DescriptionPlants are sources of nourishment for thousands of fungi, bacteria, invertebrates, vertebrates, and other plants. Plants possess a truly remarkable diversity of mechanisms to fend off attackers and recent research has shown just how complex and sophisticated these defense mechanisms can be.
Plant Defense provides comprehensive coverage of the range of different organisms that plants need to fend off, describes how plants coordinate their defenses against multiple attacks, explains the evolution of defense in plants, and how plant defences are exploited in crop protection strategies.
- Covers plants’ defenses against pathogens, pests, and parasitic plants: together in one book
- Brings together succinct, cutting edge information in a user-friendly format
- Gives an understanding of how plants ward off attacks from multiple enemies
- Is written by Dale Walters, an internationally known and respected researcher and teacher in crop protection, who distils his wealth of knowledge in a novel and exciting way
- Is an essential purchase for all those involved in plant protection around the globe
Plant Defense is primarily designed for use by upper undergraduates and post graduates studying crop protection, agricultural sciences, applied entomology, plant pathology, and plant sciences. Biological and agricultural research scientists in the agrochemical and crop protection industries, and in academia, will find much of great use in this excellent new book. Libraries in all universities and research establishments where agricultural and biological sciences are studied and taught should have multiple copies of this very valuable book on their shelves.
Chapter 1. Why Do Plants Need Defenses?
1.1 Plants as sources of food.
1.2 Organisms that use plants as food.
1.2.2 Parasitic angiosperms.
1.3 Impact of infection and herbivory in natural and agricultural ecosystems.
1.3.2 Parasitic angiosperms.
Chapter 2. What Defenses Do Plants Use?
2.2 Defenses used against pathogens.
2.2.2 Passive or preexisting defenses.
184.108.40.206 Preexisting structural defenses.
220.127.116.11 Preexisting chemical defenses.
2.2.3 Active or inducible defenses.
18.104.22.168 Inducible structural defenses.
22.214.171.124 Inducible chemical defenses.
2.2.4 Defenses used against pathogens—the next step.
2.3 Defenses used against parasitic plants.
2.3.2 Preattachment defense mechanisms.
2.3.3 Prehaustorial defense mechanisms.
2.3.4 Posthaustorial defense mechanisms.
2.4 Defenses used against nematodes.
2.4.2 Passive or preexisting defenses.
2.4.3 Active or inducible defenses.
126.96.36.199 Phenylpropanoid metabolism.
188.8.131.52 Hypersensitive response.
2.5 Defenses used against herbivorous insects.
2.5.2 Physical barriers.
184.108.40.206 Waxes on the leaf surface.
220.127.116.11 Secretory canals.
18.104.22.168 Leaf toughness and leaf folding.
2.5.3 Chemical defenses.
22.214.171.124 Nitrogen-containing organic compounds.
126.96.36.199 Arthropod-inducible proteins.
188.8.131.52 Volatile compounds.
2.6 Defenses used against vertebrate herbivores.
2.6.2 Physical defenses.
2.6.3 Chemical defenses.
184.108.40.206 Phenolic compounds.
220.127.116.11 Nitrogen-containing compounds.
18.104.22.168 Other chemicals.
22.214.171.124 A final word on chemical defenses against vertebrate herbivory.
2.7 Defenses used against neighboring plants—allelopathy.
2.7.2 Allelopathy and the black walnut.
2.7.3 Allelopathy and the Californian chaparral.
2.7.4 Allelopathy and spotted knapweed.
Chapter 3. Sounding the Alarm: Signaling and Communication in Plant Defense.
3.2 Signaling in plant–pathogen interactions.
3.2.2 Local signaling and basal resistance.
126.96.36.199 SA signaling.
188.8.131.52 JA signaling.
184.108.40.206 ET signaling.
220.127.116.11 Signaling involving other plant hormones.
3.2.3 Systemic signaling and induced resistance.
18.104.22.168 Induced resistance.
22.214.171.124 Signaling during SAR.
126.96.36.199 Signaling during ISR.
3.2.4 Volatile signaling.
3.3 Signaling in plant–nematode interactions.
3.3.2 SA signaling.
3.3.3 JA signaling.
3.4 Signaling in plant–insect herbivore interactions.
3.4.2 Local signaling.
188.8.131.52 JA signaling.
184.108.40.206 ET signaling.
220.127.116.11 SA signaling.
18.104.22.168 Specificity and regulation of jasmonate-based defenses.
3.4.3 Systemic signaling.
22.214.171.124 JA signaling.
126.96.36.199 Within leaf signaling.
3.4.4 Volatile signaling.
3.5 Signaling in interactions between plants and vertebrate herbivores.
3.6 Signaling in interactions between plants and parasitic plants.
Chapter 4. Plant Defense in the Real World: Multiple Attackers and Beneficial Interactions.
4.2 Dealing with multiple attackers: cross-talk between signaling pathways.
4.2.1 Trade-offs associated with triggering SA-mediated defenses.
188.8.131.52 SA suppression of JA-induced defenses.
184.108.40.206 Molecular basis of SA suppression of JA defenses.
220.127.116.11 Ecological costs of resistance to biotrophic versus necrotrophic pathogens.
18.104.22.168 Trade-offs with mutualistic symbioses.
22.214.171.124 Effects of SA- and JA-mediated defenses on bacterial communities associated with plants.
4.2.2 Triggering SA-dependent defenses does not always compromise defense against insect herbivores.
4.2.3 Trade-offs and positive outcomes associated with triggering JA-dependent defenses.
4.2.4 Putting it all together: orchestrating the appropriate defense response.
4.3 Can beneficial plant–microbe interactions induce resistance in plants?
4.3.2 Induction of resistance by mycorrhizas.
4.3.3 Resistance induced by endophytic and other beneficial fungi.
Chapter 5. The Evolution of Plant Defense.
5.2 Hypotheses of plant defense.
5.2.1 The growth–differentiation balance hypothesis.
5.2.2 Optimal defense hypotheses.
5.2.3 Plant apparency hypothesis.
5.2.4 The carbon–nutrient balance hypothesis.
5.2.5 The growth rate hypothesis.
5.2.6 Hypotheses of plant defense—where next?
5.3 Evolution of plant defense strategies.
5.3.1 The univariate trade-off hypothesis.
5.3.2 The resistance–regrowth trade-off hypothesis.
5.3.3 The plant apparency hypothesis.
5.3.4 The resource availability hypothesis.
5.3.5 Plant defense syndromes.
5.4 Patterns of plant defense evolution.
5.4.1 Adaptive radiation.
5.4.2 Escalation of defense potency.
5.4.3 Phylogenetic conservatism.
5.4.4 Phylogenetic escalation and decline of plant defense strategies.
5.5 Why do plants have induced defenses?
126.96.36.199 Allocation costs associated with induced responses to herbivory.
188.8.131.52 Allocation costs associated with induced responses to pathogens.
5.5.2 Targeting of inducible direct defenses.
5.5.3 Targeting of inducible indirect defenses.
5.5.4 Dispersal of damage.
5.5.5 Possible role of pathogenic bacteria in the evolution of SAR.
5.6 The coevolutionary arms race .
Chapter 6. Exploiting Plant Defense.
6.2 Using plant resistance to protect crops—breeding.
6.2.2 Breeding for resistance.
184.108.40.206 Sources of resistance.
220.127.116.11 Breeding methods and selection strategies.
6.2.3 Resistance in practice.
6.2.4 Types of resistance.
18.104.22.168 Monogenic resistance.
22.214.171.124 Polygenic resistance.
126.96.36.199 Durable resistance.
188.8.131.52 Gene-for-gene concept.
6.2.5 Making life more difficult for the attacker.
6.3 Using plant resistance to protect crops—induced resistance.
6.3.2 Induced resistance for pathogen control.
6.3.3 Induced resistance for control of herbivorous insects.
6.3.4 Induced resistance for control of nematodes and parasitic plants.
6.4 Using plant resistance to protect crops—biotechnological approaches.
6.4.2 Engineering resistance to pathogens.
6.4.3 Engineering resistance to insects.
6.4.4 Prospects for using transgenic resistance.
""The advances in this field have been striking. Recommended. Upper-division undergraduates through professionals/practitioners."" (Choice, 1 May 2011)
- Essential core information for students and professionals in agricultural and plant sciences
- Dale Walters is well respected internationally for his work in this area
- Covers plant defence from an evolutionary, ecological and crop protection standpoint
- A full understanding of this subject is vital for those working in the agrochemical industry