Post on 21-Jan-2016
Diameter of the Earth = 13,000 km
From 「みずものがたり」 (Mizu-monogatari, in Japanese)
Advances in Plant Stress #6Topic in water stress regulation in plant
(Earth water globe)
(salt water)
(fresh water)
(ice)
(ground water)
(lakes)
(soil water)
(rivers)
Mainly used this only 0.01%
Water stress
• Global shortage of available water and drought
• Osmotic aspect of salinity stress• Molecular mechanism of water
transport: Aquaporins
You can download this presentation (pptx-file) from the site:http://www.rib.okayama-u.ac.jp/MolecularPhysiology/katsuhara/katu_e.html
Global water crises
Water demand and use form
http://www.unep.org/dewa/vitalwater/article43.html
Global water crises • Increase of population
and social development
• Shortage of water for life and agriculture
• Water pollution (Less quality)
• Population in flood area
Scientific AmericanAugust, 2008
In this issue, it was mentioned that “10% reduction of irrigation water saves water more than all other uses”
Canal for agriculture
Shrink of Aral Sea(Central Asia)
60 Km
朝日放送(テレビ朝日系) 2008 年 3 月 9日放送
http://kobajun.chips.jp/wp-content/uploads/022702.jpg
Map: The Shrinking Ogallala Aquifer
http://www.circleofblue.org/waternews/2014/world/map-shrinking-ogallala-aquifer-1950-2011/
Even Without a Drought, We’re Depleting Groundwater at an Alarming Pace
http://modernfarmer.com/2015/07/ogallala-aquifer-depletion/
No more ground water until 2050
Over 1 billion people live in areas where groundwater is disappearing faster than it can be replenished.http://inhabitat.com/new-study-finds-groundwater-demand-outstrips-supply-for-over-1-billion-people/
http://sanfrancisco.cbslocal.com/photo-galleries/2015/04/09/california-drought-2015/
California Drought
http://www.agweb.com/blog/Know_Your_Market_281/drought_concerns_mounting_in_new_zealand_and_california_/
from Global Risk Report (January 15, 2015) http://www.weforum.org/reports/global-risks-report-2015
World Economic Forum
By Dr. Richard Errett Smalley (2003 ) Novel Prize, Chemistry 1996
A Puzzle for the Planet
Scientific American 312, 62 - 67 (2015)
The world is trying to improve energy, water and food supplies individually, but the challenges need to be solved in one integrated manner. That approach will also benefit the environment, poverty, population growth and disease.
• Plant scientists can contribute to the solution to this global water crisis and food production via crops requiring less water.
• 10% reduction of irrigation water saves more than all others( Scientific American 2008, previous issue)
Water
Earth scienceEnvironmental science
Social, economic,
political science
Engineering
Plant and agricultural science
Salinity and water stress
From “The use of saline waters for crop production” FAO paper 48 (1992)
Salt-affected land
Dry landSaline soil
Saline soil distribution overlaps with dry land
Bad water (saline water)
Death Valley (USA)
High evaporation → Drought ↓Salt remains → Salt stress
Water with high salt
Sanyo NewspaperApr. 3, 2011
Tsunamai
MineralWater Na+↑
Mineral
Water↓
Na+
Water(Dehydration)
• Arid and semi-arid area <dry land> (high evaporation)
• Coastal area (sea water)• Underground salt
New South Wales (Australia)
Raising saline ground water
We must manage water use adequately.
Can We Feed the World & Sustain the Planet? Scientific American 2011 日本語版日経サイエンス 2012年3月号「人口70億人時代の食糧戦略」
The world must solve three food problems simultaneously: end hunger, double food production by 2050, and do both while drastically reducing agriculture's damage to the environment.
http://www.nature.com/scientificamerican/journal/v305/n5/full/scientificamerican1111-60.html
Can We Feed the World & Sustain the Planet? Scientific American 2011 日本語版日経サイエンス 2012年3月号「人口70億人時代の食糧戦略」
http://www.nature.com/scientificamerican/journal/v305/n5/full/scientificamerican1111-60.html
Five solutions, pursued together, can achieve these goals: (1) stop agriculture from consuming more tropical land, (2) boost the productivity of farms that have the lowest yields, (3) raise the efficiency of water and fertilizer use worldwide, (4) reduce per capita meat consumption and (5) reduce waste in food production and distribution.
Approach from Plant Science Drought/salt tolerance (efficient/less water usage)
Mechanism of water uptake/transport
Salinity stress
Osmotic stressIonic stress(K+ deficiency / excess Na+ influx)
Inhibitions of: water uptakecell elongationleaf development
Dehydration
Recovery/Adaptation
Ion homeostasisNa+ extrusion/compartmentation/K+ reabsorption
Osmotic adjustmentAccumulations of ions/solutes/organic compounds
<Signal transduction>
(Cell death)
Inhibitions of: photosynthesisprotein synthesisenzyme activity
Na+ toxicity
A schematic summary of the stresses that plants suffer and resultant responses of plants to detrimental effects for survival under drought and high salinity.
Drought stress
Aquaporin
Molecular transport of water transport ・・・ depends on water potential
deference“Water potential” mainly consists in
“concentration” and “presser”
「 Semi-permeable membrane 」Water can pass but solute (M) cannnot
Power of Swelling
Physical presser need to stop swelling ( P)
Physical static presser :「 Presser potential 」 ψp
・・・” osmotic presser” ( proposal to concentration )⇒ 「 Osmotic potentail 」 ψosm
minus (osmotic pressure)
Why minuis ? ψp + ψosm =0 ( balance drnamic equation )
MWater molecule
P
P
ψosm: -0.1 > -0.5(MPa)
Water moves from high ψw to low ψw
ψp: 0 < 0.4(MPa)
Water potential ψw = ψosm + ψp
ψ1 ψ2
Water movement
This is “Turgor” in plant cells 1 MPa ≈ 0.4 mol/litter ≈ 10 atm (気圧)
ψosm -0.1 > -0.5ψp 0 < 0.4
ψ -0.1 = -0.1
(ψ1 = ψ2)
+
+ ・・・
P
ψ1 ψ2ψ1 ψ2
Animal cells Plant cells(View from water potential)
細胞膜 Plasma-membrane 細胞壁 Cell wall
• Inner ψosm = Outer ψosm• Inner ψw = Outer ψw
• Inner ψosm ≠ Outer ψosm• Presser at call wall• Inner ψw = Outer ψw
At low water potential of soil (drought/ salt stress)
Water potential
- 0 pure water
Wet
Soil Root
Weak drought/salt stress
soil Root
Strong drought/salt stress
soil Root
Osmotic adjustment= reduce cellular ψw
= reduce cellular ψosm
= increase osmotic presser
ψw
Water potential soil Root Soil root
ψw
Dehydration
Compatible solute → (osmtic compounds)
• Increase osmotic presser• Chaperon activity• Scavenging activity
Betaines: tri-methyl amino acidsH3N+- → (CH3)3N+-
Proline:
Example;Tobacco cells under salt stress
At low water potential of soil (drought/ salt stress)
Water potential
- 0 pure water
Wet
Soil Root
Weak drought/salt stress
soil Root
Strong drought/salt stress
soil Root
Osmotic adjustment= reduce cellular ψw
= reduce cellular ψosm
= increase osmotic presser
ψw
Water potential soil Root Soil root
ψw
PreventIncrease
permeability
Water uptake ( movement/flux ):
Water flux* = Driving force×water permeability ( 駆動力) (水の動きやすさ:透過性)( *per unit time )
Driving force:Water potential difference ( Dam: gravity potential )In plant, mainly,
Difference of ψosm
Permeability/conductance:( Dam: opening of gate )In plant, mainly,
Activity of aquaporins
Water uptake ( movement/flux ):
Water flux* = Driving force×water permeability ( 駆動力) (水の動きやすさ:透過性)
Water potential difference
Surface area×Water permeability per unit area (表面積) (面積当たりの水透過性)
Aquaporin determins this• All bacteria, animal and plants• Membrane proetin with about 300 amino acids• Two Asn-Pro-Ala motif
( *per unit time )
Symplastic pathApoplastic path
Aquaporins are required for water across the membrane via symplastic path
Soil water
root
casparian stripe (not permeable)
xylem
Water is most abundantly used in cells.Aquaporin is a water transporter. → Aquaporins regulate largest transport.
Regulation by; humiditiy, salt stress, light, temeperature, others
LocalizationPlasmamembrane ( PIP)Tonolast membrane(TIP)Peribacteroid memebrane or plasamamembrane (NIP)ER membrane (SIP)
Gene family: >30 genesSubstrates: H2O 、 CO2 、 H2O2, B ・・・)
aquaporinaquaporin
生体膜
Output; Stress tolerance, growth regulation, Post-harvesting…
Regulatory regions
Aquaporins ; 1) increase membrane water
permeability2) make it possible to regulate
water permeability
Structure in the membrane
Open/closeIntracellular trafficking
Murata at al. (2000) Nature 407:599
Prof. Peter AgreNovel prize (Chemistry) "for the discovery of water channels" (2003)
Discovery; 1992
Before discovery of aquaporins ?
After all, the message that appeared in textbooks was that water simply diffused "somehow'' across plants membrane and proteins were not involved in these processes.
Biophysicists continued to use pore models to explain membrane permeations without seeking a molecular explanation.
A.R.Schaffner Planta 204:131-139 (1998)
H2O
原形質膜(細胞膜)Plasma-membraene
液胞膜Tonoplast
( Functional)Cell water permeability ↓Higher than lipid bilayer ↓Water channels suggested
( Biochemical )Abundant protein that function is unknown
CHIP28
PM28
( Molecular genetics )Major Intrinsic Protein (MIP) in eyes
E.Coli glycerol transporter
( GlpF)
Aquaporin
Prof. Peter AgreNovel prize (Chemistry) "for the discovery of water channels"
Molecular structure of an aquaporin
Tameshite-Gatten 2007 May, 9
Plant aquaporins
PIP(plasm-membrane…)
(原形質膜型)TIP(tonoplast….)
(液胞膜型)NIP(Nodulin26-like…)
SIP(small …) ER signaling?
XIP(x …)
Aquaporin = MIP (membrane intrinsic protein)
XIPs are found in some plants (tomato, cotton, moss) but functions are not yet known
35 Major Intrinsic Protein in Arabidopsis
13 genes in human, and 1-2 genes in bacteria
Rice aquaporins
0.1
OsNIP2;2
OsNIP3;1
OsNIP3;2
OsNIP3;3
NIPNodulin 26-like Intrinsic Protein
OsPIP2;7
PIP
Plasma membrane Intrinsic Protein
OsTIP3;1
OsTIP3;2
OsTIP4;1
OsTIP4;2
OsTIP4;3
TIPTonoplast Intrinsic Protein
OsSIP1;1
OsSIP2;1
SIPSmall basic Intrinsic Protein
33 genes in rice( PCP Ishikawa et al. 46 : 568 (2005) Individual function
RedundancyPhenotype/mutant?
Experimental difficulty
LocalizationStress responseSubstrate
Why many in plants?
H2O2 [ OsZmPIP2;5, HvPIP2;5 ] Si(OH)4 /As(OH)4
[ OsNIP2;1 ] B(OH)3 [ AtNIP5;1 ]
High permeability: maintain cytoplasmTIP aquaporins
Determining cell water permeabilityPIP aquaporins
N
Vacuole(More than 90% volume)
Plasma-mambrane Cell wall
細胞質( cytoplasm )
External (soil) w
ater variable
•Wet•Dry•Salt stress
air N2
Peribacteroid membrane
N-fixing bacteria窒素固定菌
N2 → NH3 H2O
Legum
inos root cells NOD26( NIP-type aquaporin )
Relation to N2-fixation, too(Tyerman et al. )
Aquaporins under osmotic (drought and salt) stresses
H2O
脱水Dehydration
aquaporin
Plasma membrane
- 20
0
20
40
60
80
100
120
0 100 200 300 400
NaCl (mM)
Re
lative
gro
wth
(%
)
吸水低下Reduction of water uptake
barley
H2O
Stress ・・・ dehydration
aquaporinPlasmamembrane
• Short term responseInactivation via dephosphorylation and internalization
• Middle term responseSuppression of aquaporin expression → Root water permeability reduction
• Long term reactionOsmotic adjustment to re-establishment of motive forceExpression of aquaporin again
PP
Trafficking/recycling regulation
Chevaliiner et al. PCP 56:819 (2015)
Salt stress ↓H2O2 as signal ↓Trafficking
Internalization of fluorescence after H2O2
Boursiac et al. Plant J. (2008) 56, 207–218
H2O
Salt stress
Transientadaptation
Over-expression
Osmoticadjustment
aquaporinPM
Katsuhara et al.Plant Cell Physiol.(2003)44:1378-1383
over-expression
Low minerals (Carvajal )aquaporin expression ↓
→ root water permeability ↓
→ shoot growth ↓
Leaf movements (Moshelion )
Day : Aquaporin amount/activity ↑
→ water influx ↑ → Leaf open
Night) : Aquaporin amount/activity↓
→ Dehydration → Leaf close
Many physiological reactions elated to aquaporins
Opening tulip flower (Azad ) • Low temp→high temp, then opening• Flower cells (lower part) uptake water• PIPs express constantly• TgPIP2;2 activation by phosphorylation under Low
temp→high temp
Fruit enlargement ( Shiratake )
• Initial ・・・ cell division• Middle ~ Later cell elongation by water
uptakeTIPs ・・・ regulation of expressionPIPs ・・・ constant expression regulation via phosphorylation
From aquaporin research…
• High quality flowers and fruits
CO2↑
H2O↑
• Drought/salt tolerant crops
• High water usage crops• High CO2 fixing plants
(We are investigation some CO2-permeable aquaporins)