plant development and signals plants use development to solve ecological problems
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Plant Development and Signals Plants use development to solve ecological problems Repair, maintain, flourish Resist competitors, herbivores, pathogens, abiotic factors Seek out resources Plants respond to environmental and endogenous signals - PowerPoint PPT PresentationTRANSCRIPT
Plant Development and Signals
Plants use development to solve ecological problems– Repair, maintain, flourish
– Resist competitors, herbivores, pathogens, abiotic factors
– Seek out resources
Plants respond to environmental and endogenous signals
Signals alter gene reading programs and influence:– Cell division, expansion and differentiation at meristems
– Tissue, organ and whole plant modification
– Fitness
Gene reading programs and flow of information
DNA
m RNA transcript
proteinSignal(s)
promoter
+ -
+ -Protein synthesis
+ -
gene
enzymes
structuralregulatory transporter
cytoskeletal+ -
+ -
Classes of signals
Internal (endogenous); generally chemical– Hormone– Non-hormone– Electrical gradients (but much less so than animals)
External, generally non-chemical– Electrical, light, gravity, temperature, mechanical forces– Some chemical cues (e.g. MeJ)
Internal chemical signals
Hormones (a definition from animal biologists)
– Naturally occurring organic molecules that act in small concentrations
– Sole function is to serve as a developmental signal• Signal is context dependent
– Typically move from source to target
Plant biologist- naturally occurring organic molecule whose sole function is to serve as a development signal
– 5 classes of plant hormones
Auxin• Indoleacetic acid (IAA), IBA• Activity determined by charge separation• Many synthetics• Roles: 0.55 nm+
-
Gibberellins (GA)• Large family of compounds
– Numbered according to discovery
• Three linked rings with side groups
• Roles:
Cytokinins (CK)
• Derivative of adenine
• Different functional (R) groups attached
• Roles:R group
Ethylene (C2H4)• Gas at room temperature
• Roles:
C C
H
H
H
H
Abscisic acid (ABA)
• Named b/c it was discovered in abscised lvs
• Not the direct cause of leaf loss though
• Roles:
Internal non-hormone chemical signals
Phenolics (Phe)– Coumarin– Anthocyanin– Salicylic acid– Ferulic acid
O
R
Methyl jasmonate (MeJ)
• Related to stress response(s)
• Root initiation, tendril coiling, pollen germination
• Volatile interspecies ‘messages’
Oligosaccarides (Oligos)
• Polymers of carbohydrates
• Related to defense response– Phytoalexins, chitinase, and protease
inhibitors
External chemical signals• Nitrate (NO3
-) – Controls nitrogen assimilation
• Hydroquinones– Can signal parasitic plants to start
‘parasite gene reading program’
Principles of plant hormone action
1. Each hormone causes many responses
IAA
Abscission-
Root initiation+
Stem elongation
+
-+
Bud expansion
Vascular repair
Principles of plant hormone action
2. A hormone’s effect can differ between organs and species, and with age.
Wheat seedling elongation
Young Old
IAA Yes No
GA No Yes
10-6 IAA
+
-
Root elongation
Stem elongation
Principles of plant hormone action
3. Many hormones can affect the same response
Cell division
CK IAA GA
+ + +
Hormone sensorsSince signals vary, the meaning of a signal depends on receptors and sensitivity (kinds of sensors a cell contains)
Cells must have sensors/receptors; when hormone binds w/ following (blue) molecules response set off
• Membrane channels or carriers receive and transport signal (A)
• Signal activates enzyme (CD)
• Receptor is regulatory protein (B)
Gene reading
C D
+ -
+ + -+ -
A
A
B
Setting off a responseResponses may occur when the cell has a threshold number of receptors bound to hormones
Equilibrium conditions predicts that response can occur when:
– Hormone concentration increased
– Receptor concentration increased (= sensitivity)
Receptor
Hormone
HR
Response
+
Response depends on concentration• Induction – on/off
response once threshold hormone level is exceeded
• Modulation – on-going log linear dose response
[Hormone]
[Hormone]
Response
Response
0%
100%
Physiologic range
10-610-8
Hormone concentration control
• Synthesis
• Transport
• Destruction
• Sequestration
• Conjugation
• Example - IAA
Concentration control
• Self-inhibition
• Interactions between IAA and C2H4
• Interactions between CK and GA
• De-stabilizing concentrations
Measuring hormone concentrations
• Bioassays – Grow specimens in a range of known
concentrations– Generate dose response curve– Find value for unknown
• Chromatography
• Mass spectrometry
• Antibody
Control of phenolic synthesis
Phenolics may act as 2o messengers
Phenylalanine
Cinnamic acid
Cinnamyl CoA
Chalcone
Phenolics and flavonoids, including some phytoalexins
Lignin
PAL
Chalcone synthase
aaInjury
Pathogens
+
+
gene
gene
+
+
+
+
Ferulic acid