Tonoplast%20and%20Vacuoles - PowerPoint PPT Presentation

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Tonoplast%20and%20Vacuoles

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Routes towards the vacuole. In all eukaryotes, the best described mechanism of exiting the ER is via coat protein complex (COP)II-coated vesicles. – PowerPoint PPT presentation

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Title: Tonoplast%20and%20Vacuoles


1
Tonoplast and Vacuoles
  • presented by Tatiana Eremeeva

2
Content
  • Vacuoles. Functions and types.
  • Vacuole biogenesis.
  • Routes towards the vacuole.
  • Tonoplast.
  • Transport processes across the tonoplast.
  • Autophagy and monitoring methods.

3
Vacuoles
- (coined from vacuum) fluid-filled
compartments encompassed by a membrane called
tonoplast.
10 - Vacuole
4
Plant vacuoles are multifunctional compartments
  • Storage (proteins, amino acids and organic
    acids, ions, sugars, pigments)
  • Digestion (acid hydrolases proteases,
    nucleases, glycosidases, lipases)
  • pH and ionic homeostasis (serve as reservoirs of
    protons and metabolically important ions)
  • Defense against microbial pathogens and
    herbivores (cell wall-degrading enzymes, phenolic
    compounds, alkaloids, etc.)
  • Sequestration of toxic compounds
  • Pigmentation

5
Plants use vacuoles to produce large cells
cheaply
  • By filling a large volume of the cell with
    inexpensive vacuolar contents plants are able
    to reduce the cost of making expanded structures
    such as leaves, which are essentially solar
    collectors.
  • The water taken into vacuoles generates turgor
    pressure which expands the primary cell wall and
    creates stiff structures in conjunction with the
    walls.

6
Types of vacuoles
Two types of vacuoles are depicted large
protein storage vacuoles (V1) and smaller
lytic/autophagic-type vacuoles (V2) that may be
involved in autophagy-associated programmed cell
death.
BiochemistryMolecular Biology of Plants/edited
by Buchmann B., Gruissem W., Russel L.J.
7
Routes towards the vacuole
  • In all eukaryotes, the best described mechanism
    of exiting the ER is via coat protein complex
    (COP)II-coated vesicles. The vacuole, together
    with the plasma membrane, is the most distal
    point of the secretory pathway, and many vacuolar
    proteins are transported from the ER through
    intermediate compartments.
  • However, past results demonstrate the presence of
    alternative transport routes from the ER towards
    the tonoplast, which are independent of Golgi-
    and post-Golgi trafficking. Moreover, the
    transport mechanism of the vacuolar proton pumps
    challenges the current model of vacuole
    biogenesis, pointing to the ER for being the main
    membrane source for the biogenesis of the plant
    lytic compartment.

8
Vacuole biogenesis
Corrado Vioti, ER and vacuoles never been closer
(pages 1-5), February 2014
Model for lytic vacuole biogenesis in
Arabidopsis.
9
Routes towards the vacuole
Comparison of different pathways for the delivery
of storage proteins to vacuoles. A
Goldgi-mediated pathway for the delivery of
storage proteins to protein storage vacuoles
(PSVs) B - Goldgi-mediated pathway in which CCVs
bud off the TGN and transfer proteins to the
prevacuolar compartment (PVC) before transport to
the lytic vacuole C ER-derived protein bodies
filled with prolamins are autophaged by vacuoles.
BiochemistryMolecular Biology of Plants/edited
by Buchmann B., Gruissem W., Russel L.J.
10
Tonoplast
  • - the membrane delimiting plant vacuoles,
    regulates ion, water and nutrient movement
    between the cytosol and the vacuolar lumen
    through the activity of its membrane proteins.
  • The relative abundance of these proteins and
    their respective activities/regulation determine
    the specific function of plant vacuoles.

11
Transport processes across the tonoplast
  • The regulation of solute passage across the
    tonoplast can be achieved by modified expression
    of genes encoding tonoplast proteins. However,
    also post-translational modifications of
    tonoplast proteins represent a fundamental
    principle in vacular transport regulation and
    adaptation.
  • Direct post-translational modifications of the
    protein allow faster adaptation of protein.
    Reversible protein phosphorylation by specific
    protein kinases/phosphatases is a very common
    post-translational modification.

H. Ekkehard, O. Trentmann, Regulation of
transport processes across the tonoplast,
September 2014
Schematic drawing illustrating the current
knowledge on how tonoplast monosaccharide
transporters (TMTs) are regulated at the
post-translational level.
12
Autophagy
  • is a degradation pathway that recycles cell
    materials upon stress conditions or during
    specific developmental processes (in the lysosome
    for mammals or in the vacuole for yeast and
    plants).

13
Assessment of Autophagy MonitoringMethods
  • Model for monitoring autophagy in planta -
    Arabidopsis thaliana roots.
  • Conditions - carbon- and nitrogen-starvation.
  • Goal evaluate monitoring methods
  • Green fluorescent protein (GFP)ATG8 fusion
    protein.
  • ATG8 (autophagy-related) protein which is
  • anchored to the autophagosomal membrane, a good
    marker for the observation of autophagosome
  • movements.
  • Monodansylcadaverine (MDC) - acidotropic
    fluorescent dye
  • 3. LysoTracker Red (LTR) - acidotropic
    fluorescent dye

14
Kinetics of autophagic activity can be
monitoredin planta using GFPATG8 transgenic
Arabidopsis
A.Merkulova, A. Guiboileau, Assessment and
Optimization of Autophagy Monitoring Methods in
Arabidopsis Roots Indicate Direct Fusion of
Autophagosomes with Vacuoles (pages 715-725),
February 2014
Monitoring of the induction of autophagy by
GFPATG8 fusion protein in Arabidopsis roots.
Behavior of autophagosomal structures and
pre-autophagosomal structures (PAS) revealed by
GFPATG8 during 24 h of carbon and nitrogen
starvation in Arabidopsis.
15
Kinetics of autophagic activity can be
monitoredin planta using GFPATG8 transgenic
Arabidopsis
  • Autophagy is inhibited by wortmannin treatment in
    Arabidopsis roots. White arrowheads in (B)
    indicate small dot structures, which are putative
    pre-autophagosomal structures.
  • The high level of fluorescence observed at the
    interstices of root cells in (B) indicates the
    area of cytoplasm, which is enlarged, probably
    because the size of the central vacuoles is
    reduced after the action of wortmannin.

A.Merkulova, A. Guiboileau, Assessment and
Optimization of Autophagy Monitoring Methods in
Arabidopsis Roots Indicate Direct Fusion of
Autophagosomes with Vacuoles (pages 715-725),
February 2014
16
Result of Assessment of Autophagy Monitoring
Methods
  • The GFPATG8 transgenic line constitutes an
    excellent method for monitoring autophagy.
  • These data were compared with plants stained with
    MDC and LTR. There was no appreciable MDC/LTR
    staining of small organelles in the root under
    the induction of autophagy. Extreme caution
    should therefore be used when monitoring
    autophagy with the aid of MDC/LTR.

17
Thank you for attention!
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