated, producing different amounts of Cdc11a- and Cdc11b-complexes in the lifecycle of Ashbya gossypii. Deletion of either gene results in distinct cell polarity defects, suggesting non-overlapping functions. Cdc11a and Cdc11b complexes have differences in filament length and membrane-binding ability. Thus, septin subunit composition has functional consequences on filament properties and cell morphogenesis. Small sequence differences elicit distinct biophysical properties and cell functions of septins, illuminating how gene duplication could be a driving force for septin gene expansions seen throughout the tree of life.
TL;DR: StableMARK (Stable Microtubule-Associated Rigor-Kinesin) as mentioned in this paper is a live-cell marker to visualize stable microtubule (MT) cytoskeleton with high spatiotemporal resolution.
Abstract: The microtubule (MT) cytoskeleton underlies processes such as intracellular transport and cell division. Immunolabeling for posttranslational modifications of tubulin has revealed the presence of different MT subsets, which are believed to differ in stability and function. Whereas dynamic MTs can readily be studied using live-cell plus-end markers, the dynamics of stable MTs have remained obscure due to a lack of tools to directly visualize these MTs in living cells. Here, we present StableMARK (Stable Microtubule-Associated Rigor-Kinesin), a live-cell marker to visualize stable MTs with high spatiotemporal resolution. We demonstrate that a rigor mutant of Kinesin-1 selectively binds to stable MTs without affecting MT organization and organelle transport. These MTs are long-lived, undergo continuous remodeling, and often do not depolymerize upon laser-based severing. Using this marker, we could visualize the spatiotemporal regulation of MT stability before, during, and after cell division. Thus, this live-cell marker enables the exploration of different MT subsets and how they contribute to cellular organization and transport.
TL;DR: In this article , the transmembrane protein KASH5 is shown to be an activating adaptor for dynein and shed light on the hierarchy of assembly of kASH5-dynein-dynactin complexes.
Abstract: Cytoplasmic dynein-driven movement of chromosomes during prophase I of mammalian meiosis is essential for synapsis and genetic exchange. Dynein connects to chromosome telomeres via KASH5 and SUN1 or SUN2, which together span the nuclear envelope. Here, we show that KASH5 promotes dynein motility in vitro, and cytosolic KASH5 inhibits dynein's interphase functions. KASH5 interacts with a dynein light intermediate chain (DYNC1LI1 or DYNC1LI2) via a conserved helix in the LIC C-terminal, and this region is also needed for dynein's recruitment to other cellular membranes. KASH5's N-terminal EF-hands are essential as the interaction with dynein is disrupted by mutation of key calcium-binding residues, although it is not regulated by cellular calcium levels. Dynein can be recruited to KASH5 at the nuclear envelope independently of dynactin, while LIS1 is essential for dynactin incorporation into the KASH5-dynein complex. Altogether, we show that the transmembrane protein KASH5 is an activating adaptor for dynein and shed light on the hierarchy of assembly of KASH5-dynein-dynactin complexes.
TL;DR: In this article, actin-bundler PLS3 mediates correct surface translocation of the neurotrophin receptor TrkB and proper "cluster-like" formations of voltage-gated Ca2+ channels.
Abstract: Hennlein et al. show a novel role of the actin-bundler PLS3 that mediates correct surface translocation of the neurotrophin receptor TrkB and proper "cluster-like" formations of voltage-gated Ca2+ channels as processes that are indispensable for development and functional maintenance of motoneurons.
TL;DR: In this article , the authors used mutagenesis and site-specific crosslinking to map the path of a tail-anchored (TA) protein from its cytosolic capture by methionine-rich loops to its membrane insertion through a hydrophilic vestibule.
Abstract: Tail-anchored (TA) proteins play essential roles in mammalian cells, and their accurate localization is critical for proteostasis. Biophysical similarities lead to mistargeting of mitochondrial TA proteins to the ER, where they are delivered to the insertase, the ER membrane protein complex (EMC). Leveraging an improved structural model of the human EMC, we used mutagenesis and site-specific crosslinking to map the path of a TA protein from its cytosolic capture by methionine-rich loops to its membrane insertion through a hydrophilic vestibule. Positively charged residues at the entrance to the vestibule function as a selectivity filter that uses charge-repulsion to reject mitochondrial TA proteins. Similarly, this selectivity filter retains the positively charged soluble domains of multipass substrates in the cytosol, thereby ensuring they adopt the correct topology and enforcing the "positive-inside" rule. Substrate discrimination by the EMC provides a biochemical explanation for one role of charge in TA protein sorting and protects compartment integrity by limiting protein misinsertion.
TL;DR: In this article , the authors used budding yeast as a model to investigate how competition for the barbed ends of actin filaments might influence this process, and found that while vertebrate capping protein (CapZ) and formins can simultaneously associate with barbed end and catalyze each other's displacement, yeast capping proteins (Cap1/2) poorly displaces both yeast and vertebrate formins.
Abstract: How cells simultaneously assemble actin structures of distinct sizes, shapes, and filamentous architectures is still not well understood. Here, we used budding yeast as a model to investigate how competition for the barbed ends of actin filaments might influence this process. We found that while vertebrate capping protein (CapZ) and formins can simultaneously associate with barbed ends and catalyze each other's displacement, yeast capping protein (Cap1/2) poorly displaces both yeast and vertebrate formins. Consistent with these biochemical differences, in vivo formin-mediated actin cable assembly was strongly attenuated by the overexpression of CapZ but not Cap1/2. Multiwavelength live cell imaging further revealed that actin patches in cap2∆ cells acquire cable-like features over time, including recruitment of formins and tropomyosin. Together, our results suggest that the activities of S. cerevisiae Cap1/2 have been tuned across evolution to allow robust cable assembly by formins in the presence of high cytosolic levels of Cap1/2, which conversely limit patch growth and shield patches from formins.