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Exploitation specifically predation

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Title: Exploitation specifically predation


1
Exploitation specifically predation
  • Predator kills and eats victim
  • snake, wolf, lion, spider, seed weevil, etc.
  • Parasite lives intimately with victim and
    usually does not necessarily kill victim
  • tapeworm, flea, louse, aphid, malaria, etc.
  • Herbivore/Carnivore distinction not that
    important for dynamics

2
Exploitation
  • How does the presence / absence of a predator
    affect
  • species populations
  • assemblages of prey species
  • evolution of prey
  • Does predation contribute to community patterns?

3
Predation population dynamics
  • Predators eat prey prey die
  • How does this affect population dynamics?
  • Lotka-Volterra predator-prey model
  • N number in prey population
  • P number in predator population

4
Lotka-Volterra predator-prey
  • Without predation, prey grow exponentially
  • dN / dt r1 N
  • Predation is an increasing function of N P
  • Effect of predation on prey population C1 NP
  • C1 is the capture efficiency
  • So, with predation
  • dN / dt r1 N - C1 NP

5
Lotka-Volterra predator-prey
  • Without prey, predators starve to death
    exponentially
  • dP / dt - r2 P
  • Predation is an increasing function of N P
  • Effect of predation on predator populationC2 NP
  • C2 product of capture conversion
    efficiencies
  • So, with prey
  • dP / dt C2 NP - r2 P

6
Lotka-Volterra predator-preyEquilibrium
predictions
  • At equilibrium
  • dN / dt 0 and dP / dt 0
  • there is a specific, constant density of
    predators, above which prey cannot increase
  • there is a specific, constant density of prey,
    below which predator cannot increase

7
Lotka-Volterra predator-prey isoclines
8
Lotka-Volterra predator-prey isoclines
Predator (P)
Prey (N)
9
Lotka-Volterra predator-prey isoclines
10
Lotka-Volterra predator-prey isoclines
11
Lotka-Volterra predator-prey dynamics
12
Predator-prey cycles in real data
  • Hare Lynx
  • Other examples
  • Driven by predator-prey dynamics?
  • What assumptions are built into Lotka-Volterra
    predator-prey models?

13
Simplifying Assumptions
  • Simplifying Environmental
  • Constant in time
  • Uniform or random in space
  • Simplifying Biological
  • Individuals are identical constant in time
  • Exponential prey growth
  • Prey limited only by predation
  • Predator growth dependent only on predation

14
Explanatory Assumption
  • Predators and prey encounter each other at
    random, like bimolecular collisions
  • Frequency of encounter proportional to product of
    densities
  • Individual predator feeding rate increases
    linearly as N increases
  • No limit on increase in feeding rate

15
Unrealistic elements
  • No limits on prey except predation
  • expect real prey may be limited by food, space,
    etc. when abundant
  • upper limit ( K ) for prey even with no predators
  • Predators do not saturate with prey
  • expect real predators to hit a maximum number
    eaten
  • expect an upper limit for predators with maximal
    food (KP )

16
Gauses predator-prey experiments
Didinium Predatory ciliate
ParameciumPrey
17
Didinium - Paramecium predator-prey experiment
Paramecium
Density (N or P)
Didinium
Time (t )
18
Gauses Predator-Prey experiments
  • Predator and prey in a simple environment
  • No cycles (stable or otherwise)
  • Predator exterminates prey
  • Predator dies out shortly after
  • Inconsistent with Lotka-Volterra predator-prey
    models

19
HuffakersPredator-Prey experiments
  • Mites
  • predator Typhlodromus
  • prey Eotetranychus
  • on oranges
  • With oranges evenly spread on a tray
  • no cycles
  • prey extinction, then predator extinction

20
Huffakers modifiedPredator-Prey experiments
  • Add barriers to dispersal
  • rubber balls, vaseline
  • cycles
  • Confirms Lotka-Volterra prediction?
  • NO
  • violates simplifying environmental assumption

21
Utidas Predator-Prey experiments
  • Bean weevil Callosobruchus
  • Parasitoid Heterospilus
  • Searching in petri dishes
  • Produces population cycles

22
Predator-Prey models experiments Conclusions
  • Lotka-Volterra models are largely inadequate
  • lab systems meeting assumptions -- no cycles
  • Stable oscillations when system is fixed
  • Conceptual error
  • Design experiments to meet assumptions, then test
    predictions
  • Dont manipulate experiments until they confirm
    theory

23
Improved Predator-Prey models
  • Self limitation of prey and predators
  • Asymptotic prey consumption by predators
  • Spatial refuges for prey
  • graphical approach
  • Rosezweig MacArthur (1963)
  • mathematical approach
  • Williams (1980) Grover (1997)
  • Gilpin Ayala (1973) Populus 5.1

24
Rosenzweig MacArthur predator-prey isoclines
25
Rosenzweig MacArthur predator-prey isoclines
26
Predictions of R. MacA.
  • 1. Inefficient predator
  • isoclines dont cross
  • predicts predator extinction
  • 2. Intermediate predator efficiency 1
  • isoclines cross to right of hump
  • predicts stable coexistence with damped
    oscillations

27
Predictions of R. MacA.
  • 3. Intermediate predator efficiency 2
  • isoclines cross near hump
  • predicts stable oscillations
  • 4. Highly efficient predator
  • isoclines cross to left of hump
  • predicts expanding oscillations extinction

28
Predictions of R. MacA.
29
Further improvements A refuge for prey
  • If prey have a refuge, then a certain proportion
    can escape predation
  • Prey population in the refuge tolerates
    infinitely large predator population
  • Makes stable coexistence more likely

30
A prey refuge stabilizes the system
31
Implications of graphical predator-prey models
  • Many different patterns of dynamics are possible
  • Stable oscillations are only one special case
  • Prey may be exterminated (efficient predators)
  • Prey may be reduced to stable populations below K

32
? logistic model prey dynamics
  • dN / dt r N 1 - (N / K)? - f P
  • r prey intrinsic rate of increase
  • K prey carrying capacity
  • ? quantifies form of density dependence
  • ? 1 yields ordinary logistic
  • f functional response
  • function relating number eaten per predator to N

33
? logistic model predator dynamics
  • dP / dt sP( f - D)
  • f the number of prey eaten per predator
    (functional response)
  • D minimum feeding required for dP / dt gt0
    (predator efficiency)
  • s constant relating predator rate of increase
    to amount eaten

34
Resource models of predator-prey interactions
  • Prey consume resources and prey population grows
  • Predator eats prey and population grows
  • Chemostat system

35
Community effects of predation?
  • Basic effect - reduce prey abundance
  • Increase likelihood of prey elimination?
  • Reduce diversity?
  • Single predator - single prey
  • Smith 1983
  • Pseudacris tadpoles
  • Anax dragonfly nymphs

36
Temporary ponds
  • Isle Royal - small rock islands off main island
  • Lake Superior
  • Depressions in rock form temporary ponds

37
Temporary ponds
  • Vary in size
  • 1 liter to 1000 liters
  • influences pond duration, drying
  • Vary in height above L. Superior
  • 0 to 1 m
  • influences probability of wave washout

38
Pseudacris distribution
  • Might expect larger, higher ponds to have most
    Pseudacris
  • Absent in low ponds, absent-rare in high ponds
  • Predator Anax greatest in high ponds near forest

39
Experiment
  • Four large ponds near forest
  • Remove everything, stock with known densities of
    Pseudacris, Anax
  • Pond Original Experimental Final
  • P A P A P
  • P1(746) 229 0 297 0 166
  • P2(330) 102 0 132 33 0
  • P3(283) 0 92 112 7 57
  • P4(583) 0 50 234 95 0

40
Experiment
  • Elimination in as little as 1 week
  • Pseudacris in P3 grew better than in P1
  • physical environment is OK
  • Predation can yield reduction or local extinction
    of prey
  • Environmental heterogeneity
  • prey persist if a refuge is present

41
Other effects of predation
  • Basic predator effect reduce diversity
  • Keystone predator A predator whose removal from
    a community results in reduced species diversity
    in that community
  • therefore keystone predators increase community
    diversity
  • Keystone predator effect requires both
    interspecific competition and predation

42
Keystone predation in the Rocky intertidal zone
  • Predator
  • Pisaster sea star
  • Nucella snails
  • Grazers
  • limpets snails
  • chitons snails

43
Keystone predation in the Rocky intertidal zone
  • Sessile species
  • Mytilus Mussels
  • Pollicipes Goose-neck barnacle
  • Chthamalus, Balanus acorn barnacles

44
Pacific Northwest Intertidal(Paine 1966)
  • Competition for space
  • Mytilus the competitive dominant species
  • Pisaster preys on all speces, prefers Mytilus
  • Natural intertidal community 15 species
  • Exclude Pisaster with cages
  • 1 to 2 years 8 species
  • Without Pisaster, Mytilus dominates

45
The Keystone effect
46
Pisaster is a keystone predator
  • Keeps competitive dominant (Mytilus) from
    eliminating other species
  • Other predators do not have this effect (e.g.,
    Nucella)
  • Disturbance (e.g., storms, wave action, scouring)
    can have a similar keystone effect
  • Create open space, allow poorer competitors to
    survive

47
Models of keystone predation
  • Leibold 1996
  • What environmental conditions promote keystone
    effects?
  • 3 tropic levels
  • resource R
  • prey N (consumes resource)
  • predator P (consumes prey)

48
Keystone predation isocline
49
Keystone predation isocline
50
Keystone predator effect
  • Most likely at intermediate levels of
    productivity
  • high productivity favors predator resistant sp.
  • low productivity favors best competitor
  • Predicts unimodal diversity - productivity
    relationship

51
Keystone predator gt2 prey
  • For any given productivity (S ), there is a
    stable equilibrium with up to 2 prey spp.
  • Across a gradient of productivity, prey species
    replace each other
  • low productivity best competitors
  • high productivity least vulnerable to predator
  • May create large-scale unimodal
    diversity-productivity relationship

52
Keystone predator spatial heterogeneity
  • With spatial heterogeneity in productivity, gt2
    species of prey can coexist locally
  • Strong unimodal diversity-productivity
    relationship
  • local patches of different productivities have 2
    prey
  • regionally gt2 species coexist at intermediate
    average productivities

53
Related concept Intermediate disturbance
hypothesis
54
Intermediate Disturbance or Intermediate
predation
  • Disturbance disruption of community progress
    toward competitive equilibrium
  • Predation or physical disturbance
  • Diversity maximal at intermediate disturbance
  • Keystone effect may be a special case of
    intermediate predation

55
Intermediate Disturbance
  • Low disturbance (frequency, intensity)
  • Competitive dominant excludes other spp.
  • low diversity, low S
  • High disturbance (frequency, intensity)
  • few species can endure disturbances
  • low diversity, low S
  • Intermediate disturbance (frequency, intensity)
  • disturbance doesnt elimnate species
  • reduces or eliminates competition among prey
  • maximal diversity, maximal S

56
Intermediate predation Temporary pond
amphibians
  • Woodland ponds, SE United States
  • Fill with spring rains later dry up
  • Up to 17 spp. amphibian larvae in one pond
  • Up to 25 spp. present locally
  • Morin 1983, 1981 Wilbur 1983 and many more
    recent papers

57
Temporary pond amphibians
  • Predators salamanders
  • Newts (Notophthalmus)
  • adults and larvae
  • Prey on larvae of anurans
  • (frogs toads)

58
Temporary pond amphibians
  • Common anurans
  • Spadefoot toad
  • (Scaphiopus holbrooki)
  • Leopard frog
  • (Rana sphenocephala)
  • Southern toad
  • (Bufo terrestris)
  • All filter feeders scrapers

59
Temporary pond amphibians
  • Other common anurans
  • Spring peeper
  • (Hyla crucifer)
  • Barking tree frog
  • (Hyla gratiosa)
  • Grey tree frog
  • (Hyla crhysocselis)
  • Also filter feeders scrapers

60
Experiment 1 Artificial ponds
  • Cattle tanks
  • Stock with leaf litter, plants, invertebrates
  • 1200 newly hatched larvae of a mix of the 6
    anuran species (150 to 300 each species)
  • Predators 0, 2, 4, 8 adult newts

61
Effect of newt predation
  • 0 newts
  • Scaphiopus dominates, Hyla rare
  • 2 newts
  • Scaphiopus dominates, Hyla crucifer increases
  • Maximal mass of anuran adults Maximal evenness
  • 4 newts
  • Hyla crucifer Scaphiopus equally abundant
  • 8 newts
  • 60 Hyla crucifer, all others rare

62
Supporting data
  • Scaphiopus most vulnerable to newt predation
  • Most active, moves, forages most
  • Best competitor
  • Hyla crucifer poorest competitor
  • Moves very little
  • General tradeoff -- high vs. low activity
  • High activity, effective foraging, good
    competitor, vulnerable to predation
  • Low activity, lower foraging success, poor
    competitor, less subject to predation

63
Temporary pond amphibians
  • Newt predation concentrated on competitive
    dominant species
  • Intermediate predation yields maximal diversity
  • Both competition and predation are necessary for
    the keystone predator or intermediate predation
    effect

64
Temporary pond amphibians
  • Predators salamanders
  • Tiger salamanders (Ambystoma)
  • larvae
  • Prey on larvae of anurans
  • (frogs toads)

65
Experiment 2 Artificial ponds
  • Ambystoma as a predator, same prey species
  • With any Ambystoma present, anuran larvae are
    exterminated
  • No intermediate predation effect
  • No keystone effect
  • Effect on diversity specific to the predator prey
    combination

66
Beyond the keystone predator effect
  • Predation is a pairwise interaction
  • Interference competition is a pairwise
    interaction
  • Effects on the two species involved
  • There can be effects beyond the pair of species
  • Indirect effect An effect of one species on
    another that occurs via an effect on a third
    species

67
Indirect effect
Increase predator ? Decrease Herbivore
? Increase Plant
TROPHIC CASCADE effects produced 2 or more
trophic levels down from top predator
68
Indirect effect
Decrease prey 1 ? Decrease Predator
? Increase Prey 2
APPARENT COMPETITION negative effects caused via
a shared enemy
69
A surprisingIndirect effect
RESOURCE COMPETITION negative effects caused via
a shared victim
70
Indirect effect
Decrease predator 1 ? Increase Prey
1 ? Decrease Prey 2
? Decrease Predator 2
INDIRECT PREDATOR MUTUALISM positive effects of
one predator on another via competing prey
71
Indirect effects
  • Possibilities are complex
  • Become more complex with more species
  • Two problems
  • 1. How do you detect indirect effects?
  • 2. How important are indirect effects in
    determining community composition?

72
Detecting indirect effects
  • You must
  • know something about the pairwise direct
    interactions within the community
  • Do experiments, typically species removals and
    additions
  • If you dont know which pairwise interactions are
    present, indirect effects may be interpreted
    incorrectly even in an experiment

73
Misinterpreting an indirect effect in an
experiment
  • Remove predator 2
  • Predator 1 increases
  • Prey 1 decreases
  • Prey 2 increases
  • If you dont know the interactions, it looks like
    Predator 2 might prey on Prey 2

74
The importance of indirect effects
  • Commonly assumed that
  • direct effects are strong
  • indirect effects are weak
  • Indirect effects may be stronger, more important
    determinants of species composition and diversity
  • Data? (Wootton 1994)

75
Intertidal invertebrates (again)
76
Interactions in intertidal
  • Observation Exclude bird predation (cages)
  • Nucella decreases relative to control (2 - 4 X)
  • Pollicipes increases relative to control (5 X)
  • Semibalanus decreases relative to control (3 -
    7 X)
  • Mytilus decreases relative to control (to 70)
  • Excluding predator
  • 2 prey species decrease
  • 1 non-prey species decreases
  • 1 prey species increases

77
Understanding this effect
  • A hypothesis to explain this result
  • Which direct interactions are strong?
  • affect numbers of individuals
  • Which direct interactions are weak?
  • do not affect numbers of individuals

78
Hypothesis 1 strong weak interactions
79
Hypothesis 2 strong weak interactions

Sea star Leptasterias
-
Birds (crows, gulls)
-



-

Predatory snail Nucella

-
-


-
Goose Barn. Pollicipes
-
-
-
-
-
-
Mussel Mytilus
Acorn Barnacle Semibalanus
-
-
80
Hypothesis 3 strong weak interactions
81
Hypotheses ? new predictions
  • Remove Pollicipes with birds excluded
  • H 1 Mytilus, Semibalanus, Nucella all increase
  • H 2 Mytilus, Semibalanus increase
  • H 3 Mytilus only increases
  • vs. birds excluded only

82
Hypotheses ? new predictions
  • Exclude birds after removing Pollicipes
  • H 1 no effects
  • H 2 Nucella decreases, Leptasterias increases
  • H 3 Semibalanus, Nucella decrease,
    Leptasterias increase
  • vs. removing Pollicipes only

83
Experiment 1Manipulate Pollicipes without birds
84
Experiment 2.Manipulate birds without Pollicipes
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