1. Ecological footprints of some nations already exceed available ecological capacity.1

2. Our ecological ‘footprint’… 1)
Before lecture on Tuesday,
take the quiz on
Insert your result in the top of the lecture outline, as shown on the LO (cut out the one shown), and bring the lecture outline to class.

3. Chapter 15: Dynamics of predator-prey interactions
Lyunx = a cat but not = mt. Lion (closer to bobcat in size, action

4. Objectives Adaptations of predators Prey deterrents to predation
Do predators limit prey?
Functional / numerical responses of
predators to prey density
Predator-prey synchronized cycles
How stabilize predator-prey interactions?
Laboratory studies of refugia/spatial heterogeneity

5. What are predator adaptations to exploit prey?

6. The jaws of snakes are adapted for grasping and swallowing large prey.

7. C41. 9 Rock python and gazelle. Can’t chew; must swallow whole
C41.9 Rock python and gazelle. Can’t chew; must swallow whole. Long period of digestion.

8. Predators vary in size relative to their prey.

9. Prey deterrents to predation
Group living
Induced structural defense
Chemical defense
Cryptic coloration
Aposematism
Mimicry

10. Prey have active adaptations for escaping their predators: chemical warfare!
Bombadier beetle sprays noxious liquid at temp of boil water toward a predator.

11. Palatable prey avoid predators passively via crypsis.

12. Cryptic coloration - passive escape
C53.5 camouflage: a canyon tree frog disappearing into granite

13. Unpalatable animals have warning coloration (aposematism)
Unpalatable animals have warning coloration (aposematism). Predators learn from mistakes.
C53.6 Poison arrow frog; skin produces noxious chemicals.
Predators apparently learn to associate color with danger as soon
as they touch frog’s skin.
Figure 3

14. Warning is even greater in groups…

15. Top-down control Tri-trophic predators interactions herbivores (prey) plants nutrients/light Bottom-up control
Top-down: predators control herbivores
Bottom up: plants (or nutirents that control plants) control herbivore
(e.g. light or nutrients lower plant productivity which lowers herbivore producitify
Also intraspecific competition may control herbivores; or other abioltic factors

16. Do predators control prey abundance? If… then…
K Duck eggs hatching in ND from which striped skunks removed duirng hesting season
Figure 6

17. Is there a response of this predator to an increase in its prey
Is there a response of this predator to an increase in its prey? Why or why not?
territorial
K forest rodents and tawny owls in Poland. Red arrow = heavy crop from oak, maple, hornbean - triggered large increase in seed-eating rodents. Tawny owls maintain stable number on territories regardless of large change in prey abundance.
Heavy
seed crop
in 89
Figure 7

18. Human activities have altered: 1) predator-prey relations 2) ‘top-down’ control

19. Individual predators exhibit 3 types of functional responses to increasing prey density.

20. Functional response: A change in rate of capture of prey by an individual predator as prey density changes.
Type I: Capture directly proportional
to prey density
Type II: Capture levels off at high prey
density (predator satiation)
Type III: as Type II, but is also low at low
prey density
1) heterogeneous habitat---> hiding places
2) lack of learned search behavior
3) switching to alternative prey

21. ***What type of functional response of kestrels to vole density?
SS Kestrels and voles during breeding.
Curve did not reach horizontal level; no predator saturation.
Type of curve underlying L-V equations
Type 1 linear funcitonal response: predators take prey in proportion to their
availability

22. ***What type of functional response of wolves to moose?
K13-17Type 11 fucntinonal response . Predation rate of wolves incresases with moose density, then appears to level off…need more data at higher densisites to resolve shape of relationsihip.

23. What type of functional response
***What type of functional response? Predators switch to different prey in response to fluctuations in prey density.
Predators swtich to alternate prey in response to fluctuations in prey density.
Water bug feeding on mayfly larvae; red line = no preference of mayfly larvae over other prey
At low density - goes to other prey; at high density switches to mayfly disproportionately.

24. Switching to alternative prey occurs only when preferred prey density falls to low level.

25. Is this a numerical or functional response of wolves to moose?
K Density of wolves increass with moose density up to about 1 moose per km2 and them may reach a plateau. Wolves defend territories, which may restrict their numerical response to prey abundance
Figure 11

26. Why didn’t top-down control limit spruce budworm devastation?

27. Is there a functional response. Numerical response
***Is there a functional response? Numerical response? What is the total response of warblers to spruce budworm abundance? Does the warbler control its prey?
Figure 12A B C
K13.19
Warbler increased 12X in response to irruptionof spruce budworm in Canada.
Showed both a functional (A) and numerical (B)response. C= combined (total) response As shown in C, an 8000 X increase in budworm reduced predator to an insignificant mortality agent. Threshold of prey density above which prey escape from being limited by predators.

28. Population cycles synchronized among species in a region
Population cycles synchronized among species in a region. Periodic cycles with peaks separated by same number of years.
Small mammal synchronized cycling, but dominated by varation in most common species, but other species tend to reach peak abundances more or less in synchrony with it.
Figure 13

29. Cycles have damped out with warmer temperatures.29

30. Other species may vary in their response to changes in the environment --> asynchronized cycles.
Pop highs and lows don’t coincide closely, suggesting that they are governed by different factors.
Four moth species in same haibtat fluctuate independently. Germany over 60 yrs.
Figure 14

31. Predator and prey populations often increase and decrease in synchronized cycles. Which group lags the other?

32. Do prey control predators or vice versa?
Predators eat prey--->reduce prey numbers
Predators go hungry---> their numbers drop
Few prey do better--->prey numbers rise
Predators have more food---> their numbers
rise.
Do prey control predators or vice versa?
What other factor could explain prey cycles?

33. Question: What factors control the hare-lynx population cycle?
Hypothesis: Predation, food availability to prey, or a combination of those two factors controls the cycle.
Null Hypothesis: They do NOT control the cycle.
Experimental Design??
Prediction: Hare populations in at least one type of manipulated plot will be higher than mean population in control plots.
Prediction of null H: Hare populations will be the same in all of the plots.
Figure 16

34. Fence;
no lynx
Controls
Extra food
for hares
Both

35. What is conclusion?
Do predation, food, or a combination of both factors control the hare-lynx cycle?
Figure 17

36. The lynx-hare story update…alternative explanations.
See Gotelli pg 161-2

37. Fluctuations in population density in a host-parasitoid system in the lab.
Azuki bean weevil and wasp parasitoid kept for 120 cycles
Krebs…pg 215

38. How stabilize predator-prey interactions?
No sediment
Sediment(hiding places)
SS15.4 Paramecium and Didinium: R = K13.7 Gause’s testtube experiments
A - oat w/o sediment; Didinium found all prey and ate, then starved to etinction
B - oat with sediment; Didinium found all prey in clear, but then starved; some prey hid in refuge and took off after Didinium extinction
C Immigration of P and D in oat without sediment; regular cycles
Concluded: prey need refuge from predator
stable system not from predator-prey interactions, but from outside force againsg the system.(immigration)
Immigration
Figure 19

39. Huffaker’s experiment to get predator-prey populations to persist without immigration.
2 mites = prey and predator

40. 1) Oranges clumped---> what happened to cycle?
Figure 20

41. 2) Oranges dispersed randomly---> what happened to cycles? Why?
3) Spatial heterogeneity --->stable cycles.
120 spots; equilvalent of 6 oranges; added bariers to dispersal of predator (vasoline) and some pegs to faciliate parachuting of prey to new locations
Figure 21