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Host Plant Resistance and Conservation of Genetic Resources

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Improved agronomic characters (yield, durability, timing and ... Soybean Cyst Nematode and Resistant ... Soybean cyst = major pest of soybeans in midwest ... – PowerPoint PPT presentation

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Title: Host Plant Resistance and Conservation of Genetic Resources


1
Host Plant Resistance and Conservation of Genetic
Resources
2
Crop Cultivars
  • Improved agronomic characters (yield, durability,
    timing and uniformity of harvest)
  • Resistance to pests and diseases (resistant
    cultivars available in many plant species vs many
    different kinds of plant pests)

3
Adaptations of Pests Overcoming Resistance
  • To pesticides (many examples with insects)
  • To resistant cultivars
  • To cultural/agronomic practices

4
Resistance Management
  • Important so pests dont overcome resistance
  • Important to minimize selection pressure to slow
    development of resistant pests
  • Use IPM, reduced dosages, rotation of methods,
    different cultivars, etc.
  • Avoid overusing same method or cultivar

5
Soybean Cultivars and Resistance to Nematodes
6
Soybean Cyst Nematode and Resistant Soybean
Cultivars
  • Soybean cyst major pest of soybeans in midwest
    US
  • Many isolates
  • Managed by soybean cultivars resistant to a
    specific isolate
  • Use of same resistant cultivar for 2-3 yrs in a
    row selects for new isolates and breaking of
    resistance

7
Soybean Cyst Nematode and Resistant Soybean
Cultivars
  • Soybean cyst major pest of soybeans in midwest
    US
  • Many isolates
  • Managed by soybean cultivars resistant to a
    specific isolate
  • Use of same resistant cultivar for 2-3 yrs in a
    row selects for new isolates and breaking of
    resistance
  • Solution rotate soybean cultivars, using
    resistant cv only one year at a time. e.g.,
    nonhost --- resistant cv --- susceptible cv

8
Costs of obtaining/utilizing resistant or
high-yielding cultivars
Wild relatives Crop species Selection Plant
breeding Cultivar (variety)
Germplasm
9
Costs of obtaining/utilizing resistant or
high-yielding cultivars
Wild relatives Crop species Selection Plant
breeding Cultivar (variety)
Biotechnology accelerates development of new
cultivars
Germplasm
10
Costs of obtaining/utilizing resistant or
high-yielding cultivars
Wild relatives Crop species Selection Plant
breeding Cultivar (variety)
Crop genetic diversity decreases
Agronomic performance increases
11
Costs of obtaining/utilizing resistant or
high-yielding cultivars
  • Cultivar has desirable attributes (high yield,
    resistance to some pest)
  • Potential cost is that because of loss of genetic
    diversity, it may become susceptible to other
    problems
  • Most breeding programs now recognize this, and
    include broader genetic base in new cultivars

12
Unimproved germplasm can have high genetic
diversity (high variability)
Wild relatives Crop species Selection Plant
breeding Cultivar (variety)
Germplasm
13
Least genetic diversity in vegetatively
propagated plants (clonal propagation)
14
Genetic Diversity (not same as HPR)
  • Advantages
  • Mixed genotypes can provide future source for
    developing new resistant cultivars
  • Mixed crop genotypes can slow epidemics,
    invasion of new pests, withstand biological and
    environmental events

15
Genetic Diversity (not same as HPR)
  • Disadvantages
  • - - Lower yields than genotypes selected for high
    yield
  • - - Less effective than resistant cultivars
    against single pests

16
Maintaining Genetic Diversity
  • On farm, if mixed crop genotypes are planted
    genetic diversity maintained within plant
    population (e.g., local crop varieties in many
    tropical areas)
  • Within region, if different cultivars are planted
    genetic diversity among plant populations
    (e.g., some US crops like corn, that have many
    cultivars)

17
Classical examples of lack of genetic diversity
  • Potato produced from tuber seed pieces clonal
    propagation low genetic diversity
  • Potatoes in Ireland consisted of two genotypes,
    introduced on two clones of potatoes in 1500s
  • Became highly successful and productive crop,
    supported human population growth

18
Classical examples of lack of genetic diversity
  • Potato produced from tuber seed pieces clonal
    propagation low genetic diversity
  • Potatoes in Ireland consisted of two genotypes,
    introduced on two clones of potatoes in 1500s
  • Became highly successful and productive crop,
    supported human population growth
  • Potato late blight fungus (Phytophthora
    infestans) appears in 1840s
  • Both clones highly susceptible to late blight
  • Irish potato famine results

19
Classical examples of lack of genetic diversity
  • Potato produced from tuber seed pieces clonal
    propagation low genetic diversity
  • Potatoes in Ireland consisted of two genotypes,
    introduced on two clones of potatoes in 1500s
  • Became highly successful and productive crop,
    supported human population growth
  • Potato late blight fungus (Phytophthora
    infestans) appears in 1840s
  • Both clones highly susceptible to late blight
  • Irish potato famine results

South America great diversity of potato clones,
epidemics dont establish
20
Classical examples of lack of genetic diversity
Green Revolution, 1960s
  • High yielding wheat and rice cultivars (high
    genetic uniformity)
  • Widely planted in Tropics
  • Uniform genotypes highly susceptible to pests and
    environmental conditions

21
Conservation of Genetic Resources
  • Gene banks International Research Centers,
    research stations, etc., maintain plant germplasm
    (seeds, other plant materials, etc.)
  • Habitat and community-based conservation wild
    crop relatives maintained in natural habitats,
    borders of fields, etc.

22
Conservation of Genetic Resources
  • Gene banks International Research Centers,
    research stations, etc., maintain plant germplasm
    (seeds, other plant materials, etc.)
  • Habitat and community-based conservation wild
    crop relatives maintained in natural habitats,
    borders of fields, etc.

Political controversy Who owns/controls genetic
resources?
23
Future Host Plant Resistance
  • Development of resistant plant cultivars is an
    ongoing process
  • Need to be prepared to develop new cultivars
    before pests overcome resistance in the old ones
  • Always looking for new sources for resistance and
    for cultivar development
  • Need to insure that these genetic sources will be
    available in the future

24
References
  • Text, Ch. 9, esp. pp. 148-150, 155-162.
  • Carroll et al., 1990. Ch. 6 (pp.173-177), Chs.
    16,19.
  • Tivy, 1992. Ch. 6 (pp. 106-107).
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