SOCIALITY IN INSECTS

1. SOCIALITY IN INSECTS

2. Social Insects - Importance One colony - 306,000,000 workers - 1,000,000 queens - 45,000 interconnected nests - 2.7 km2 Formica yessensis

3. Social Insects - Importance Pollinators

4. Sociality Eusociality 1. Division of labour with caste system 2. Cooperation in tending young 3. Overlap of generations Subsociality

5. Subsocial Groups 1. Aggregations - non reproductive Pentatomid bugs

6. Subsocial Groups 1. Aggregations - non reproductive Monarch (Danaus) butterflies

7. Subsociality - parental care Oviposition preferences - Corixidae % on each substrate Wood Plexiglas Elodea - Aiken ‘81

8. Subsociality - parental care Male Abedus

9. Subsociality - parental care a) Without nesting - remove tending parent Predation Parasitism Diseases

10. Subsociality - parental care a) Without nesting Membracidae (treehoppers - Homoptera) Bugs - secrete honeydew Attracts ants Ants deter predators Female bugs leave early

11. SO FAR: Subsociality Aggregations Parental care Without nesting With nesting Solitary nesting Communal nesting

12. Parental Care - With Nesting Nest - parents use or make some structure - lay eggs - provision young Found in - Orthoptera - Dermaptera - Coleoptera - Hymenoptera Dermaptera (earwigs)

13. Solitary Nesting in the Hymenoptera - immoblize arthropod prey and provision young 1. Provision prey in its own burrow 2. Dig burrow after prey capture 3. Dig burrow before prey capture 4. Build a solitary structure 5. Build structures in aggregations

14. Subsociality in other Orders Homoptera - aphids Normal nymph “Soldier” nymph

15. Subsociality in other Orders Thysanoptera - thrips Normal female Soldier nymph

16. Quasi- and Semisociality - subsocial - all females reproduce Quasisocial - communal nest - members of same generation - all assist in brood rearing - all females can lay eggs Semisocial - communal nest - members of same generation - all assist in brood rearing - only 1 female can lay eggs - females are sisters (not daughters of queen)

17. Quasi- and Semisociality In Social Hymenoptera -division of labour -variability in fecundity Fully reproductive Reduced fecundity in groups halictine bees Quasisocial Some lay only male eggs (workers of Bombus) Worker sterility Super reproductive queen Semisocial

18. solitary eusocial Sociality among groups of Hymenoptera subsocial Apinae Megachilinae Adreninae Colletinae Halictinae Crabronidae Sphecidae Other vespoids Formicidae Scoliiidae Eumeninae Stenogastrinae Polistinae Vespinae Chrysidoidea Rest of Apocrita

19. Eusocial Hymenoptera

20. Eusocial Hymenoptera Fertilized 2N Egg (Female[worker]) Unfertilized N Egg (Male[drone])

21. Eusocial Hymenoptera Wasps Founding queen -builds nest -produces and feeds first brood Stops foraging -becomes purely reproductive Later in season - produce more males and new queens

22. Eusocial Hymenoptera Wasps Jobs of workers YOUNG MIDDLE AGE -distribution of protein-rich food to larvae -distribution of carbohydrate-rich food to adults OLD -clean cells and dispose of dead larvae -ventilation and air-conditioning of nest -construction and repair of nest -foraging - wood pulp, fluids, prey -nest defence

23. Caste Differentiation in Bees

24. Caste Differentiation in Bees Royal Jelly

25. Caste Differentiation in Bees Royal Jelly Hypopharyngeal glands

26. Caste Differentiation in Bees Royal Jelly

27. Caste Differentiation in Bees Royal Jelly Protein Carbohydrate Lipid N D J F A M J J A

28. Eusociality in Termites Reproductive castes Primary reproductives - King + Queen Supplementary reproductives - Neotenics Workers Non-reproductive castes Soldiers

29. Assumption: Subsociality is a necessary precursor for (and primitive to) eusociality Cryptocercus - a wood roach - Blattodea √ - symbionts in hind gut √ • colonies - mated pair • + 15  25 offspring - transfer symbionts by eating exuviae - nymphs help in nest maintenance √ Conclusion: These animals represent an evolutionary precursor to Isoptera (termites)

30. Assumption: Subsociality is a necessary precursor for (and primitive to) eusociality BLATTODEA Polyphagidae (including Cryptocercus) ISOPTERA Other families MANTODEA

31. Termitidae - Pathways for Caste Development Large worker 5 Alate Nymph 5 Large worker 4 Nymph 4 Small soldier Large soldier Large worker 3 Nymph 3 Small presoldier Small worker 2 Large presoldier Large worker 2 Nymph 2 Small worker 1 Large worker 1 Nymph 1 Small larvae (2nd) Large larvae (2nd) Larva (1st) egg King + Queen

32. Caste Development in Lower Termites Hormonal Control of Castes 1. Remove King and Queen 2. Divide colony with membrane 1. Re-introduce King and Queen - into membrane No change Pseudergates develop into reproductives

33. Why should a female bee (adult) sacrifice her own reproduction for that of the colony ? ?

34. Kin Selection and Inclusive Fitness Fitness comes from Your own reproduction Reproduction of relatives Inclusive Fitness

35. In Social Hymenoptera Sperm contain 100% of paternal genes Males are haploid - N Females are diploid - 2N Eggs contain 50% of maternal genes  Offspring (daughters/workers) -have all of father’s genes Full sisters share 3/4 of their genes -have 1/2 of mother’s genes  Workers are more related to each other than their mother