Volume 7, Issue 6, Pages (June 2014)

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Volume 7, Issue 6, Pages 1026-1040 (June 2014) Homotypic Vacuole Fusion Requires VTI11 and Is Regulated by Phosphoinositides  Zheng Jiameng , Han Sang Won , Rodriguez-Welsh Maria Fernanda , Rojas-Pierce Marcela   Molecular Plant  Volume 7, Issue 6, Pages 1026-1040 (June 2014) DOI: 10.1093/mp/ssu019 Copyright © 2014 The Authors. All rights reserved. Terms and Conditions

Figure 1 itt3 Mutants Have Multiple Vacuoles per Cell in Various Cell Types. (A–F) Seedling vacuole morphology of the parental control (GFP–TIP2;1, (A, C, E)) or itt3 mutants (B, D, F). Three-day-old seedlings were imaged by confocal microscopy to visualize vacuoles in root cells (A, B), hypocotyls (C, D), and cotyledons (E, F). Note the multiple vacuoles in roots and hypocotyls in itt3 (B, D). (G, H) Hypocotyl cells from mature embryos from the parental line (GFP–TIP2;1, (G)) and itt3 mutants (H) were imaged to visualize the morphology of PSVs. Images show the autofluorescent signal from PSVs. Scale bar: 20 μm Molecular Plant 2014 7, 1026-1040DOI: (10.1093/mp/ssu019) Copyright © 2014 The Authors. All rights reserved. Terms and Conditions

Figure 2 itt3 Is a Mutant Allele of VTI11. (A) Schematic structure of the VTI11 locus indicating the positions of itt3 and zig-1 mutations. (B)zig-1 seedlings were stained with FM4-64 for 3h to label the vacuole membrane. Multiple vacuoles per cell were observed in zig-1 roots. (C) Complementation test between itt3 and zig-1 mutant alleles. F1 plants from a cross between zig-1 and itt3 GFP–TIP2;1 (zig1/itt3 GFP–TIP2;1/+) display the multiple-vacuole morphology of the single mutants. (D) Volume rendering of itt3 vacuoles from z-stacks of GFP–TIP2;1 fluorescence. (E) Volume rendering of zig1 vacuoles from z-stacks of BCECF-labeled vacuoles (green). Scale bar: 20 μm. Molecular Plant 2014 7, 1026-1040DOI: (10.1093/mp/ssu019) Copyright © 2014 The Authors. All rights reserved. Terms and Conditions

Figure 3 Wortmannin Rescues the itt3 Phenotype. (A) Parental control plants (GFP–TIP2;1) treated with DMSO for 2h. (B)itt3 mutants treated with DMSO for 2h. (C) Parental control plants (GFP–TIP2;1) treated with 33 μM Wm for 2h. (D)itt3 mutants treated with 33 μM Wm for 2h. Wm treatment of itt3 mutants resulted in a single large central vacuole. (E) Time-lapse microscopy of itt3 mutants treated with 33 μM Wm. Seedlings were incubated with Wm directly on the slide and images were captured over time. Arrows of the same color indicate membrane fusion events between two time points. Membrane fusion events can be detected as early as 10min. Scale bar: 20 μm. Molecular Plant 2014 7, 1026-1040DOI: (10.1093/mp/ssu019) Copyright © 2014 The Authors. All rights reserved. Terms and Conditions

Figure 4 LY294002 Induces Vacuole Fusion in itt3. (A) Parental control plants (GFP–TIP2;1) treated with 1% DMSO for 2h. (B)itt3 mutants treated with DMSO for 2h. (C) Parental control plants (GFP–TIP2;1) treated with 100 μM of LY294002 for 2h. (D)itt3 mutants treated with 100 μM of LY294002 for 2h. Scale bar: 20 μm. Molecular Plant 2014 7, 1026-1040DOI: (10.1093/mp/ssu019) Copyright © 2014 The Authors. All rights reserved. Terms and Conditions

Figure 5 PtdIns(3)P and PtdIns(4)P Counteract the Bioactivity of Wm for Vacuole Fusion. (A–C) Time-lapse imaging of Wm-induced fusions by epifluorescence microscopy. Four-day-old itt3 seedlings were pre-incubated in lipid carrier (A), carrier + PtdIns(3)P (B), or carrier + PtdIns(4)P (C) for 30min. Seedlings were then treated with 33 μM Wm and images were captured immediately after Wm treatment (0:00) and up to 30min (30:00). Scale bar: 20 μm. (D) Quantification of vacuole fusion events as a function of time. Plants were treated as in (A–C) with carrier only + Wm (black line), PtdIns(3)P + Wm (dashed red line), and PtdIns(4)P + Wm (dotted green line), and images were captured every 8 s. The effect of PtdIns(3)P or PtdIns(4)P alone is also shown. The Relative Vacuole Number per cell was calculated as the number of vacuoles at each time point relative to the number of vacuoles for that cell at the beginning of the experiment. Vacuoles were counted from images in which the focal point was around the medial section of each cell. N: 15–20 cells from at least three seedlings per treatment. Data points that were significantly different from the Wm control in a Student’s t-test are shown with asterisks in red (Wm + PtdIns(3)P) or green (Wm + PtdIns(4)P) (P < 0.05). Bars indicate standard error. Molecular Plant 2014 7, 1026-1040DOI: (10.1093/mp/ssu019) Copyright © 2014 The Authors. All rights reserved. Terms and Conditions

Figure 6 Microtubules and Microfilaments Are Required for Wm-Induced Vacuole Fusion. Four-day-old seedlings were pre-incubated in each inhibitor prior to addition of 33 μM Wm. Roots were imaged by confocal microscopy at 0, 30, and 60min after the addition of Wm. (A) Seedlings were pre-incubated in 1% DMSO (control). (B) Seedlings were pre-incubated in 20 μM Oryzalin. (C) Seedlings were pre-incubated in 50 μM Lantrunculin B (Lat-B). Asterisks indicate vacuoles that did not fuse up to 60min after Wm + inhibitor treatment. Scale bar: 20 μm. Molecular Plant 2014 7, 1026-1040DOI: (10.1093/mp/ssu019) Copyright © 2014 The Authors. All rights reserved. Terms and Conditions

Figure 7 PtdIns(3)P Regulates Vacuole Fusion in Guard Cells. (A–C) Wm treatment induced the fusion of guard cell vacuoles in closed stomata. Epidermal peels from Vicia faba were pre-incubated in stomata closing buffer containing ABA for 50min (A). Peels were then incubated in 1% DMSO (B) or 33 μM Wm (C) in the presence of acridine orange for 20min. The morphology of the vacuole was visualized by confocal microscopy (acridine orange), and guard cells were visualized in bright field. Merged images are also shown (right panels). (D) Peels were treated as in (A–C) with either 0, 1, 4, or 33 μM of Wm, and the number of vacuoles per cell was obtained from medial sections for each stomata. N: 100–150 guard cells per treatment. Standard error is shown. (E) Peels were treated as in (A–C) and stomata apertures were measured from medial sections. N: 50. (F–H) Guard cell vacuoles remain fragmented in vti11 mutant alleles under conditions that induce stomata opening. Epidermal peels from Col-0 wild-type (Col WT, F), itt3 (G), and zig1 (H) were incubated in the light in the presence of stomata opening buffer for 2h, and stained with acridine orange. (I)vti11 mutant alleles have defects in stomata opening. Stomata aperture was measured in Col wild-type (Col WT, black bars), itt3 (white bars), and zig1 (gray bars) epidermal peels after 0, 1, and 2h of stomata opening. Data represent 50–80 stomata and bars represent standard error. Data points that are significantly different from the DMSO control (D) or wild-type (I) in a Student’s t-test are shown with asterisks (* P < 0.01). Scale bar in (A–C): 10 μm; scale bar in (F–H): 5 μm. Molecular Plant 2014 7, 1026-1040DOI: (10.1093/mp/ssu019) Copyright © 2014 The Authors. All rights reserved. Terms and Conditions