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Bacillus thuringiensis bt toxin

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Depends on plasmid transfer by conjugation ... After conjugation, the strain's potency against a wide spectrum of insects is increased ... – PowerPoint PPT presentation

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Title: Bacillus thuringiensis bt toxin


1
Bacillus thuringiensis (bt) toxin
  • BS322 Environmental Microbiology

2
Bacillus thuringiensis (Bt) toxin action, use
and genetic engineering
  • References
  • Not many suitable ones in MH, but some
    information can be found on the genetic
    manipulation of plants at 631.51 onwards.
  • Dines, A.J. and Mottley, J. (1999). Seeds of
    Change Applications of Biotechnology to
    Agriculture. In Springham, D. (ed) Biotechnology
    The Science and the Business (in MH library - ref
    only). Can also can be found at
    http//homepages.uel.ac.uk/J.Mottley/Newchapt.html
  • Alternatively try the WWW (NBIAP Monthly News
    Reports are useful - to be found at
    www.nbiap.vt.edu where there is also a searchable
    database).

3
Bacillus thuringiensis
  • Main biological insect control agent
  • Gm ve sporulating bacterium
  • Produces crystals of endotoxin in sporulating
    cells
  • Specific for certain insect groups, particularly
    Lepidoptera, Diptera and Coleoptera

4
Types of Bt toxin
Pseudomonas fluorescens
MVP, M-TRAK
Mycogen Corp.
?
5
Factors affecting effectiveness of Bt toxin
  • Amount of toxin ingestion
  • Processing within the insect gut
  • Activity at site of action

6
Toxin ingestion
  • Effect of larval size
  • Early stages more susceptible
  • Feeding behaviour
  • Indiscriminate feeders eat all parts of plant
  • Discriminate feeders - only certain parts of
    plant used for food either all the time or at
    certain stages of life cycle

7
Gut processing of toxin
  • Requires two processes that may differ in
    different insects and produce different
    responses
  • Toxin solubilisation
  • Occurs in highly alkaline (pH8-9.5) juices of
    target insects mid gut
  • Toxin activation
  • By action of proteolytic enzymes

8
Activity at site of action
  • Toxin binds to specific receptors on surface of
    insect mid-gut epithelial cells, specifically to
    the p-lipids in the brush border membranes of the
    columnar cells
  • A pore forms through the cell membrane resulting
    in loss of insects ability to osmoregulate
  • Insect dies due to massive water uptake and cell
    bursting

9
Strategies for increasing the effectiveness of Bt
insecticides
  • Two main approaches
  • Genetic modification of Bt plasmids
  • Genetic modification of plants to produce Bt

10
Genetic modification of Bt plasmids
  • Depends on plasmid transfer by conjugation
  • Bt strain that shows low activity against a wide
    spectrum of insects chosen as recipient. Some of
    its plasmids are cured by growth at high temp.
  • Bt strain with high potency but with maybe narrow
    spectrum of activity chosen as donor
  • After conjugation, the strains potency against a
    wide spectrum of insects is increased

11
Genetic modification of plants with Bt toxin genes
  • Plants are genetically modified with Bt toxin
    genes so that they produce Bt toxin in their
    tissues.
  • Insects are then killed when they feed on the
    plant tissues
  • This has been successful and widely used
    commercially in most important crops, eg. maize,
    tobacco, tomatoes and cotton

12
Reduced use of synthetic chemical insecticides
  • Should lead to cheaper products, a less polluted
    environment and safer food
  • Conventional insecticides may still be needed,
    especially with large populations
  • With small pest populations, farmers may choose
    to use cheaper synthetic alternatives

13
Table 2. Comparison of strategies for delivery of
Bt toxin either as conventional sprays or via GM
plants
14
POTENTIAL RISKS OF UTILIZING BT PRODUCING CROPS
  • Toxicity to the consumer
  • Toxicity to non-target insect species
  • Build-up of insect resistance to BT

15
Toxicity to the consumer
  • Consumers in industrialised countries have been
    exposed to residues from BT sprays in their food
    for many years with no obvious toxicity problems,
    but
  • Long-term toxicity of large dosages needs
    determining
  • Toxin chemical structure may differ when produced
    in plants, eg. active form

16
Toxicity to non-target insect species
  • Although only insects that feed on BT-producing
    plants are targeted, useful insects may also be
    harmed if the spectrum of activity of the toxins
    is altered. For example, honey bees and (Monarch)
    butterflies when they feed on the nectar or
    pollen of Bt crops
  • Only signs of this are in lab experiments under
    highly unnatural conditions with highly abnormal
    doses

17
Development of insect resistance to Bt toxin
  • Few reports of resistance development in over 40
    years of use and these done in lab
  • Contrasts with use of synthetic pesticides in lab
    and field

18
Possible causes of insect resistance to Bt toxin
  • Could result from
  • Reduced solubilization in the gut
  • Changes in the gut protease composition/activity
  • Decreased sensitivity of the gut receptor sites
  • But would these reduce overall fitness of
    resistant insects?

19
Build-up of insect resistance to BT sprays
  • Little information available on the long-term
    effects of constantly exposing insect populations
    to lethal doses of BT sprays
  • Buildup of resistance more likely from marginally
    susceptible insects than extremely susceptible
    ones
  • If so, Bt may become obsolete as the most
    important biological pest control agent

20
Build-up of insect resistance to GM Bt crops
  • Selection pressure through increased use of
    single and active Bt toxin strains in GM Bt
    plants on a very wide scale compared to more
    limited use and multiple strains in sprays
  • Unlike with synthetic pesticides, different toxin
    strains have slightly different modes of action
    and often insects resistant to one are not
    resistant to another so need multigenic mutations
    to create resistance

21
Strategies for reducing insect resistance in Bt
crops
  • All based on providing a non-Bt environment so
    that susceptible insects can survive and multiply
  • Rotations
  • Bt crops rotated with non-Bt crops to reduce
    build-up of resistant insects

2001
2002
2003
Non-GM
GM
Non-GM
22
  • Refugia
  • Whole fields of non-Bt crops placed alongside
    fields of Bt crops

GM
Non-GM
GM
Non-GM
GM
Non-GM
23
  • Mosaics
  • Bt and non-Bt crops grown in the same field

GM Non-Gm Gm Non-GM GM Non-GM Gm Non-GM GM Non-G
M GM Non-GM Gm Non-GM Gm Non-GM GM Non-GM GM
24
Conclusions
  • Bt toxin delivery can be achieved in TWO ways
    spray or through the plant food of insects
  • Both methods can be improved by GM
  • Both methods have their advantages and
    disadvantages
  • Use of Bt plants definitely reduces use of
    dangerous synthetic pesticides but may not
    eliminate it altogether
  • A risk from increased use may be the development
    of insect resistance (but not yet proven)
  • Agricultural strategies can be used to reduce the
    build-up of resistance
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