Topic 6 Predation

Question 1

Give examples of specialist predators and their mode of feeding

Answer 1

SNAKES

• Sit and wait, often by feeding areas, nests
• Flexible jaws; all parts of mandible move indepently from rest of skull so they can eat large prey
• Two strategies:

1. Constrict prey using strong body muscles OR;
2. Venom containing toxins to subdue prey eg. Neurotoxins that paralyse prey by blocking the signals from nerves to muscles. Large fangs in front-fanged snakes, or between grooves of teeth in back fanged snakes to deliver venom to prey. Toxins are delivered quickly in one strike, then snake will follow prey til it collapses and eat it whole.

SPIDERS

• Sit and wait
• Some use toxins
• Produce silk to form traps and webs

CATS (Felidae)

• Chase their prey
• Retractable claws
• Powerful jaws and large teeth
• Agility and rapid movement
• Social organisation (hunt in packs)

Question 2

Describe the role of neurotransmitters, how naturally occurring molecules interfere with their activity and the medical benefits of understanding these processes

THEME MOVEMENT

Answer 2

Neurotoxins are example of convergent evolution. Possible because the neuromascular junction is similar across animals.

In normal functioning neurotransmitters (eg acetylcholine) are released by action potetial at nerve ending and binds with receptor sites at muscle celll membrane causing contraction

Alkaloids like tubocararine are chemically similar to neurotranmsitter so can also bind at receptor preventing nerotransmitter from binding causing muscle to cease movement

Tubocurarine is an acetylcholine antagonist because it inhibitst a response

Nicotine is an acetylcholine agonist because it stimulates a response (increases blood pressure, heart rate etc)

There are different types of acetylcholine receptor sites at different types of muscle tissue (eg. cardiac musle and smooth musle which are not under conscious control v skeletal muscle)

Knowing the molecular structure of alkiloids and how they bind at different sites allows the development of targeted drugs (eg.painkillers).

Question 3

Alkiloids

Answer 3

Large and diverse group of chemicals, containing nitrogen, often produced as secondary chemicals.

Question 4

Secondary chemicals

Answer 4

Chemicals produced by organisms that are outside the primary metabolism of the organism. They may be used for defence eg tubocurarine in the Curarea vine used as poison curare by indigenous people

Question 5

Why are plant-derived compounds useful in medicine?

Answer 5

• Compounds have evolved as defence mechanisms against a wide variety of predators.
• The action of defence mimics natural processes in the human body, such as the behaviour of neurotransmitters.
• Manipulation of neurotransmitter levels can be useful in a variety of medical applications, such as muscle relaxation and pain relief.
• Therefore plant defence compounds (or synthetic analogues of these compounds) offer the opportunity for development of useful medicines

Question 6

Discuss ways in which prey types are identified amongst existing and extinct species

Answer 6

Extant

• Direct observation eg. direct feeding, carcass damage and predator tracks.

Extinct and Extant

• Carbon-12 and Carbon-13 ratios in mammalian tooth enamel
• Ratios of 12C and 13C indicate whether animal is herbivore or carnivore
• Also indicate whether C4 or C3 plants are preferred in herbivores
• Can be used to determine prey types of fossilised predator remains (eg Soledad et als study into fossilised remains from same time/location looked at carbon ratios and the weights of predators and prey to determine which prey the predators would have taken)

Question 7

Explain the implications of predator–prey interactions for changes in the abundance of other components of the food web

THEME: INTERACTION

Answer 7

TROPHIC CASCADE - Changes in abundance of species at one trophic level due to changes in abundance at a higher or lower trophic level.

The stronger a predator-prey interaction the more likely the effect the abundance of one will effect the abundance of the other. This effect applies to all interactions within a food web; the relative abundance of one species can affect a variety of others up and down trophic levels.

Eg. Paine (1965) removed predator starfish P. ochraceus from intertidal zone and its prey, the mussel Mytilus californianus, increased vastly in abundance and ended up outcompeting other organisms in area to become dominant competitior. The removal of starfish affected all other organisms in area mediated through a competitive adavantage for the mussels.

These interactions can be tested

• In the field (by adding or removing an organism and seeing effect)
• In the lab (not as good as complex interactions in wild may be missed)
• Computer modelling

Question 8

TROPHIC CASCADE

Answer 8

Changes in abundance of species at one trophic level due to changes in abundance at a higher or lower trophic level. These can be top-down or bottom-up.

Question 9

Describe how power-law relationships arise in biology, especially with reference to body size

Answer 9

Power-law relationships arise in biology when a dependent variable eg BMR is linked to the mass of an organism raised to a certain power eg the power-law relationship of BMR and body mass (m) is BMR = 70m ^ 0.75

This relationship is ALLOMETRIC since it pertains to physiogical process and BODY SIZE specifically

This is because they relate to processes to different dimensions eg. Surface area (measured in two dimensions) vs mass (which is measured in 3 dimensions)

Surface area to volume (mass) ratios decrease as an animal gets larger

Question 10

Power-law relationships

Answer 10

Relationships between two variables in which the dependent variable is raised to a particular power of the independent variable, i.e. y = axb. An example is metabolic activity (y) and body size (x). The latter is an example of an allometric relationship.Power-lP

Question 11

Allometric relationships

Answer 11

Changes in organism function (e.g. physiology) with body size. Eg Changes in BMR in relation to body size

Question 12

Interpret phylogenies with age estimates

Answer 12

Phylogenies can be used to determine whether coevolution is ocurring between two clades (eg Cats and their respective papillomaviruses)

Similar phylogenies visually may mean that coevolution is occuring

Length and pattern of branches indicate level of change between each member and members molecular relationship

Members on same branch will be most similar as they have shared the same amount of changes

Length of a branch from the branch point represents number of nucleotide substituions present.