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Benefits of Grouping

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Alloparenting in Red ruffed lemurs (Varecia Ruvra) of the Masoala ... behavior appears be an integral part of the ruffed lemur's reproductive strategy ... – PowerPoint PPT presentation

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Title: Benefits of Grouping


1
Benefits of Groups
2
  • Predation
  • Foraging
  • Finding a Mate
  • Thermoregulation and Water Conservation

3
Predation
4
Reduced Risk of Predation
  • Anti-predator Vigilance
  • Dilution of risk
  • Predator confusion

5
Anti-predator Vigilance
  • Classic Many Eyes theory
  • suggests that more eyes are able to detect a
    predator earlier
  • as group size increases, individuals can decrease
    their own vigilance without increasing the risk
    of failing to detect an attack.

6
Sparrows and Finches, Pulliam, 1988
7
Dilution of Risk
  • As group size increases, individuals can reduce
    their risk of being killed by grouping, even when
    the risk that someone in the group will be
    captured stays constant.

8
Selfish Herds
  • Hamiltons Selfish Herd Theory
  • If a predator captures the first prey item that
    it comes across, then an individual animal is
    more vulnerable to predation than an animal
    within a group.

9
Confusion of Predators
  • There is an exponential decrease in predator
    success with increasing group size.
  • four different aquatic predators all were less
    successful at attacking prey fish in groups
    rather than individual fish
  • Neill Cullen, 1974

10
  • Foraging

Foraging
11
1.Locating Food
  • Less time spent looking for food
  • Benkman (1988) showed search time to best tree
    (49 seeds) reduced by 50 when foraging with a
    partner.
  • Fish play follow the leader. Reebs (2000)
    demonstrated that one knowledgeable fish could
    guide the rest of the shoal to food.

12
2.Catch difficult prey
  • Easier to catch large prey
  • Creel and Creel (1995)
  • African wild dogs 2025 kg whose major prey are
    ungulates ranging from 15 to 200 kg
  • This study showed that hunting success, prey mass
    and the probability of multiple kills increased
    with number of adults

13
3.Colonies/Roosts as Information Centres (or
mutual parasitism?)
  • Unsuccessful members of a colony can follow
    successful members to a food source.
  • Benefit to successful member? Another day he may
    need to follow a group member to food.

14
  • Wilkinson .G. (1991) showed that the evening bat
    (Nycticeius humeralis) transfers information
    about the location and abundance of food patches
    to the rest of the group.
  • Vampire Bats live in colonies, an unsuccessful
    member can persuade a successful neighbour to
    donate blood. The benefit will be returned to the
    donating bat another night when he has been
    unsuccessful.

15
4. Vigilance
  • ? chance that a predator will be spotted with
    increasing group size
  • Ex. Ostrichs - the larger the group size, the
    more time spent foraging
  • Ex. Clutton-Brock et al (1999)
  • Meerkats - Sentinels allow increased foraging
    time for others

16
5.Harvesting Renewing Food
  • Group foraging most efficient manner with which
    to exploit habitats with renewing patches as
    individuals in groups are less likely to revisit
    patches that have already been exploited recently
    by others.
  • Brent Geese and sea plantain. Geese leave 4 day
    gap intervals before revisiting patch.

17
Finding a Mate
18
Finding A Mate
  • Sexual behaviour is a current hot topic in
    behavioural ecology
  • The benefits associated with breeding in groups
    have received a great deal of sampling over the
    past number of years
  • Benefits include increased matings, increased
    reproductive success, alloparenting, inclusive
    fitness

19
  • Being in a group where you may not be the most
    handsome or biggest male may not be so bad!
  • Cooperation of males to get rid of dominant male
  • Inclusive fitness in courtship displays

20
  • Alloparenting in Red ruffed lemurs (Varecia
    Ruvra) of the Masoala Peninsula, Madagascar
  • Natalie Vasey

21
  • Mating occurs both within and between core
    groups- polygamous system
  • Two months after birth, core group members range
    more widely, and the network of care providers
    grows larger
  • Among the types of allocare provided are
    allonursing, co-stashing, infant guarding, and
    adoption

22
  • Alloparenting behavior appears be an integral
    part of the ruffed lemur's reproductive strategy
  • Improving survivorship of young by protection
  • Also the fitness of parents- more time to forage
    and socially engage with others

23
  • Have winter spacing patterns of Harlequin Ducks
    been partially shaped by sexual selection?
  • Rodway, Michael S

24
  • Typically dispersed in small groups
  • Sexually-selected changes in spacing to
    facilitate courtship and mate sampling
  • Behaviour similar to lekking was observed

25

Thermoregulation and Water Conservation

26
Thermoregulation
  • is the maintenance of an internal body
    temperature within a range.
  • Need to conserve heat.
  • Solitary animals may find it difficult to cover
    the cost of this.
  • Social animals share the cost of keeping warm
    between them

27
Conserving heat.
  • There are a number of ways which animals may
    conserve heat
  • Huddling
  • Warming the air around them, which works for
    those who live in confined spaces such as
    burrows.
  • - initial cost involved
  • - saving energy in the long run.

28
Huddling
  • two or more individuals in close contact with
    each other.
  • Reduces surface area - to - volume ratio, and so
    there is less exposed surface area over which
    heat can be lost.
  • Assumes that both of the sides in contact are the
    same temperature, therefore there is no heat
    loss.
  • This benefit increases with group size.
  • It is seen in a number of bird, insect and
    mammalian species.

29
Kotze et al. (2008) experiment
  • Damaraland Mole Rat Vs Natal Mole Rat.
  • Compare energetics of huddling in both.
  • Measured oxygen consumption (VO2) in groups
    ranging from 1 to 15 in size at different ambient
    temperatures (14, 18, 22, 26, 30oC)
  • Results
  • VO2 increased with increasing group size.
  • D. VO2 gt N. VO2

30
Emperor Penguins
  • Two experiments
  • Gilbert (1996) Male penguins spend only 38 18
    of incubation period huddling with other
    incubating males.
  • Temperature during this period is over 20oC for
    about 13 12 of huddling time.
  • - Allows all males to get equal and regular
    access to a warm environment, allowing them to
    save energy to successfully incubate their eggs.

31
Emperor Penguins
  • G.H. Visser(2007)
  • Compares males who huddle, and those that dont
    while incubating eggs.
  • Group 1 Incubating and Huddle.
  • Group 2 Just Incubating.
  • Results
  • Incubating alone resulted in an elevation rate
    of 20, store of fats diminished fairly fast and
    a higher incidence of egg desertion.

32
More Examples
  • Birds roosting Best way to conserve energy?
  • Beauchamp (1999) any energy saved in roosting
    is spent on the transport to get to the roosting
    sites.
  • Honeybees increase their heat production and
    huddle together to retain heat.
  • Deer mice initial socialisation is expensive but
    thermal conductance and mass specific metabolic
    rate by 30 within 5 days (Andrews, 1986).

33
Water Conservation
  • Better for those on periphery of group.
  • Many animals cluster so as to conserve water, e.g
    slugs pack close so that large areas of their
    flanks are in contact gt minimising area over
    which evaporation can occur.
  • Many animals will lay their eggs in clusters so
    they are protected from desiccation.

34
Desiccation Hypothesis
  • Stamp (1980) egg clustering is adaptive per se
    by reducing egg mortality due to desiccation.
  • Clark and Faeth (1997) Natural variation and
    Experimental variation in cluster size and the
    success of the hatches at varying levels of
    controlled humidity.
  • Found that hatch successes were positively
    related to relative humidity.
  • Layers also helped in water conservation.
  • Support for Hypothesis North American
    Lepidopteran species cluster their eggs tightly,
    those in tropical areas lay eggs singly or in
    loose monolayers.

35
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36
References
  • Andrews, R. V., Belknap, R. W., (1986),
    Bioenergetic benefits of huddling by deer mice
    (Peromyscus maniculatus), Comparative
    Biochemistry and Physiology. A, Comparative
    Physiology, 85(4), 775-778
  • Benkman, C. W., 1988, Flock size, food dispersion
    and the feeding behaviour of Crossbills.
    Behavioural Ecology and Sociobiology, 23, 167-75
  • Benkman, C.W., and Pulliam, H.R. (1988). The
    Comparative Feeding Rates of North American
    Sparrows and Finches. Ecology, 69, 1195-1199.
  • Clark, B. R., Faeth, S. H., (1998), The evolution
    of egg clustering in butterflies A test of the
    egg desiccation hypothesis, Evolutionary Ecology,
    12, 5, 543-552
  • Clutton-Brock, T. H., O'Riain, M. J., Brotherton,
    P. N. M., Gaynor, D., Kansky, R., Griffin, A. S.
    and Manser, M. (1999), Selfish Sentinels in
    Cooperative Mammals. Science, 2845420, 1640-44
  • Creel, S. and Creel, N.,M. (1995), Communal
    hunting and pack size in African wild dogs,
    Lycaon pictus, Animal Behaviour, 50, 1325-39

37
  • Gilbert, C., (2006), Huddling behaviour in
    Emperor penguins dynamics of huddling.
    Physiology and Behaviour, 88, 4-5, 479-488
  • Hamilton,W.D. (1971). Geometry for Selfish Herd.
    Journal of Theoretical Biology, 31, 295.
  • Kotze, J., Bennett, N. C., Scantlebury, M.,
    (2008), The energetics of huddling in two species
    of Mole-rat (RodentiaBathyergidae), Physiology
    and Behaviour, 93, 1-2, 215-221
  • Lima,S.L. (1993). Back to the basics of
    anti-predatory vigilance the group-size effect
    Animal Behaviour , 58 , 3 , 537 - 543
  • Neill, S. R. St. J. and Cullen, J. M. (1974).
    Experiments on whether schooling of prey affects
    hunting behaviour of cephalopods and fish
    predators. Journal of Zoology, 170, 549-69
  • Reebs, S.G, (2000), Can a minority of informed
    leaders determine the foraging movements of a
    fish shoal?, Animal Behaviour, 59, 403-409

38
  • Wilkinson, G., (1992), Information transfer at
    evening bat colonies, Animal Behaviour, 44,
    501-518
  • Visser, G. H., (2007), Regulation of energy
    expenditure in free-living animals under extreme
    conditions, Appetite, 49, 1, 338
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