Predation Lecture 15. Overview Chapter in Text: 15, 17 Predation and Herbivory Responses of...

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Predation Lecture 15

Transcript of Predation Lecture 15. Overview Chapter in Text: 15, 17 Predation and Herbivory Responses of...

PredationLecture 15

Overview• Chapter in Text: 15, 17• Predation and Herbivory• Responses of individuals to predation• Responses of populations to predation –

refuges• Importance of Predators

– Maintenance of ecosystem diversity– as a Keystone species

What is a predator?• Narrow sense

• Broad sense

• Ecological definition of predator:

– Herbivores:• Grazers and browsers – consume part of plant/plant not

killed• Seed eaters + planktinovores: consume entire plant

– Parasite: generally do not kill host– Parasitoid: lay eggs in host – feeding by larvae

eventually kill host

– Under simple laboratory conditions, the predator often exterminates its prey• It then becomes

extinct itself having run out of food!

Lotka-Volterra Models and Predator-Prey cycling:• Developed during 1920s• Assume mutual interaction of predator and prey

numbers• Predict persistence of both predator and prey

populations• The Lotka–Volterra equations for predator and

prey populations link the two populations– Each population functions as a density-dependent

regulator on the other• Predator as a source of density-dependent regulation on the

mortality of the prey population• Prey as a source of density-dependent regulation on the

birthrate of the predator population

• The paired equations, when solved, show that the two populations rise and fall in oscillations

• The cycle can continue indefinitely — the prey is never quite destroyed; the predator never completely dies out

“Now, here you see, it takes all the running you can do, to keep in the same place” – the Red Queen

• Coevolution: as prey species evolve ways to avoid being caught, predators evolve more effective means to capture them

• Natural selection (think in terms of fitness) – “smarter,” more evasive prey– “smarter,” more skilled predators

• Prey defenses to avoid being detected, selected, and captured by predators:– Chemical defense

• Alarm pheromones• Repellants• Toxins

– Cryptic coloration– Warning coloration– Protective armor– Behavioral defense

• Some animals receive an added benefit from eating plants rich in secondary chemical compounds– Caterpillars of monarch butterflies concentrate and store

these compounds

Chemical Defenses

• They then pass them to the adult and even to eggs of next generation

• Birds that eat the butterflies regurgitate them

Blue jay

I’m not eating this again!

• Physical– Thorns– Height– Heavy seed coat

• Chemical– Toxins– Digestion inhibitors

• Nutritional– Low levels of N in older foliage– Tough, difficult to masticate foliage

Plant Responses to Herbivores

• Mustard oils protected plants from herbivores at first– At some point, however, certain insects evolved the

ability to break down mustard oil

Chemical Responses of Plants to Herbivory

• These insects were able to use a new resource without competing with other herbivores for it

–Cabbage butterfly caterpillars

Adult

Green caterpillar

• Physical• Behavioral• Chemical

– Toxins• Coloration

– Cryptic – Warning coloration – aposmatic

• Batesian mimicry – harmless mimics– After Henry Bates, a 19th century British naturalist

• Müllerian mimicry – common coloration of toxin bearing spp

– After Fritz Müller, a 19th century German biologist

Animal Defenses against PredationMonarch butterfly

Viceroy butterfly

• Involves adaptations where one animal body part comes to resemble another

– This type of mimicry is used by both predator and prey

– Example• “Eye-spots” found in many butterflies, moths

and fish

Self Mimicry

• Two or more unrelated but protected (toxic) species come to resemble one another

Müllerian Mimicry

– Thus a group defense is achieved

Yellow jacket

Masarid wasp

Sand wasp Anthidiine bee

Yellow jacket

Predation and Behavior Modification - Refuges• Schooling of prey fish – response to predator

attack – some survive• Alarm calls – Prairie dogs, ground squirrels• Song birds mob and harass predator bird

species• Avoidance – temporal, spatial• Refuges

Refuges

• A mechanism that allows exploited population to escape predation/parasitism – many forms:– Place/form of cover, schooling, synchronized

reproduction (large numbers at one time), size– May not provide absolute sanctuary, enough for

species to survive– Important for survival of predator too!

Protection in Numbers• Living in a large group provides a “refuge.”• Predator’s response to increased prey density:

Prey consumed x Predators = Prey Consumed Predator Area Area

• Wide variety of organisms employ predator satiation defense.– Prey can reduce individual probability of being eaten by

living in dense populations.

Examples of Predator Satiation

• Synchronous widespread seed and fruit production by plants - masting.

• Synchronized emergence of Cicadas – 16-17 year cycle– Williams estimated 1,063,000 cicadas emerged

from 16 ha study site.• 50% emerged during four consecutive nights.• Losses to birds was only 15% of production

Size As A Refuge• If large individuals are ignored by predators,

then large size may offer a form of refuge.– Peckarsky observed mayflies (Family

Ephenerellidae) making themselves look larger in the face of foraging stoneflies.

• In terms of optimal foraging theory, large size equates to lower profitability.

• Is regulation top-down or bottom-up?• ie. primary productivity versus limits

imposed by predator populations

Ch 18 p 344

• Diffuse predator–prey interactions– The lynx, coyote, and horned owl are responsible

for the periodic cycles in the snowshoe hare population

• Diffuse mutualism– A single plant species may depend on a variety of

animal species for successful reproduction

Lynx predates weakened

hares – eventually

crashes

Hare popul crashes as:1. Reduced forage weakened hares, high lynx prdation2. Forage produced after heavy browsing accumulates plant defense chemicals less palatable

• Is regulation top-down or bottom-up?

• ie. primary productivity vs. limits imposed by predator populations

Predators and Diversity – see pages 340-344

• Alter competitive balance amongst prey spp.– Robert Paine studies: sea star exclusion in intertidal plots

decreased prey diversity (15 8 spp)• Selective alteration of competitive relationships

– Peter Morin studies – altered competitive relationships amongst immature frog spp by predatory newt

Keystone Predator (or Keystone Consumer –) • Species essential to maintenance of ecosystem

structure/diversity• Example (there are many): CA sea otter – kelp

forest community

THINGS TO WORRY ABOUT

• Your Pores — Portals for Invasion? • Musty Dankness • Fleas & Ticks — Tiny Terrorists

What's Embedded in Your Bed? • What Your Mother Never Told You About Those

Hidden Corners and Cracks • Pink Mold — Slime or Scourge?

Mildew — Mold's Evil Twin