1. “Plant & Animal Responses”
Biology 3.3
“Plant & Animal Responses”

2. Tropisms

4. Plants grown on the ISS Grown in light + zero gravity
Grown in darkness + zero gravity

5. Plant Hormones (for chemists)
Auxin
Cytokinins (zeatin)
Gibberellins (GA3)
Abscisic Acid
Ethylene

6. Nasties

7. Kineses
Slater – Porcellio scaber

8. Slater – Porcellio scaber Hygrokinesis
Original: 1 frame/5 sec

9. The top half of the container is a high humidity environment
The top half of the container is a high humidity environment. The Bottom is a low humidity environment. Note that animals stay in the high humidity environment.
(Original: 1 frame/60 seconds)

10. Taxes

11. Slater Phototaxis
Task: Design and carry out an experiment using choice chambers to demonstrate whether or not slaters show phototaxis.
Consider: how MUCH of a difference in responses will be sufficient to be able able state that there is a REAL difference!

12. Slater Phototaxis (13 Bio 2012)
Aim: Do slaters prefer light or dark habitats?
Hypothesis: That slaters prefer dark habitats (because this will help them avoid desiccation)
Results:
Conclusions:

13. Slater Phototaxis (13 Bio 2011)
Aim: Do slaters prefer light or dark habitats?
Hypothesis: That slaters prefer dark habitats (because this will help them avoid desiccation)
Results:
Conclusions: Hypothesis proved correct, slaters prefer darker habitats. Slaters were nearly 5 times more likely to be found in the dark. We suspect, therefore, there is a strong preference to avoid drying out and being visible to predators.
"Do Slaters Show Phototaxis?"
Number of Slaters
Dark
Light
Average
9.0
1.9

14. Migration
NZ Shining Cuckoo: Breeds NZ + Chathams, migrates to Solomon Islands

15. Migration
Migration: the mass movement of a large number of animals of the same species often over a large distance.
Migration is an important response to seasonal environmental change. In true migration animals usually travel from one location where they breed to another where they feed and then they move back again.

16. Migration Features
Active (eg swimming), not passive dispersal (drifting in current)
Usually to feeding / breeding area
Usually two-way trip
Usually regular timing
Often long distance
Often at defined life stage
Initiated by internal clocks / timekeepers in resonse to environmental cues (eg temp. change, daylength change)
-’s risky and costly in terms of energy – death is the ultimate energy cost
+’s safe breeding grounds, avoid climate extremes, maintain food supply (seasonal, food supply used up)
Eg: salmon – adults migrate up rivers to spawn
Eg: humpback whale feed at pole in summer, breed in tropics
Moving on because of food source depletion (locust) might not count as migration.

17. Homing

18. Homing
Homing The ability of an animal to return to home over unfamiliar territory. Key Features Distances can be relatively short (may use familiar landmarks) Usually on a regular (eg daily, tidal) basis Involves navigation Examples Homing pigeons returning to loft Chitons to home indentation on a rock
Limpet ‘home scar’

19. Navigation

20. Bee Navigation Waggle Dance: uses solar navigation
In vertical hive combs:
Angle of dance to vertical indicates horizontal angle from sun to food
Speed, duration of waggle indicates closeness of food
(Must have a biological clock to account for the fact that the sun moves across the sky and the angle to the food will have changed by the time they get back to the hive).
Round Dance: indicates food closer than 50m
“go and look nearby and you’ll find food”

21. Female
Male
Monarch Navigation
Flight patterns appear to be inherited, based on a combination of the position of the sun in the sky and:
Time-compensated sun compass
based in their antennae.
New research shows: use the earth's magnetic field
Antennae protein is sensitive to violet/blue, in that light it can function as a chemical compass indicating alignment to magnetic field (or not). Can’t tell N/S

22. Timing Responses

23. Petrolisthes elongatus, half crab

24. Astronomical Cycles
Solar year – days (rotations) of Earth in one orbit (revolution) around the sun. Lunar month – 29.5 days between full moons Earth day – 23 h 56min 4.09s (to rotate on axis once) Seasons – Caused by tilt of Earth’s axis in conjunction with orbit around sun (23.5°) Tidal XXXXX

25. Actograms Actogram — chart commonly used to plot activity against time
24 hours 
Day
No Activity
Night
Activity

26. For the first 7-days mice were maintained under a 12-hour light: 12-hour dark cycle, and subsequently mice were maintained in constant darkness.
When the animal is placed into constant darkness, the period of the free-run driven by the endogenous clock at around 23.5 hour cycles, is apparent with activity starting earlier each day.
After 11 days in free-running constant darkness (identified by the grey arrow), a discrete light pulse was applied four hours after activity onset. Light at this phase of the circadian cycle produces a delaying shift in the endogenous molecular clock of cells in suprachiasmatic nucleus that is apparent in the onset of activity over the subsequent 10 days.
This combination of endogenous clock and ability to reset to light stimuli provides the entrainment to the daily light cycle and illustrates how we adjust when flying to different time zones.

27. What is happening here?

28. Animals bearing lesions of the SCN are unable to entrain to light:dark cycles, and rhythms in behavioral, neuroendocrine, and autonomic outflows become completely arrhythmic
An illustration of the effect of SCN lesions on a sample slave rhythm.  Under a 12:12 dark:light cycle, an intact nocturnal animal, such as a rat, is active during the dark phase of the DL cycle.  Almost immediately following ablation of the SCN (SCNX), the animal's rhythms become completely arrhythmic in the circadian time domain

31. My Body Temp Rhythm
Aim: to find out whether we can demonstrate our own daily temperature variation. Method: Hourly thermometer readings, at rest (as much continuous data as possible) Conclusions:

32.
Actually it is more than a simple strip chart, as it is a composite of four groups of humans. Each data point is an average of measurements taken at that particular time point from the whole group. Further, each group has been held at a different ambient temperature. Comparison of the four strip charts all plotted together tells us the amount of masking that environmetal temperature can exert on the clock-controlled rhythm of core body temp

33. SDP flower with short day and long night
SDP flower with short day and long night. But if you interrupt a long night with light then SDP don’t flower. This shows that the long nights make them flower as short nights (leaving the short day intact) stops them flowering.
LDP flower with long day and short night. But if you interrupt a long day with darkness then LDP still flower. This shows that the short nights make them flower as short days (leaving the short night intact) keepsw them flowering.

34. Social Organisation

35. Communication

37. President Carter while he brokered peace between Egypt and Israel in the late 70’s. I then documented his success on the North Lawn of the White House with a three-way handshake between Egypt’s Sadat, Israel’s Begin and Carter

38. Communication
Essential for organisms to interact appropriately with others of the species
Encompasses many types of signals
Visual: vervet monkey (shows blue testicles to indicate gender)
Touch: slaters (communicates presence, enable clumping behaviour)
Sound: blackbird (squawk when cat present)
Smell: skunk (warns predators)
The more complex the social organisation the more complex the signals.
Simple: Sheep – higher pitched baa “I’ve lost my baby”…not much other signals.
Complex: Chimps – grooming behaviour (maintaining social bonds)

39. Sexual Dimorphism
Pheasant m. f.
Nyala
Terrapin

40. Co-Operative Behaviour
Bees vs Hornets
(see text resource: