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exam 2 learning in a natural environment special case... flower learning

PART 4: BEHAVIORAL PLASTICITY #19: ASSOCIATIVE LEARNING IN HONEYBEES II. exam 2 learning in a natural environment special case... flower learning odor learning in the proboscis extension reflex summary. PART 4: BEHAVIORAL PLASTICITY #19: ASSOCIATIVE LEARNING IN HONEYBEES II. exam 2

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exam 2 learning in a natural environment special case... flower learning

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  1. PART 4: BEHAVIORAL PLASTICITY #19: ASSOCIATIVE LEARNING IN HONEYBEES II • exam 2 • learning in a natural environment • special case... flower learning • odor learning in the proboscis extension reflex • summary

  2. PART 4: BEHAVIORAL PLASTICITY #19: ASSOCIATIVE LEARNING IN HONEYBEES II • exam 2 • learning in a natural environment • special case... flower learning • odor learning in the proboscis extension reflex • summary

  3. SEMINAR • Dr. Spence Behmer • Department of Entomology, Texas A & M University • Friday, April 6th @ 3:30 WHI Auditorium • Grasshoppers and nutritional physiology: from learning to community structure • to supplement your enjoyment or if you can’t make the seminar… literature will be posted • be ready for one bonus question on the final

  4. ODOR LEARNING & PROBOSCIS EXTENTION REFLEX • PER from sucrose contact on proboscis or antennae • reliable in hungry bees • studied in the laboratory • used with odor for conditioning • some simple rules for learning...

  5. ODOR LEARNING & PROBOSCIS EXTENTION REFLEX • odor by itself does not elicit PER • classical or Pavlovian conditioning • US = sucrose • UR = PER • CS = odor • training: US + CS • test: CR = PER • bees learn that odor predicts sucrose reward

  6. ODOR LEARNING & PROBOSCIS EXTENTION REFLEX • in color experiment • classical or Pavlovian conditioning • US = sucrose • UR = feeding • CS = color • training: US + CS • test: CR =  preference • bees learn that color predicts sucrose reward

  7. ODOR LEARNING & PROBOSCIS EXTENTION REFLEX • CS (e.g., color) must precede US (sucrose)

  8. ODOR LEARNING & PROBOSCIS EXTENTION REFLEX • CS (e.g., pattern) must precede US (e.g., sucrose) • can use 2 CS stimuli = differential conditioning • CS+ = paired with US • CS– = not paired with US • CR = shift in preference for either training testing

  9. odor “B” (CS–) odor “A” (CS+) + shock (US) flies  choice point ODOR LEARNING & PROBOSCIS EXTENTION REFLEX • CS (e.g., odor) must precede US (e.g., shock) • can use 2 CS stimuli = differential conditioning • CS+ = paired with US • CS– = not paired with US • CR = shift in preference for either training testing

  10. ODOR LEARNING & PROBOSCIS EXTENTION REFLEX • CS (e.g., odor) must precede US (e.g., shock) • timing critical • determine interstimulus interval function

  11. ODOR LEARNING & PROBOSCIS EXTENTION REFLEX • interstimulus interval function determination in PER • CS = geraniol odor • US = sucrose • optimal response when CS preceeds US by 2-3s

  12. ODOR LEARNING & PROBOSCIS EXTENTION REFLEX • interstimulus interval function determination in PER • similar to color learning in free flying bees • CS = color • US = sucrose • optimal response when CS preceeds US by 2-3s

  13. ODOR LEARNING & PROBOSCIS EXTENTION REFLEX • acquisition function determination in PER • how fast do bees learn? • CS = odor • US = sucrose • asymptotic response with 3 trials • excitatory or faciliatory conditioning leads to CR 

  14. ODOR LEARNING & PROBOSCIS EXTENTION REFLEX • CS as predictor of the absence of US • how does unpaired CS pre-exposure influence CR? • CS = odor • US = sucrose • inhibitory conditioning reduces effect of training • CS is a less reliable predictor of US for the bees

  15. ODOR LEARNING & PROBOSCIS EXTENTION REFLEX • differential conditioning in PER • can it be reversed? • CS+ = odor A paired • CS– = odor B unpaired • US = sucrose • 1st generalize to odor, then differentiate with training • CR+ & CR– are opposite • reversal training = retrain bees to alternate odors

  16. ANATOMY OF PER • insect brains ~ vertebrate brains • fewer neurons • ~ complexity

  17. ANATOMY OF PER • insect brains ~ vertebrate brains • fewer neurons • ~ complexity • e.g., Drosophila

  18. ANATOMY OF PER • insect brains ~ vertebrate brains • fewer neurons • ~ complexity • e.g., Drosophila • sensory input

  19. ANATOMY OF PER • insect brains ~ vertebrate brains • fewer neurons • ~ complexity • e.g., Drosophila • sensory input • motor output

  20. ANATOMY OF PER • insect brains ~ vertebrate brains • fewer neurons • ~ complexity • e.g., Drosophila • sensory input • motor output • processing

  21. ANATOMY OF PER • insect brains ~ vertebrate brains • fewer neurons • ~ complexity • e.g., Drosophila • sensory input • motor output • processing • neuropile • cell bodies

  22. ANATOMY OF PER • honeybee brain • ~ 106 neurons • complex • what neuropiles mediate PER?

  23. ANATOMY OF PER • honeybee brain • ~ 106 neurons • complex • what neuropiles mediate PER? • CS

  24. ANATOMY OF PER • honeybee brain • ~ 106 neurons • complex • what neuropiles mediate PER? • CS • US + “VUM”

  25. ANATOMY OF PER • honeybee brain • ~ 106 neurons • complex • what neuropiles mediate PER? • CS • US • CS + US convergence?

  26. ANATOMY OF PER • CS + US convergence? • 3 regions tested using bilateral cooling: • antennal lobe • mushroom body -lobe • mushroom body -lobe

  27. ANATOMY OF PER • CS + US convergence? • 3 regions tested using bilateral cooling: • antennal lobe • mushroom body -lobe • mushroom body -lobe

  28. ANATOMY OF PER • CS + US convergence? • 3 regions tested using bilateral cooling: • antennal lobe • mushroom body -lobe • mushroom body -lobe • distributed function • MB most critical

  29. ANATOMY OF PER • CS + US convergence? • two specific neurons tested for PER functions: • PE1 • VUMmx1

  30. ANATOMY OF PER • CS + US convergence? • PE1 • dye filled

  31. ANATOMY OF PER • CS + US convergence? • PE1 • intracellular recordings • reduced response after training

  32. ANATOMY OF PER • CS + US convergence? • PE1 • intracellular recordings • qualitative change in response with multiple trials • may be change in PE1 or change in KC input • suggest PE1 involvement in memory acquisition

  33. ANATOMY OF PER • CS + US convergence? • VUMmx1 • ventral unpaired medial • dye filled • VERY extensive pattern of arborization • all areas of CS & US input

  34. ANATOMY OF PER • CS + US convergence? • VUMmx1 • intracellular recording • fires in response to sucrose application • triggers neural circuit  proboscis extension*

  35. ANATOMY OF PER • CS + US convergence? • VUMmx1 • substitute sugar with injected current • measurement of PER* • VUMmx1 provides US • current alone does  UR • separates sensory from US at neural level

  36. ANATOMY OF PER • CS + US convergence? • VUMmx1 • intracellular recordings •  spikes with forward conditioning only

  37. ANATOMY OF PER • CS + US convergence? • VUMmx1 • differential conditioning • intracellular recordings • responds to CS+ only

  38. ANATOMY OF PER • CS + US convergence? • VUMmx1 • 1st order conditioning • train: CS1 (odor A) + US1 (sugar) • test: CS1  CR1 (PER) • 2nd order conditioning • train: CS2 (odor B) + CS1 (odor A = US2) • test: CS2  CR2 (PER = CR1)

  39. ANATOMY OF PER • CS + US convergence? • VUMmx1 • octopamine transmitter • substitute sugar with octopamine injection @ • calyx • antennal lobe • measurement of PER* • VUMmx1 provides US

  40. LEARNING IN HONEYBEES: SUMMARY • learning necessary for survival in nature • several forms of learning • several modalities of learning • rapid learning • permanent memory in 3 trials • temporal requirements of learning critical • waggle dance • integrate stimuli • can learn complex patterns • can learn general environmental features

  41. LEARNING IN HONEYBEES: SUMMARY • proboscis extension reflex (PER) • show all features of learning described in vertebrates • temporal requirements of learning • differential conditioning • inhibitory learning • 2nd order conditioning • structures correlated with learning • mushroom bodies & antennal lobes • neurons correlated with learning • PE1 & VUMmx1

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