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1. Model-based inference of a dual role for HOPS in regulating guard cell vacuole fusion

   https://doi.org/10.1093/insilicoplants/diae015  

   Hodgens, Charles; Flaherty, D T; Pullen, Anne-Marie; Khan, Imran; English, Nolan J; Gillan, Lydia; Rojas-Pierce, Marcela; Akpa, Belinda S (August 2024, in silico Plants)

   Zhu, Xin-Guang (Ed.)

   Abstract Guard cell movements depend, in part, on the remodelling of vacuoles from a highly fragmented state to a fused morphology during stomata opening. Indeed, full opening of plant stomata requires vacuole fusion to occur. Fusion of vacuole membranes is a highly conserved process in eukaryotes, with key roles played by two multi-subunit complexes: HOPS (homotypic fusion and vacuolar protein sorting) and SNARE (soluble NSF attachment protein receptor). HOPS is a vacuole tethering factor that is thought to chaperone SNAREs from apposing vacuole membranes into a fusion-competent complex capable of rearranging membranes. In plants, recruitment of HOPS subunits to the tonoplast has been shown to require the presence of the phosphoinositide phosphatidylinositol 3-phosphate. However, chemically depleting this lipid induces vacuole fusion. To resolve this counter-intuitive observation regarding the role of HOPS in regulating plant vacuole morphology, we defined a quantitative model of vacuole fusion dynamics and used it to generate testable predictions about HOPS-SNARE interactions. We derived our model by using simulation-based inference to integrate prior knowledge about molecular interactions with limited, qualitative observations of emergent vacuole phenotypes. By constraining the model parameters to yield the emergent outcomes observed for stoma opening—as induced by two distinct chemical treatments—we predicted a dual role for HOPS and identified a stalled form of the SNARE complex that differs from phenomena reported in yeast. We predict that HOPS has contradictory actions at different points in the fusion signalling pathway, promoting the formation of SNARE complexes, but limiting their activity. 

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2. Sphingolipids containing very long-chain fatty acids regulate Ypt7 function during the tethering stage of vacuole fusion

   https://doi.org/10.1016/j.jbc.2024.107808  

   Zhang, Chi; Calderin, Jorge D; Hurst, Logan R; Gokbayrak, Zeynep D; Hrabak, Michael R; Balutowski, Adam; Rivera-Kohr, David A; Kazmirchuk, Thomas DD; Brett, Christopher L; Fratti, Rutilio A (November 2024, Journal of Biological Chemistry)

   Sphingolipids are essential in membrane trafficking and cellular homeostasis. Here, we show that sphingolipids containing very long-chain fatty acids (VLCFAs) promote homotypic vacuolar fusion in Saccharomyces cerevisiae. The elongase Elo3 adds the last two carbons to VLCFAs that are incorporated into sphingolipids. Cells lacking Elo3 have fragmented vacuoles, which is also seen when WT cells are treated with the sphingolipid synthesis inhibitor Aureobasidin-A. Isolated elo3Δ vacuoles show acidification defects and increased membrane fluidity, and this correlates with deficient fusion. Fusion arrest occurs at the tethering stage as elo3Δ vacuoles fail to cluster efficiently in vitro. Unlike HOPS and fusogenic lipids, GFP-Ypt7 does not enrich at elo3Δ vertex microdomains, a hallmark of vacuole docking prior to fusion. Pulldown assays using bacterially expressed GST-Ypt7 showed that HOPS from elo3Δ vacuole extracts failed to bind GST-Ypt7 while HOPS from WT extracts interacted strongly with GST-Ypt7. Treatment of WT vacuoles with the fluidizing anesthetic dibucaine recapitulates the elo3Δ phenotype and shows increased membrane fluidity, mislocalized GFP-Ypt7, inhibited fusion, and attenuated acidification. Together these data suggest that sphingolipids contribute to Rab-mediated tethering and docking required for vacuole fusion. 

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3. Data from: Regulation of vacuole fusion in stomata by dephosphorylation of the HOPS subunit VPS39

   https://doi.org/10.5061/dryad.905qftv05  

   Pullen, Anne-Marie; Billings, Grant; White, Giselle; Hodgens, Charles; Akpa, Belinda; Rojas-Pierce, Marcela (January 2025, Dryad)

   {"Abstract":["Understanding how plants regulate water loss is important for improving\n crop productivity. Tight control of stomatal opening and closing is\n essential for the uptake of CO2 while mitigating water vapor loss. The\n opening of stomata is regulated in part by homotypic vacuole fusion, which\n is mediated by conserved homotypic vacuole protein sorting (HOPS) and\n vacuolar SNARE (soluble N-ethylmaleimide sensitive factor attachment\n protein receptors) complexes. HOPS tethers apposing vacuole membranes and\n promotes the formation of trans-SNARE complexes to mediate fusion. In\n yeast, HOPS dissociates from the assembled SNARE complex to complete\n vacuole fusion, but little is known about this process in plants.\n HOPS-specific subunits VACUOLE PROTEIN SORTING39 (VPS39) and VPS41 are\n required for homotypic plant vacuole fusion, and a computational model\n predicted that post-translational modifications of HOPS may be needed for\n plant stomatal vacuole fusion. Here, we characterized a viable T-DNA\n insertion allele of VPS39 which demonstrated a critical role of VPS39 in\n stomatal vacuole fusion. We found that VPS39 has increased levels of\n phosphorylation at S413 when stomata are closed versus open, and that\n VPS39 function in stomata and embryonic development requires dynamic\n changes in phosphorylation. Among all HOPS and vacuolar SNARE subunits,\n only VPS39 showed differential levels of phosphorylation between open and\n closed stomata. Moreover, regions containing S413 are not conserved\n between plants and other organisms, suggesting plant-specific mechanisms.\n  Our data are consistent with VPS39 phosphorylation altering\n vacuole dynamics in response to environmental cues, similar to\n well-established phosphorylation cascades that regulate ion transport\n during stomatal opening."],"TechnicalInfo":["# Data from: Regulation of vacuole fusion in stomata by dephosphorylation\n of the HOPS subunit VPS39 --- The methods for this dataset are described\n in detail in our manuscript. These compressed files contain: Raw images\n (.czi) for vacuoles from roots (Root_vacuole_data.zip) used for Figure 1C.\n Raw images (.czi) for stomata vacuoles (Stomata_Vacuole_Data.zip) used for\n Figure 1D-E and Figure 3D-E. Images (.jpg) of siliques used for\n quantification of Figure 3A-C (Siliques_Data.tar). Genotypes associated\n with each plant number on each slide are listed in an Excel file. qRT-PCR\n data (.xlsx) from seedlings corresponding to Figure 1B\n (Seedling_qRT_PCR_vps39-2.xlsx). qRT-PCR data (.xlsx) from guard\n cell-enriched tissue corresponding to Figure 1F\n (Guard_Cell_enriched_RT_qPCR.xlsx). ## Description of the data and file\n structure ### **Root Vacuole image data files** This includes confocal raw\n image files captured with a Zeiss LSM980 with Airy scan microscope. Images\n are organized in folders by date of image acquisition (set 1 to set 6).\n Within each set, images are organized by genotype (WT,\n *vps39-2* or *vps39-2* VPS39-RFP/+). Each image includes green channel for\n BCECF fluorescence detection and red channel for VPS39-RFP detection. ###\n Stomata vacuole image data files This includes confocal raw image files\n captured with a Zeiss LSM980 with an Airy scan microscope. Data is\n organized in folders based on data of image acquisition. Each folder is\n subdivided by genotype: wild type (WT), *vps39-2*\n mutant, or *vps39-2* mutant complemented with VPS39-S-A-GFP (v*ps39-2*\n VPS39-S-A-GFP) or VPS39-S-D-GFP (v*ps39-2* VPS39-S-A-GFP). Within each\n genotype, images are sorted by box numbers, where each box corresponds to\n a leaf fragment from a different plant. ### **Silique image data** This\n contains all the images from siliques as captured with a Leica Thunder for\n Model Organisms dissecting scope. Images are organized in folders by date\n of data acquisition. Within each date, data is sorted by genotype. Within\n each genotype, each image includes multiple siliques from 1 or more\n plants. Each silique is marked with a genotype number as part of the\n image. An Excel sheet is included to match a plant number to a specific\n plant genotype for each image. ### **qRT-PCR files** These files contain\n raw data from gene expression studies. **Date (when included):** Date when\n qRT-PCR run was performed. **Well:** The plate position of the reaction on\n the qRT-PCR plate. **Fluor:** The fluorescence channel used for detection\n (SYBR GREEN was always used). **Target:** Specific gene transcript\n amplified for that reaction. **Content:** The reaction type as designated\n in the run file (e.g., Unknown sample, Standard, NTC, etc.). This labels\n the functional role of the well in the experiment, including NTC (no DNA\n Template Control) or NRT (no RT reaction) controls. This column was not\n specified for wells containing samples, and therefore, these were marked\n as "Unkn" by the qPCR machine. All other empty wells (not used)\n are marked as "Unkn". **Sample:** The sample ID corresponding to\n the biological sample loaded in the well. Genotypes used were either wild\n type (WT) or vps39-2 mutant (39). For each of these, biological replicates\n are indicated as A, B, C, and D, and technical replicates with numbers\n (1-4).  **Cq:** The quantification cycle (Ct) value is automatically\n calculated by the instrument. Empty cells indicate that no Ct value was\n generated due to an unused well. "N/A" indicates that no\n fluorescence was detected, and these cells correspond to non-template\n controls. Other cells left blank correspond to wells intentionally not\n used in the plate layout (no-template, no-primer, or unassigned wells).\n These were left blank because the instrument does not output data for\n unused wells."]} 

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4. Coordination and Crosstalk between Autophagosome and Multivesicular Body Pathways in Plant Stress Responses

   https://doi.org/10.3390/cells9010119  

   Wang, Mengxue; Li, Xifeng; Luo, Shuwei; Fan, Baofang; Zhu, Cheng; Chen, Zhixiang (January 2020, Cells)

   null (Ed.)

   In eukaryotic cells, autophagosomes and multivesicular bodies (MVBs) are two closely related partners in the lysosomal/vacuolar protein degradation system. Autophagosomes are double membrane-bound organelles that transport cytoplasmic components, including proteins and organelles for autophagic degradation in the lysosomes/vacuoles. MVBs are single-membrane organelles in the endocytic pathway that contain intraluminal vesicles whose content is either degraded in the lysosomes/vacuoles or recycled to the cell surface. In plants, both autophagosome and MVB pathways play important roles in plant responses to biotic and abiotic stresses. More recent studies have revealed that autophagosomes and MVBs also act together in plant stress responses in a variety of processes, including deployment of defense-related molecules, regulation of cell death, trafficking and degradation of membrane and soluble constituents, and modulation of plant hormone metabolism and signaling. In this review, we discuss these recent findings on the coordination and crosstalk between autophagosome and MVB pathways that contribute to the complex network of plant stress responses. 

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5. Yeast cells actively tune their membranes to phase separate at temperatures that scale with growth temperatures

   https://doi.org/10.1073/pnas.2116007119  

   Leveille, Chantelle L.; Cornell, Caitlin E.; Merz, Alexey J.; Keller, Sarah L. (January 2022, Proceedings of the National Academy of Sciences)

   Membranes of vacuoles, the lysosomal organelles of Saccharomyces cerevisiae (budding yeast), undergo extraordinary changes during the cell’s normal growth cycle. The cycle begins with a stage of rapid cell growth. Then, as glucose becomes scarce, growth slows, and vacuole membranes phase separate into micrometer-scale domains of two liquid phases. Recent studies suggest that these domains promote yeast survival by organizing membrane proteins that play key roles in a central signaling pathway conserved among eukaryotes (TORC1). An outstanding question in the field has been whether cells regulate phase transitions in response to new physical conditions and how this occurs. Here, we measure transition temperatures and find that after an increase of roughly 15 °C, vacuole membranes appear uniform, independent of growth temperature. Moreover, populations of cells grown at a single temperature regulate this transition to occur over a surprisingly narrow temperature range. Remarkably, the transition temperature scales linearly with the growth temperature, demonstrating that the cells physiologically adapt to maintain proximity to the transition. Next, we ask how yeast adjust their membranes to achieve phase separation. We isolate vacuoles from yeast during the rapid stage of growth, when their membranes do not natively exhibit domains. Ergosterol is the major sterol in yeast. We find that domains appear when ergosterol is depleted, contradicting the prevalent assumption that increases in sterol concentration generally cause membrane phase separation in vivo, but in agreement with previous studies using artificial and cell-derived membranes. 

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