Title: to 20' Pest Management
1Terrestrial ecology
2Whats a pest?
- What characterises a pest?
- How would you define the term pest?
3Whats a pest?
- an animal that has a detrimental effect on a
valued resource
4Whats a valued resource?
5Whats a valued resource?
- Natural environment / ecosystem / species
- Agricultural / forestry crop
- Something used / needed/ liked / wanted by
someone
- pest value judgement
- DISAGREEMENT
6So pests can be
- Introduced / native
- Herbivores / omnivores /carnivores
- In towns / country
- In National Parks / farmland / forestry
detrimental effect on a valued resource
7and Pests are
- Time specific
- Place specific
- Person specific
8Pest impact via interactions
- competition
- predation
- herbivory
9Aim of pest management?
- ? numbers?
- ? detrimental impact?
- Often component of conservation management
- Endangered species
- Communities / ecosystems
10Manage impact of pests - how?
- List general methods
- Which methods suit which situations?
- Give examples
- Advantages /disadvantages of each?
11Manage impact of pests - how?
- ? numbers (? population size)
- ? mortality (affect deaths)
- DIRECT shoot, trap, poison
- INDIRECT introduce pathogen e.g. myxoma virus,
calicivirus - rabbits - ? fecundity (affect births)
- DIRECT baits with birth control
- INDIRECT introduce self-spreading vector to
transmit birth control - ? behaviour
12Management by numbers (populations)
r rate of increase slope
- Pests
- r high, ve
- or popn. K r 0
- Endangered sp.
- Low population
- r 0 or -ve
13Pest rates of (populations) increase
Hone L95 p714 Fig 1 A rabbit B red fox C
house mouse
- Pests
- r high, ve
- or popn. K r 0
Hone J. (1999) On rate of increase (r) patterns
of variation in Australian mammals and the
implications for wildlife management. Journal of
Applied Ecology, 36, 709-718.
14Management by numbers (populations)
- Three problems
- Conservation
- ? abundance
- r gt 0
- Sustained yield
- Maintain abundance
- r 0
- Pest control
- ? abundance
- r lt 0
15Management by numbers (populations)
- Conservation management of endangered species
- Directional selection against ve rates of
population increase
Hone J. (1999) On rate of increase (r) patterns
of variation in Australian mammals and the
implications for wildlife management. Journal of
Applied Ecology, 36, 709-718.
16Management by numbers (populations)
- Sustainable harvesting
- Stabilizing selection against extremes of high
and low rates of population increase
17Management by numbers (populations)
- Pest control
- Directional selection to abundance
- Shift rates of increase to lower or -ve levels
18Management by numbers
Endangered species
Sustained harvest
Pest control
during
after
19Pest impact management by numbers
- -ve rate of increase ? population
- Methods
- ? mortality (affect deaths)
- ? fecundity (affect births)
20Aim ? pest impact Method 1 ? pest
numbersProblems ?
- Humaneness?
- Numbers vs. impact?
- Enhanced demographic vigour?
- Non-target species?
21Humaneness
- Irrespective of status of animal
22Numbers vs. impact?
23Numbers vs. impact - example
Tree seedling damage on plantations in Tasmania
Pademelons
BT possums
24Numbers vs. impact - example
Tree seedling damage on plantations in Tasmania
- 32 E.nitens plantations
- seedlings assessed for damage at 12 months
- vegetation characteristics measured
- index of animal abundance scat counts
- (stepwise) linear regression
25Numbers vs. impact - example
Tree seedling damage on plantations in Tasmania
26Numbers vs. impact - example
Tree seedling damage on plantations in Tasmania
y 0.46 2.00x1 1.61x2 0.13x3 r2
0.71 y damage score x1 possum abundance
(scats) partial r2 0.54 x2 grass cover
(transformed) partial r2 0.09 x3
bracken cover (transformed) partial r2 0.09
Bulinski J. McArthur C. (2003) Identifying
factors related to the severity of mammalian
browsing damage in eucalypt plantations. Forest
Ecology and Management, 183, 239-247.
27Numbers vs. impact - example
Tree seedling damage on plantations in Tasmania
Bracken
Grass
Poss scats
y 0.46 2.00x1 1.61x2 0.13x3 y
damage score x1 possum abundance (scats)
?
Damage
Population size
28Numbers vs. impact - example
Tree seedling damage on plantations in Tasmania
Bracken
Grass
Poss scats
y 0.46 2.00x1 1.61x2 0.13x3 y
damage score linear pademelon scats not
significant
Damage
Population size
29Enhanced demographic vigour
30Enhanced demographic vigour
- Caughley Sinclair p292 Table 17.1
Caughley G. Sinclair A. R. E. (1994) Wildlife
Ecology and Management, 1st edn. Blackwell
Science, Cambridge, Massachusetts.
31Enhanced demographic vigour
- ? proportion of breeding females
- ? mortality of young (? survival)
- Younger age to maturity
32Non-target species
- Affect pest - affect others?
- Direct indirect interactions
pest
33Non-target species - example
Prey switching by wedge-tailed eagles as rabbit
numbers ?
- Mutawintji National Park
- 120km NE of Broken Hill, NSW
- Destructive sampling of nests (not recommended)
- Assess eagle diets
- before (1995)
- during (1996)
- after (1997) RCD rabbit calicivirus disease
- RCD rabbit abundance ? 44 78
Sharp A., Gibson L., Norton M., Ryan B., Marks A.
Semeraro L. (2002) The breeding-season diet of
wedge-tailed eagles (Aquila audax) in western New
South Wales and the influence of Rabbit
Calicivirus Disease. Wildlife Research, 29,
175-184.
34Non-target species - example
Prey switching by wedge-tailed eagles as rabbit
numbers ?
eagle
reptiles
rabbit
others
35Non-target species - example
Prey switching by wedge-tailed eagles as rabbit
numbers ?
- 2071 prey items identified
Sharp A., Gibson L., Norton M., Ryan B., Marks A.
Semeraro L. (2002) The breeding-season diet of
wedge-tailed eagles (Aquila audax) in western New
South Wales and the influence of Rabbit
Calicivirus Disease. Wildlife Research, 29,
175-184.
36Non-target species - example
Prey switching by wedge-tailed eagles as rabbit
numbers ?
- Dietary items (as of total)
Sharp A., Gibson L., Norton M., Ryan B., Marks A.
Semeraro L. (2002) The breeding-season diet of
wedge-tailed eagles (Aquila audax) in western New
South Wales and the influence of Rabbit
Calicivirus Disease. Wildlife Research, 29,
175-184.
37Non-target species - example
Prey switching by wedge-tailed eagles as rabbit
numbers ?
- Evidence consistent with prey switching
- Impact of rabbit control on non-targets
- Enough alternative prey to sustain eagles?
- Effect of change in diet on native prey?
- Need to monitor populations
Sharp A., Gibson L., Norton M., Ryan B., Marks A.
Semeraro L. (2002) The breeding-season diet of
wedge-tailed eagles (Aquila audax) in western New
South Wales and the influence of Rabbit
Calicivirus Disease. Wildlife Research, 29,
175-184.
38Aim ? impact Method 1 ? numbersProblems ?
- Humaneness?
- Numbers vs. impact?
- Enhanced demographic vigour?
- Non-target species?
Ecology
39Aim ? impact Method 1 ? numbersProblems ?
- Can you kill enough animals?
- Sustained yield
- Maintain abundance
- r 0
- Pest control
- ? abundance
- r lt 0
40Can you kill enough animals?
Goats in Egmont National Park can they be
eradicated?
Forsyth D. M., Hone J., Parkes J. P., Reid G. H.
Stronge D. (2003) Feral goat control in Egmont
National Park, New Zealand, and the implications
for eradication. Wildlife Research, 30, 437-450.
41Can you kill enough animals?
Goats in Egmont National Park can they be
eradicated?
- 1910 Goats 1st report in ENP
- 1920 large goat herds
- 1925 Ranger appointed to control goats
- 1925 1940 control intermittent
- 1950 bounty introduced
- 1961 1987 NZFS hunters to control goats
- 1987 present DOC hunters to control goats
Forsyth D. M., Hone J., Parkes J. P., Reid G. H.
Stronge D. (2003) Feral goat control in Egmont
National Park, New Zealand, and the implications
for eradication. Wildlife Research, 30, 437-450.
42Can you kill enough animals?
Goats in Egmont National Park can they be
eradicated?
- Model population change based on
- Assume logistic growth
- Maximum rate of increase of goats (rm) 0.468
- Carrying capacity K 10000
- Current population size 1047
Forsyth D. M., Hone J., Parkes J. P., Reid G. H.
Stronge D. (2003) Feral goat control in Egmont
National Park, New Zealand, and the implications
for eradication. Wildlife Research, 30, 437-450.
43Can you kill enough animals?
Goats in Egmont National Park can they be
eradicated?
Forsyth D. M., Hone J., Parkes J. P., Reid G. H.
Stronge D. (2003) Feral goat control in Egmont
National Park, New Zealand, and the implications
for eradication. Wildlife Research, 30, 437-450.
44Can you kill enough animals?
- killed must be high enough to ? population
- Eradication
- High effort ()
- often not feasible
45Manage impact of pests - how?
- ? numbers (? population size)
- ? mortality (affect deaths)
- DIRECT shoot, trap, poison
- INDIRECT introduce pathogen e.g. myxoma virus,
calicivirus - rabbits
- Humaneness?
- Numbers vs. impact?
- Enhanced demographic vigour?
- Non-target species?
- Can you kill enough?
46Manage impact of pests - how?
- ? numbers (? population size)
- ? mortality (affect deaths)
- ? fecundity (affect births)
- Especially for vertebrate pests
- DIRECT baits with birth control
- INDIRECT introduce self-spreading vector to
transmit birth control
Barlow N. D. (2000) The ecological challenge of
immunocontraception editor's introduction.
Journal of Applied Ecology, 37, 897-902.
47Pest management by fertility control
- Fertility control
- any technique that ? production of young
- Methods
- temporary or permanent sterilisation
- E.g. immunocontraceptionallergic to
reproducing - Steps in R D
- Develop something which inhibits reproduction
- Does it ? population size?
- Does this ? impact of pests?
48Pest management by fertility control
- Risks e.g. SARS
- Bird virus
- Bird ? human
- Human ? very sick/die
- Recently
- 1st case human-human transfer
- Advantages
- More humane?
- More sustained effect?
- Disadvantages
- Could it ever work?
- Risks?
49Step 1 immunocontraception
50Step 1 immunocontraception
Lloyd M. L., Shellam G. R., Papadimitriou J. M.
Lawson M. A. (2003) Immunocontraception is
induced in BALB/c mice inoculated with murine
cytomegalovirus expressing mouse zona pellucida
3. Biology of Reproduction, 68, 2024-2032.
51Step 1 immunocontraception
- Trials
- Short term
- 10 females innoculated (virus or placebo)
- 1 male mouse until females pregnant
- Long term
- Groups of females (virus or placebo)
- 1 male per group females long-term
Lloyd M. L., Shellam G. R., Papadimitriou J. M.
Lawson M. A. (2003) Immunocontraception is
induced in BALB/c mice inoculated with murine
cytomegalovirus expressing mouse zona pellucida
3. Biology of Reproduction, 68, 2024-2032.
52Step 1 immunocontraception
- Lloyd et al 2003 SC31
- Table 4 short term male intro - effects
- Fig 5A long term male pesence effects on
births
Lloyd M. L., Shellam G. R., Papadimitriou J. M.
Lawson M. A. (2003) Immunocontraception is
induced in BALB/c mice inoculated with murine
cytomegalovirus expressing mouse zona pellucida
3. Biology of Reproduction, 68, 2024-2032.
53Step 1 immunocontraception
Lloyd M. L., Shellam G. R., Papadimitriou J. M.
Lawson M. A. (2003) Immunocontraception is
induced in BALB/c mice inoculated with murine
cytomegalovirus expressing mouse zona pellucida
3. Biology of Reproduction, 68, 2024-2032.
54Pest management by fertility control
?
- Steps in R D
- Develop something which inhibits reproduction
- Does it ? population size?
- Does this ? impact of pests?
55Step 2 does sterilisation ? population size?
- Sterilisation of females may change?
- Dominance
- Territoriality
- Proportion of breeding females
56Step 2 does sterilisation ? population size?
- Example 1
- dominance relationship within group hasNO EFFECT
on a females probability of breeding
Caughley G., Pech R. Grice D. (1992) Effect of
fertility control on a population's productivity.
Wildlife Research, 19, 623-627.
57Step 2 does sterilisation ? population size?
- Example 2
- dominance relationship within group is linear
- only top dominant breeds
- sterilisation removes female from dominance
hierarchy
Caughley G., Pech R. Grice D. (1992) Effect of
fertility control on a population's productivity.
Wildlife Research, 19, 623-627.
58Step 2 does sterilisation ? population size?
- Example 3
- 1 female dominant (all others equally
subordinate) - only top dominant breeds
- sterilisation removes dominant female, all
others free to breed
Caughley G., Pech R. Grice D. (1992) Effect of
fertility control on a population's productivity.
Wildlife Research, 19, 623-627.
59Step 2 does sterilisation ? population size?
- Example 1
- dominance relationship within group hasNO EFFECT
on a females probability of breeding
- Example 2
- dominance relationship within group is linear
- only top dominant breeds
- sterilisation removes female from dominance
hierarchy
- Example 3
- 1 female dominant (all others equally
subordinate) - only top dominant breeds
- sterilisation removes dominant female, all
others free to breed
60Step 2 does sterilisation ? population size?
- Example 1
- dominance relationship within group hasNO EFFECT
on a females probability of breeding
Caughley G., Pech R. Grice D. (1992) Effect of
fertility control on a population's productivity.
Wildlife Research, 19, 623-627.
61Step 2 does sterilisation ? population size?
Example 1
- Result
- ? females sterilised
- ? number of offspring
Caughley G., Pech R. Grice D. (1992) Effect of
fertility control on a population's productivity.
Wildlife Research, 19, 623-627.
62Step 2 does sterilisation ? population size?
If N 1 If N 5 Where N number of females in
a group
- Example 2
- dominance relationship within group is linear
- only top dominant breeds
- sterilisation removes female from dominance
hierarchy
- Example 3
- 1 female dominant (all others equally
subordinate) - only top dominant breeds
- sterilisation removes dominant female, all
others free to breed
63Step 2 does sterilisation ? population size?
- Example 2
- dominance relationship within group is linear
- only top dominant breeds
- sterilisation removes female from dominance
hierarchy
Caughley G., Pech R. Grice D. (1992) Effect of
fertility control on a population's productivity.
Wildlife Research, 19, 623-627.
64Step 2 does sterilisation ? population size?
Example 2
- Result
- ? females per group
- ? must be sterilised
- to get same mean number of litters per group
Caughley G., Pech R. Grice D. (1992) Effect of
fertility control on a population's productivity.
Wildlife Research, 19, 623-627.
65Step 2 does sterilisation ? population size?
- Example 3
- 1 female dominant (all others equally
subordinate) - only top dominant breeds
- sterilisation removes dominant female, all
others free to breed
Caughley G., Pech R. Grice D. (1992) Effect of
fertility control on a population's productivity.
Wildlife Research, 19, 623-627.
66Step 2 does sterilisation ? population size?
Example 3
- Result
- sterilising may lead to ? number of litters per
group - opposite of desired effect
Caughley G., Pech R. Grice D. (1992) Effect of
fertility control on a population's productivity.
Wildlife Research, 19, 623-627.
67Pest management by fertility control
?
- Steps in R D
- Develop something which inhibits reproduction
- Does it ? population size?
- Does this ? impact of pests?
Not always
68Manage impact of pests - how?
- ? numbers (? population size)
- ? mortality (affect deaths)
- ? fecundity (affect births)
- Fencing - exclusion
69Manage impact of pests - how?
- ? numbers (? population size)
- ? mortality (affect deaths)
- ? fecundity (affect births)
- Fencing (exclusion)
- ? behaviour
70Changing pest behaviour
- ? numbers (? population size)
- ? behaviour
- How?
- Suitable for which pest problems?
- Give examples
71Repellents to deter pests
Example 1 Big Game Repellent, apple twigs,
deer browsing
Andelt W. F., Burnham K. P. Baker D. L. (1994)
Effectiveness of capsaicin and bitrex repellents
for deterring browsing by captive mule deer.
Journal of Wildlife Management, 58, 330-334.
72Repellents to deter pests
Example 1 Big Game Repellent, apple twigs,
deer browsing
Andelt W. F., Burnham K. P. Baker D. L. (1994)
Effectiveness of capsaicin and bitrex repellents
for deterring browsing by captive mule deer.
Journal of Wildlife Management, 58, 330-334.
73Repellents to deter pests
Example 2 WR-1, eucalypt seedlings,
pademelon browsing
(but new growth eaten)
Witt A. Effects of repellents on seedling growth
and herbivory. B.Sc. (Hons.) Thesis, University
of Tasmania, Hobart.
74Diversionary food to ? impact of pests
Example 3 Sunflower seeds, lodgepole pine trees,
red squirrel
- 3 paired sites
- 2 treatments
- Expt. control
- Diversionary sunflower seeds
- Damage to pine trees?
Sullivan T. P. Klenner W. (1993) Influence of
diversionary food on red squirrel populations and
damage to crop trees in young lodgepole pine
forest. Ecological Applications, 3, 708-718.
75Diversionary food to ? impact of pests
Sullivan T. P. Klenner W. (1993) Influence of
diversionary food on red squirrel populations and
damage to crop trees in young lodgepole pine
forest. Ecological Applications, 3, 708-718.
76Manage impact of pests
- ? numbers
- ? mortality (affect deaths)
- ? fecundity (affect births)
- Fencing (exclusion)
- ? behaviour
- Repellents
- Diversions
77Main points
- Aim ? impact of pest
- Methods
- ? population or
- change behaviour
- Can ? population by
- ? Mortality
- ? Fecundity
- MUST consider
- Humaneness
- Effectiveness
- Numbers vs. impact
- Enhanced demographic vigour
- Can you kill enough?
- Non-targets
78References
- Andelt W. F., Burnham K. P. Baker D. L. (1994)
Effectiveness of capsaicin and bitrex repellents
for deterring browsing by captive mule deer.
Journal of Wildlife Management, 58, 330-334. - Barlow N. D. (2000) The ecological challenge of
immunocontraception editor's introduction.
Journal of Applied Ecology, 37, 897-902. - Caughley G., Pech R. Grice D. (1992) Effect of
fertility control on a population's productivity.
Wildlife Research, 19, 623-627. - Caughley G. Sinclair A. R. E. (1994) Wildlife
Ecology and Management, 1st edn. Blackwell
Science, Cambridge, Massachusetts. - Forsyth D. M., Hone J., Parkes J. P., Reid G. H.
Stronge D. (2003) Feral goat control in Egmont
National Park, New Zealand, and the implications
for eradication. Wildlife Research, 30, 437-450. - Hone J. (2004) Yield, compensation and fertility
control a model for vertebrate pests. Wildlife
Research, 31, 357-368.
79References
- Hone J. (1999) On rate of increase (r) patterns
of variation in Australian mammals and the
implications for wildlife management. Journal of
Applied Ecology, 36, 709-718. - Lloyd M. L., Shellam G. R., Papadimitriou J. M.
Lawson M. A. (2003) Immunocontraception is
induced in BALB/c mice inoculated with murine
cytomegalovirus expressing mouse zona pellucida
3. Biology of Reproduction, 68, 2024-2032. - Saunders G., McIlroy J., Berghout M., Kay B.,
Gifford E., Perry R. van de Ven R. (2002) The
effects of induced sterility on the territorial
behaviour and survival of foxes. Journal of
Applied Ecology, 39, 56-66. - Sharp A., Gibson L., Norton M., Ryan B., Marks A.
Semeraro L. (2002) The breeding-season diet of
wedge-tailed eagles (Aquila audax) in western New
South Wales and the influence of Rabbit
Calicivirus Disease. Wildlife Research, 29,
175-184. - Sullivan T. P. Klenner W. (1993) Influence of
diversionary food on red squirrel populations and
damage to crop trees in young lodgepole pine
forest. Ecological Applications, 3, 708-718. - Witt A. Effects of repellents on seedling growth
and herbivory. B.Sc. (Hons.) Thesis, University
of Tasmania, Hobart.