1. Water uptake
Path starts at root hairs
Must take water from soil
Ease depends on availability & how tightly it is bound
Binding depends on particle size & chem

2. Water uptake
Availability depends on amount in soil pores
Saturation: completely full
Field capacity: amount left after gravity has drained excess
Permanent wilting point: amount where soil water potential is too negative for plants to take it up

3. Plant Stress
Water?
Nutrients?
Environment?
Temp?
Pollution?
Ozone, other gases?
Herbicides, eg Round-Up, Atrazine?
Insects and other herbivores?
Pathogens = bacteria, viruses, fungi
Salinity

4. Plant Stress
Next assignment: presenting a plant stressor, what is known about it, and why it might affect plant 2˚ compounds in an ~ 10 minute presentation?
Alternative: presenting another good plant/stressor response to study and why we should choose it over the ones already presented.

8. Mineral Nutrition
Nutrients in soil
Plants alter roots to aid uptake
Also use symbionts
Mycorrhizal fungi help: especially with P
Some plants form symbioses with N-fixing prok.

9. Nutrient uptake
Most nutrients are dissolved in water
Enter root through apoplast until hit endodermis
Then must cross plasma membrane

10. Nutrient uptake
Then must cross plasma membrane
Gases, small uncharged & non-polar molecules diffuse
down their ∆ [ ]
Important for CO2, auxin & NH3 transport

11. Selective Transport
1) Channels
integral membrane proteins with pore that specific ions diffuse through

12. Selective Transport
1) Channels
2) Facilitated Diffusion (carriers)
Carrier binds molecule

13. 4 classes of Active transport ATPase proteins
1) P-type ATPases (P = “phosphorylation”)
2) V-type ATPases (V = “vacuole”)
3) F-type ATPases (F = “factor”)
4) ABC ATPases (ABC = “ATP Binding Cassette”)
multidrug resistance proteins

14. Secondary active transport
Uses ∆ [ ] created by active transport to pump something else across a membrane against its ∆ [ ]

15. Nutrient uptake
Gases enter/exit by diffusion down their ∆ [ ]
Ions vary dramatically!

16. Nutrient uptake
Gases enter/exit by diffusion down their ∆ [ ]
Ions vary dramatically!
H+ is actively pumped out of cell by P-type H+ -ATPase

17. Nutrient uptake
Ions vary dramatically!
H+ is actively pumped out of cell by P-type H+ -ATPase
and into vacuole by V-type ATPase & PPase

18. Nutrient uptake
H+ is actively pumped out of cell by P-type H+ -ATPase
and into vacuole by V-type ATPase & PPase
Main way plants make membrane potential (∆Em)!

19. Nutrient uptake
H+ is actively pumped out of cell by P-type H+ -ATPase
and into vacuole by V-type ATPase & PPase
Main way plants make membrane potential (∆Em)!
Used for many kinds of transport!

20. Nutrient uptake
Many ions are imported by multiple transporters with varying affinities

21. Nutrient uptake
Many ions are imported by multiple transporters with varying affinities
K+ diffuses through channels down ∆Em: low affinity

22. Nutrient uptake
Many ions are imported by multiple transporters with varying affinities
K+ diffuses through channels down ∆Em: low affinity
Also taken up by H+ symporters : high affinity

23. Nutrient uptake
Many ions are imported by multiple transporters with varying affinities
K+ diffuses through channels down ∆Em: low affinity
Also taken up by H+ symporters : high affinity
Low affinity is cheaper
but less effective

24. Nutrient uptake
K+ diffuses through channels down ∆Em: low affinity
Also taken up by H+ symporters : high affinity
Low affinity is cheaper but less effective
some channels also transport Na+

25. Nutrient uptake
K+ diffuses through channels down ∆Em: low affinity
Also taken up by H+ symporters : high affinity
Low affinity is cheaper but less effective
some channels also transport Na+
why Na+ slows K+ uptake?

26. Nutrient uptake
K+ diffuses through channels down ∆Em: low affinity
Also taken up by H+ symporters : high affinity
Low affinity is cheaper but less effective
some channels also transport Na+
why Na+ slows K+ uptake?
Na+ is also expelled
by H+ antiport

27. Nutrient uptake
Na+ is also expelled
by H+ antiport
Enters through channels
Ca2+ is expelled by P-type
ATPases in PM

28. Nutrient uptake
Ca2+ is expelled by P-type ATPases in PM
& pumped into vacuole & ER by H+ antiport & P-type

29. Nutrient uptake
Ca2+ is expelled by P-type ATPases in PM
pumped into vacuole & ER by H+ antiport & P-type
enters cytosol via gated channels

30. Nutrient uptake
PO43-, SO42-, Cl- & NO3-
enter by H+ symport

31. Nutrient uptake
PO43-, SO42-, Cl- & NO3- enter by H+ symport
also have anion transporters of ABC type

32. Nutrient uptake
PO43-, SO42-, Cl- & NO3- enter by H+ symport
also have anion transporters of ABC type
and anion channels

33. Nutrient uptake
PO43-, SO42-, Cl- & NO3- enter by H+ symport
also have anion transporters of ABC type
and anion channels
Plants take up N many ways

34. Nutrient uptake
Plants take up N many ways: NO3- & NH4+ are main forms

35. Nutrient uptake
Plants take up N many other ways
NO3- also by channels
NH3 by diffusion
NH4+ by carriers

36. Nutrient uptake
Plants take up N many other ways
NO3- by channels
NH3 by diffusion
NH4+ by carriers
NH4+ by channels

37. Nutrient uptake
Plants take up N many other ways
3 families of H+ symporters take up amino acids

38. Nutrient uptake
Plants take up N many other ways
3 families of H+ symporters take up amino acids
Also have many peptide transporters
some take up di- & tri-
peptides by H+ symport

39. Nutrient uptake
Plants take up N many other ways
3 families of H+ symporters take up amino acids
Also have many peptide transporters
some take up di- & tri-
peptides by H+ symport
others take up tetra- &
penta-peptides by H+ symport

40. Nutrient uptake
Plants take up N many other ways
3 families of H+ symporters take up amino acids
Also have many peptide transporters
some take up di- & tri-
peptides by H+ symport
others take up tetra- &
penta-peptides by H+ symport
Also have ABC transporters
that import peptides

41. Nutrient uptake
Plants take up N many other ways
3 families of H+ symporters take up amino acids
Also have many peptide transporters
some take up di- & tri-
peptides by H+ symport
others take up tetra- &
penta-peptides by H+ symport
Also have ABC transporters
that import peptides
N is vital!
NO3- & NH4+ are main forms

42. Nutrient uptake
Metals are taken up by ZIP proteins & by ABC transporters
same protein may import Fe, Zn & Mn!

43. Nutrient uptake
Much is coupled to
pH gradient

44. Nutrient transport in roots
Move from soil to endodermis in apoplast

45. Nutrient transport in roots
Move from soil to endodermis in apoplast
Move from endodermis to xylem in symplast

46. Nutrient transport in roots
Move from endodermis to xylem in symplast
Transported into xylem by H+ antiporters

47. Nutrient transport in roots
Move from endodermis to xylem in symplast
Transported into xylem by H+ antiporters, channels

48. Nutrient transport in roots
Transported into xylem by H+ antiporters, channels,pumps

49. Nutrient transport in roots
Transported into xylem by H+ antiporters, channels,pumps
Lowers xylem water
potential -> root pressure

50. Water Transport
Passes water & nutrients to xylem
Ys of xylem makes root pressure
Causes guttation: pumping water into shoot

51. Transport to shoot
Nutrients move up
plant in xylem sap

52. Nutrient transport in leaves
Xylem sap moves through apoplast
Leaf cells take up what
they want

53. Nutrient assimilation
Assimilating N and S is
very expensive!
Reducing NO3- to NH4+
costs 8 e- (1 NADPH +
6 Fd)

54. Nutrient assimilation
Assimilating N and S is
very expensive!
Reducing NO3- to NH4+
costs 8 e- (1 NADPH +
6 Fd)
Assimilating NH4+ into
amino acids also costs
ATP + e-

55. Nutrient assimilation
Assimilating N and S is very expensive!
Reducing NO3- to NH4+ costs 8 e- (1 NADPH + 6 Fd)
Assimilating NH4+ into amino acids also costs ATP + e-
Nitrogen fixation costs 16 ATP + 8 e-

56. Nutrient assimilation
Assimilating N and S is very expensive!
Reducing NO3- to NH4+ costs 8 e- (1 NADPH + 6 Fd)
Assimilating NH4+ into amino acids also costs ATP + e-
Nitrogen fixation costs 16 ATP + 8 e-
SO42- reduction to S2- costs 8 e- + 2ATP

57. Nutrient assimilation
Assimilating N and S is very expensive!
Reducing NO3- to NH4+ costs 8 e- (1 NADPH + 6 Fd)
Assimilating NH4+ into amino acids also costs ATP + e-
Nitrogen fixation costs 16 ATP + 8 e-
SO42- reduction to S2- costs 8 e- + 2ATP
S2- assimilation into Cysteine costs 2 more e-
Most explosives are based on N or S!

58. Nutrient assimilation
Most explosives are based on N or S!
Most nutrient assimilation occurs in source leaves!

59. N cycle
Must convert N2 to a form that can be assimilated
N2 -> NO3- occurs in atmosphere: lightning (8%) & Photochemistry (2%) of annual total fixed
Remaining 90% comes from biological fixation to NH4+

60. N cycle
Soil bacteria denitrify NO3- & NH4+ back to N2
Plants must act fast!
Take up NO3- & NH4+ but generally prefer NO3-
Main form available due to bacteria

61. N assimilation by non-N fixers
Nitrate reductase in cytoplasm reduces
NO3- to NO2-
NO3- + NADPH = NO2- + NADP+
large enzyme with FAD & Mo cofactors
NO2- is imported to plastids & reduced
to NH4+ by nitrite reductase

62. N assimilation by non-N fixers
NO2- is imported to plastids & reduced
to NH4+ by nitrite reductase
NO Fdred + 8 H+ = NH Fdox + 2 H2O
0.2% of NO2- is released as N2O : another reason rape & corn biofuels increase global warming

63. N assimilation by non-N fixers
NO2- is imported to plastids & reduced
to NH4+ by nitrite reductase
NO Fdred + 8 H+ = NH Fdox + 2 H2O
0.2% of NO2- is released as N2O : another reason rape & corn biofuels increase global warming
Regulated at NO3- reductase; always << NO2- reductase
NO2- is toxic!

64. N assimilation by non-N fixers
Regulated at NO3- reductase; always << NO2- reductase
NO2- is toxic!
NR induced by light & nitrate

65. N assimilation by non-N fixers
Regulated at NO3- reductase; always << NO2- reductase
NO2- is toxic!
NR induced by light & nitrate
Regulated by kinase in dark, dephosphorylation in day

66. NH4 assimilation
GS -> GOGAT
Glutamate + NH4+ + ATP <=> Glutamine + ADP +Pi

67. GS -> GOGAT
Glutamate + NH4+ + ATP <=> Glutamine + ADP +Pi
Glutamine + a-ketoglutarate + NADH/2 Fdred <=>
2 Glutamate + NAD+/ 2 Fdox

68. GS -> GOGAT
Glutamate + NH4+ + ATP <=> Glutamine + ADP +Pi
Glutamine + a-ketoglutarate + NADH/2 Fdred <=>
2 Glutamate + NAD+/ 2 Fdox
3. Fd GOGAT lives in source cp

69. GS -> GOGAT
Fd GOGAT lives in source cp
NADH GOGAT lives in sinks

70. GS -> GOGAT
Glutamate + NH4+ + ATP <=> Glutamine + ADP +Pi
Glutamine + a-ketoglutarate + NADH/2 Fdred <=>
2 Glutamate + NAD+/ 2 Fdox
3. Use glutamate to make other a.a. by transamination

71. GS -> GOGAT
3. Use glutamate to make other a.a. by transamination
Glutamate, aspartate & alanine can be converted to the other a.a.

72. S assimilation
SO42- comes from weathering or from rain: now an important source! Main thing that makes rain acid!

73. S assimilation
S is used in cysteine & methionine

74. S assimilation
S is used in cysteine & methionine
Also used in CoA, S-adenosylmethionine

75. S assimilation
S is used in cysteine & methionine
Also used in CoA, S-adenosylmethionine
Also used in sulphoquinovosyl-diacylglycerol

76. S assimilation
S is used in cysteine & methionine
Also used in CoA, S-adenosylmethionine
Also used in sulphoquinovosyl-diacylglycerol
And in many storage compounds: eg allicin (garlic)

77. S assimilation
SO42- comes from weathering or from rain: now an important source! Main thing that makes rain acid!
Some bacteria use SO42- as e- acceptor -> H2S

78. S assimilation
SO42- comes from weathering or from rain: now an important source! Main thing that makes rain acid!
Some bacteria use SO42- as e- acceptor -> H2S
Some photosynthetic bacteria use reduced S as e- donor!

79. S assimilation
SO42- comes from weathering or from rain: now an important source! Main thing that makes rain acid!
Some bacteria use SO42- as e- acceptor -> H2S
Some photosynthetic bacteria use reduced S as e- donor!
Now that acid rain has declined in N. Europe Brassica & wheat need S in many places

80. S assimilation
SO4 2- is taken up by roots &
transported to leaves in xylem
Most is reduced in cp

81. S assimilation
SO4 2- is taken up by roots &
transported to leaves in xylem
Most is reduced in cp
1. add SO4 2- to ATP -> APS

82. S assimilation
add SO4 2- to ATP -> APS
Transfer S to Glutathione -> S-sulfoglutathione

83. S assimilation
add SO4 2- to ATP -> APS
Transfer S to Glutathione -> S-sulfoglutathione
S-sulfoglutathione + GSH -> SO32- + GSSG

84. S assimilation
add SO4 2- to ATP -> APS
Transfer S to Glutathione -> S-sulfoglutathione
S-sulfoglutathione + GSH -> SO32- + GSSG
Sulfite + 6 Fd -> Sulfide

85. S assimilation
add SO4 2- to ATP -> APS
Transfer S to Glutathione -> S-sulfoglutathione
S-sulfoglutathione + GSH -> SO32- + GSSG
Sulfite + 6 Fd -> Sulfide
Sulfide + O-acetylserine -> cysteine + acetate
O-acetylserine was made from serine + acetyl-CoA

86. S assimilation
Most cysteine is converted to
glutathione or methionine

87. S assimilation
Most cysteine is converted to
glutathione or methionine
Glutathione is main form
exported

88. S assimilation
Most cysteine is converted to
glutathione or methionine
Glutathione is main form
exported
Also used to make many other
S-compounds

89. S assimilation
Most cysteine is converted to
glutathione or methionine
Glutathione is main form
exported
Also used to make many other
S-compounds
Methionine also has many uses
besides protein synthesis

90. S assimilation
Most cysteine is converted to glutathione or methionine
Cys + homoserine -> cystathione

91. S assimilation
Most cysteine is converted to glutathione or methionine
Cys + homoserine -> cystathione
Cystathione -> homocysteine + Pyruvate + NH4+

92. S assimilation
Most cysteine is converted to glutathione or methionine
Cys + homoserine -> cystathione
Cystathione -> homocysteine + Pyruvate + NH4+
Homocysteine + CH2=THF -> Met + THF
80% of met is converted to S-adenosylmethionine & used for biosyntheses

93. S assimilation
Most cysteine is converted to glutathione or methionine
Glutathione is made enzymatically!
Glutamate + Cysteine -> g-glutamyl cysteine

94. S assimilation
Glutathione (GluCysGly) is made enzymatically!
Glutamate + Cysteine -> g-glutamyl cysteine
g-glutamyl cysteine + glycine -> glutathionine

95. S assimilation
Glutathione (GluCysGly) is made enzymatically!
Glutamate + Cysteine -> g-glutamyl cysteine
g-glutamyl cysteine + glycine -> glutathionine
Glutathione is precursor for many chemicals, eg phytochelatins

96. S assimilation
Glutathione (GluCysGly) is made enzymatically!
Glutamate + Cysteine -> g-glutamyl cysteine
g-glutamyl cysteine + glycine -> glutathionine
Glutathione is precursor for many chemicals, eg phytochelatins
SAM & glutathione are also precursors for many cell wall components

97. Assignment 1
Pick a secondary compound and figure out how to measure it

98. Assignment 2
Design a way to see how plants are responding to the stress