22 In-Text Art, p. 650 Ethylene

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22 In-Text Art, p. 650 Ethylene
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Figure 22.5 The triple response in Arabidopsis
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Figure 22.1 Triple response of etiolated pea
seedlings
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Figure 22.2 Ethylene biosynthetic pathway and
the Yang cycle
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Figure 22.3 ACC concentrations, ACC oxidase
activity, and ethylene during ripening of apples
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Figure 22.4 Two inhibitors that block ethylene
binding to its receptor
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Figure 22.6 Screen for the etr1 mutant of
Arabidopsis
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Figure 22.9 Screen for Arabidopsis mutants that
constitutively display the triple response
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Figure 22.20 Schematic view of the roles of
auxin and ethylene during leaf abscission
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Figure 22.19 Effect of ethylene on abscission in
birch (Betula pendula)
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Figure 22.17 Inhibition of flower senescence by
inhibition of ethylene action
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Figure 22.11 Ethylene production and respiration
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Figure 22.7 Schematic diagram of five ethylene
receptor proteins and their functional domains
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Figure 22.8 Model for ethylene receptor action
based on the phenotype of receptor mutants
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Figure 22.8 Model for ethylene receptor action
(A) Wild type
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Figure 22.8 Model for ethylene receptor action
(B) In the absence of ethylene
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Figure 22.8 Model for ethylene receptor action
(C) A missense mutation
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Figure 22.8 Model for ethylene receptor action
(D) Disruption mutations
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Figure 22.10 Model of ethylene signaling in
Arabidopsis
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Figure 22.10 Model of ethylene signaling in
Arabidopsis
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Figure 22.13 Amounts of ACC in the xylem sap and
ethylene production in the petiole
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Figure 22.16 Promotion of root hair formation by
ethylene in lettuce seedlings
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Figure 22.18 Formation of the abscission layer
of jewelweed (Impatiens)
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22 In-Text Art, p. 667 Ethephon releases ethylene
slowly by a chemical reaction