Plant water regime - PowerPoint PPT Presentation

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Plant water regime

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... Orchidaceae) Plant water regime Transport of liquid water Transport of water across membranes Absorption of water by roots Radial transport of water in roots ... – PowerPoint PPT presentation

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Title: Plant water regime


1
Plant water regime
  • Transport of liquid water
  • Transport of water across membranes
  • Absorption of water by roots
  • Radial transport of water in roots
  • Root pressure
  • Absorption of water by shoots

2
Basic characteristics of water transport on
cellular level
  • Transport of liquid water across membrane
  • (plasmalemma, tonoplast, organelle membranes)
  • Jw Lp ??w Lp (??p ???s)
  • Jw - membrane water transport rate, Lp - membrane
    water permeability,
  • ??w - water potential difference, ??p - pressure
    potential difference,
  • ? - reflection coefficient, ??s - osmotic
    potential difference between two membrane sites

3
Coupling of water and solute flow
  • Thermodynamic of irreversible processes, equation
    for water and single solute flow
  • Jw Lw??w Lws??s
  • Js Ls??s Lsw??w
  • Jw - transport of water, Js - transport of
    solute, ??w - gradient of chemical potential of
    water, ??s - gradient of chemical potential of
    solute, Lw, Ls - membrane permeability for water
    and solute, respectively, Lws Lsw (Onsager
    reciprocity coefficients)

4
Interactions between water and solute during
membrane transport
5
Membranes, aquaporins
  • Membrane phospholipid bilayer (transport of O2,
    CO2) transmembrane proteins (transport of
    water, ions including protons, some hydrophylic
    organic substances) diffusion and active
    transport (ATPase, carriers, antiport, symport)
  • Aquaporins belongs into "major intrinsic
    proteins" (MIP) 25 - 30 kDa
  • tonoplast intrinsic proteins (TIP), plasmalemma
    intrinsic proteins (PIP)
  • passive transport in both directions, water
    permeability 10 to 100 times higher than that of
    phospholipid bilayer widespread occurrence, high
    heterogeneity inside plant and among plant
    species (Arabidopsis 35 TIP or PIP genes)

6
Aquaporins
7
Aquaporins
(Luu and Maurel 2005)
8
Aquaporins
  • Regulation of water transport by changes in
    occurrence (gene expression) or by changes in
    permeability
  • phosphorylation increases permeability,
    dephosphorylation decreases permeability
  • Ca2
  • Na, Cl-
  • lack of O2, ROS
  • water stres, ABA
  • circadial rhythm
  • different selectivity
  • Importance for water redistribution inside cells
    (much more TIP than PIP), and rapid transport
    between neighbouring cells (stomata, motoric
    cells, elongation growth, under decreased
    apoplast transport)

9
Water uptake
  • Jw Lsr ??w
  • Jw - absorption rate, Lsr - conductance in the
    soil-root boundary, ??w - difference in water
    potential between soil and root
  • Ma A Lsr ??w
  • Ma - amount of water absorbed by the roots, A -
    exchange area of absorption zone
  • Availability of soil water is dependent on
    amount of water, amount of solutes, (osmotic
    potential of soil solution), size of capillary
    pores (matric potential of soil).

10
Adaptations of roots for sufficient water uptake
  • Hydrotropic growth slower growth on the side
    where is higher soil moisture and more rapid
    growth on the opposite side.
  • Root distribution species specific (shallow,
    deep, or multilayer root system)
  • Anatomical adaptations endodermis, exodermis,
    etc.
  • Physiological adaptations e.g. osmotic
    adjustment
  • Soil water potential is mostly less negative than
    root water potential, but under special
    conditions it might be more negative (transport
    of water from plant to soil).
  • Plant - lift for water

11
Root morphology and anatomy
  • Most rapid absorption is in the apical part of
    the root (5 - 10 cm) where is the highest
    occurrence of root hairs.
  • Number of root hairs is huge, their longevity
    short (max. several weeks). They increase
    absorption area considerably.
  • Water absorption by older (suberized) root parts
    is much slower. Nevertheless, due to large area
    the amount of water might be about 30 .
  • Arbuscular mycorrhiza or ectomycorrhiza
  • Great variability in root anatomy

12
Radial water transport in root
  • Three pathways
  • apoplast (cell walls, intercellular spaces)
  • symplast (cell protoplasm connected by
    plasmodesmas)
  • across cells
  • In water transport (Jr), both the gradient of
    pressure potential (??p) and the gradient of
    osmotic potential (??s) take part, their
    importance is dependent on transport pathway and
    transpiration rate.
  • Jr Lr ??w Lr (??p ???s)
  • Lr - root conductance, ? - reflection coefficient

13
Water transport pathways
14
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15
Transport pathways
  • Apoplastic pathway - under high ??p and high
    transpiration rate, its conductance is high,
    reflection coefficient is low (mass flow of water
    and solutes), it is limited by endodermis and
    exodermis
  • Symplastic pathway across cells - ??s is
    important, reflection coefficient is high, its
    conductance is rather low and dependent on
    aquaporins, ABA, Ca2
  • Similar transport mechanism radial transport in
    stem, longitudinal transport in root and stem
    tissue with exception of vascular system,
    transport in leaf tissue
  • Transport of water is dependent on 1) morphology
    and anatomy, 2) transport mechanism 3)
    water-solute interactions, 4) activity of
    aquaporins

16
Root pressure
  • Under high soil moisture and high air humidity
    (low transpiration rate)
  • Important for vein filling in spring or after
    embolism
  • Gutation, exudation
  • Mechanism transport osmotically active compounds
    into xylem creates gradient of osmotic potential
    between xylem and root cells which is driving
    force for water transport into xylem

17
Model of radial transport of water and ions
18
Water uptake by shoot
  • The water source rain, dew, fog, air humidity
    near 100
  • Under rather low water potential in shoot,
    dependent also on leaf wettability
  • For plant water balance is usually more important
    limitation of transpiration than water uptake
  • Epiphytic plants (Bromeliaceae, Orchidaceae)
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