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Explore how interacting populations evolve in response to predator-prey relationships, using the rabbit/myxoma virus and Prickly Pear cactus examples. Discover the adaptations and evolutionary responses in predator vs. prey species, including parasites and herbivores, shaping ecosystem dynamics.
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+ Chapter 17: Predation and Herbivory (and a bit of Chapter 20) Robert E. Ricklefs The Economy of Nature, Fifth Edition
Evolution of Resistance in Rabbits • Decline in lethality of the myxoma virus in Australia resulted from evolutionary responses in both the rabbit and the virus populations: • genetic factors conferring resistance to the disease existed in the rabbit population prior to introduction of the myxoma virus: • the myxoma epidemic exerted strong selective pressure for resistance • eventually most of the surviving rabbit population consisted of resistant animals
Evolution of Hypovirulence in Myxoma Virus • Decline in lethality of the myxoma virus in Australia resulted from evolutionary responses in both the rabbit and the virus populations: • less virulent strains of virus became more prevalent following initial introduction of the virus to Australia: • virus strains that didn’t kill their hosts were more readily dispersed to new hosts (mosquitoes bite only living rabbits)
The Rabbit-Myxoma System Today • Left alone, the rabbit-myxoma system in Australia would probably evolve to an equilibrial state of benign, endemic disease, as in South America: • pest management specialists continue to introduce new, virulent strains to control the rabbit population • Contagious diseases spread through the atmosphere or water are less likely to evolve hypovirulence, as they are not dependent on their hosts for dispersal.
… is an example of a predator (the virus) and prey (the rabbits). RABBITS AND MYXOMA …
Prickly Pear cactus were also introduced into Australia. • Like rabbits, they quickly spread over the continent. • A predator of the cactus was introduced. • The cactus moth. • The cactus only survived in areas where the moth was absent.
Comparing cactus before (a) and after (b) the moth introduction.
The cactus is an example of predator prey interactions. • Do predators limit prey population growth? • Do prey limit predator population growth? • The balance between the two depends on their adaptations. • Some adaptations were already found in species. • Some adaptations are a result of predator/prey interactions.
All life forms are both consumers and victims of consumers. • There are many consumer-resource interactions: • Predator-prey • Herbivore-plant • Parasite-host • Producers • Consumers • Predator; Parasite; Parasitoid: Herbivore; Detritivore
+ 11 Some Definitions • Predators catch individuals and consume them, removing them from the prey population. • Parasites consume parts of a living prey organism, or host: • parasites may be external or internal • a parasite may negatively affect the host but does not directly remove it from the population
+ 12 More Definitions • Parasitoids consume the living tissues of their hosts, eventually killing them: • parasitoids combine traits of parasites and predators • Herbivores eat whole plants or parts of plants: • may act as predators (eating whole plants) or as parasites (eating parts of plants): • grazers eat grasses and herbaceous vegetation • browsers eat woody vegetation
+ 14 Detritivores occupy a special niche. • Detritivores consume dead organic material, the wastes of other species: • have no direct affect on populations that produce these resources: • do not affect the abundance of their food supplies • do not influence the evolution of their resources • are important in the recycling of nutrients within ecosystems
An example of a parasitoid wasp. • This was is laying its egg in the caterpillar. • The egg will develop into larvae. • The larvae will consume the caterpillar as it grows. • A combination of predation, and parasitism.
Predators have adaptations for exploiting their prey. • This lion has adaptations to capture fast prey. • This whale is a filter feeder. • Spiders make webs to subdue prey.
Predators and prey are different sizes, and this can pose problems. • If a prey item is too small – it may be too hard to handle. • Imagine trying to capture mice with your hands. • If a prey item is too large – the predator may not be able to subdue. • Imagine trying to tackle a elephant to eat. • Blue whales weigh many tons, but eat tiny shrimp (use of filters).
+ 16 Form and Function Match Diet • Form and function of predators are closely tied to diet: • vertebrate teeth are adapted to dietary items: • horses have upper and lower incisors used for cutting fibrous stems of grasses, flat-surfaced molars for grinding • deer lack upper incisors, simply grasping and tearing vegetation, but also grinding it • carnivores have well-developed canines and knifelike premolars to secure and cut prey
+ 17 A predator’s form and function are closely tied to its diet. (a) upper incisors are used to cut plant material; (b) flat-surfaced molars for grinding plant material; (c) knifelike premolars secure prey and tear flesh
+ 18 More Predator Adaptations • The variety of predator adaptations is remarkable: • consider grasping and tearing functions: • forelegs for many vertebrates • feet and hooked bills in birds • distensible jaws in snakes • digestive systems also reflect diet: • plant eaters feature elongated digestive tracts with fermentation chambers to digest long, fibrous molecules comprising plant structural elements
+ 19 Distensible jaws: shift the articulation of the jaw with the skull from the quadrate bone to the supratemporal
Burmese python (3.9m) vs alligator (1.8m) in Everglades National Park (Florida)
+ 20 Digestive tracts of consumers are adapted to their diets. Digestive organs of herbivores > carnivores
Large carnivores tend to pursue large prey.Size of prey consumed is related to size of predator.
What about the prey? • How much energy do you have available for growth? • If you are predated upon, your growth rates are affected.
Prey have adaptations to avoid being consumed. • Hiding • If a predator can’t see you, it can’t eat you. • Evolution of cryptic coloration. • Escaping • If you can outrun your predator, it can’t eat you. • Evolution of speed or maneuverability. • Active defense mechanisms • Animals with poison glands. • Plants with thorns, toxic substances.
+ 23 Crypsis and Warning Coloration • Through crypsis, animals blend with their backgrounds; such animals: • are typically palatable or edible • match color, texture of bark, twigs, or leaves • are not concealed, but mistaken for inedible objects by would-be predators • Behaviors of cryptic organisms must correspond to their appearances.
+ 24 Cryptic appearances (a) mantid; (b) stick insect; (c) lantern fly
Chemical defenses. • The production of chemicals which repel potential predators. • Toxin + boiling temp => • Notice the colors of this bombardier beetle.
+ 25 Warning Coloration: aposematism • Why should a prey item evolve bright colors? • It definitely brings attention to you. • Black and yellow are the most common colors. • Unpalatable animals may acquire noxious chemicals from food or manufacture these chemicals themselves: • such animals often warn potential predators with warning coloration or : • certain aposematic colorations occur so widely that predators may have evolved innate aversions • If an animal eats a brightly colored prey item: • It may get sick. • It may die. • If it lives, it will remember.
+ 26 Unpalatable organisms
+ 27 Why aren’t all prey unpalatable? • Chemical defenses are expensive, requiring large investments of energy and nutrients. • Some noxious animals rely on host plants for their noxious defensive chemicals: • not all food plants contain such chemicals • animals using such chemicals must have their own means to avoid toxic effects
+ 28 Batesian Mimicry • Certain palatable species mimic unpalatable species (models), benefiting from learning experiences of predators with the models. • This relationship has been named Batesian mimicry in honor of discoverer Henry Bates. • Experimental studies have demonstrated benefits to the mimic: • predators quickly learn to recognize color patterns of unpalatable prey • mimics are avoided by such predators
+ Harmless mantid (b) and moth (c) evolved to resemble a wasp (a)
+ 30 Müllerian Mimicry • Müllerian mimicry occurs among unpalatable species that come to resemble one another: • many species may be involved • each species is both model and mimic • process is efficient because learning by predator with any model benefits all other members of the mimicry complex • certain aposematic colors/patterns may be widespread within a particular region
+ Costa Rican butterflies and moths
Class petition…Any questions? EXAM APRIL 22ND (EARTH DAY): 2 TO 3.30 PM, EXAM HALL
Latest news… MALARIA, MOSQUITOES, EVOLUTION
Parasites! • Parasites have adaptations to allow them to live in the host. • The host has adaptations to fight off parasites. • The parasite does not want to kill the host, but disperse its offspring to another host.
+ 32 Parasites have adaptations to ensure their dispersal. • Parasites are usually much smaller than their hosts and may live either externally or internally: • internal parasites exist in a benign environment: • both food and stable conditions are provided by host • parasites must deal with a number of challenges: • host organisms have mechanisms to detect and destroy parasites • parasites must disperse through hostile environments, often via complicated life cycles with multiple hosts, as seen in Plasmodium, the parasite that causes malaria
+ 33 Parasite-Host Systems: A Balancing Act • The parasite-host interaction represents a balance between parasite virulence and host defenses: • immune system of host can recognize and disable parasites • but parasites may multiply rapidly before an immune response can be deployed
+ 34 Parasites may defeat a host’s immune response. • Circumventing the host’s immune system is a common parasite strategy: • some parasites suppress the host’s immune system (AIDS virus) • other parasites coat themselves with proteins that mimic the host’s own proteins (Schistosoma) • some parasites continually coat their surfaces with novel proteins (trypanosomes)
+ 35 Cross-Resistance • Some parasites elicit an immune response from the host, then coat themselves with host proteins before the immune response is fully mobilized: • initial immune response by host may benefit the host later when challenged by related parasites in a phenomenon known as cross-resistance • Once an immune response has been elicited, antibodies can persist for a long time, preventing reinfection.
Many parasites have complex life cycles.Malaria (Plasmodium) parasitic life cycle.