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Diversity of reproduction Asexual reproduction Parthenogenesis Hermaphrodites Sequential hermaphrodites - protogyny (F  M) or protoandry (M  F) Sexual.

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Presentation on theme: "Diversity of reproduction Asexual reproduction Parthenogenesis Hermaphrodites Sequential hermaphrodites - protogyny (F  M) or protoandry (M  F) Sexual."— Presentation transcript:

1 Diversity of reproduction Asexual reproduction Parthenogenesis Hermaphrodites Sequential hermaphrodites - protogyny (F  M) or protoandry (M  F) Sexual reproduction

2 Male/female reproductive strategy Asymmetrical gamete size (anisogamy) means the sex with smaller gametes should usually compete for access to the sex with larger gametes. This results in greater variation among males than among females for reproductive success.

3 Males should, therefore, fight over females and females should select for resources Sexual selection - The advantage which certain individuals have over others of the same sex and species, in exclusive relation to reproduction (Darwin, 1871)

4 A form of natural selection that occurs when individuals vary in their ability to compete with others for mates or in their attractiveness to members of the opposite sex. As with natural selection, sexual selection leads to genetic changes in the population over time

5 Intrasexual selection Competition for copulation Dominance Alternatives: friendship with females male coalition female mimicry satellite males forced copulation

6 Competition for fertilization Sperm competition Physical, chemical, mate guarding, etc Competition after fertilization Bruce effect Infanticide

7 Female choice Unequivocal female preference, not a result of male competition Choice based on "genetic quality “ runaway selection — Fisher good genes (survival skill) handicap principle — Zahavi rare male effect

8 Choice based on 'non-genetic' benefit resource defense parental ability Mating systems: monogamy, polygyny, polyandry, promiscuity

9 Cooperation or mutualism-- a mutually helpful action Reciprocal altruism (reciprocity)-- a helpful action that will be repaid in the future by the recipient Altruism-- helpful behavior that raises the recipient's direct fitness while lowering the donor's direct fitness

10 Kin selection A form of selection in which alleles differ in their rate of propagation because they influence the survival of kin who carry the same allele

11 Indirect fitness-- the genes contributed by an individual indirectly by helping non-descendant kin, in effect creating relatives that would not have existed without the help inclusive fitness-- the sum of an individual's direct and indirect fitness B/C > 1/ r or rB - C > 0

12 Cooperative breeding a social systems in which some group members defer their own reproduction, even as adults, and help care for the young of a few breeding individuals Helpers are typically (but not always) related to breeders and are often individuals that do not disperse instead aid in the rearing of their siblings

13 found in only about 3% of birds and mammals (roughly 200-300 bird species and about 120 mammal species) Helper's duties--feeding, carrying, huddling, babysitting, grooming, defense, teaching, incubation, etc. Do helpers really help?

14 Increase breeding success correlation approach exp. removal of helper Increase number of breeding free females from caring fledgling Increase breeder survivorship

15 Social behavior Societies--groups of conspecifics organized in a cooperative manner Evolutionary advantages of living in groups Protection from physical factors Protection against predator Assembling for mates Finding resources, beater effect, overwhelm prey

16 Group defense of resources Division of labors among specialists Richer learning environment for young that develop slowly, social facilitation Cooperative defense against predator Increase vigilance, alarm Dilution effect Selfish herd hypothesis Mobbing, fight back

17 Evolutionary disadvantages of group living Increase competition Increase chances of spreading diseases and parasites Interference with reproduction Reduce fitness due to inbreeding Attracting predators

18 Eusocial insect cooperative care of young reproductive castes overlap between generations

19 Possible explanations for worker sterility Kin selection – haplodiploidy But, they are more closely related to their own male offspring (r = 1/2) and their nephews (r = 3/8) than their brothers (r = 1/4). Therefore, expect workers to lay unfertilized eggs

20 If mothers are polyandrous (mate multiple times), then workers may be more closely related to their brothers than to half-nephews (r=1/8). Expect workers to kill unfertilized eggs laid by other workers. Example: honeybees and yellowjackets are polyandrous and have low levels of worker reproduction

21 What about diploid eusocial animals (e.g. termites, naked mole rats)? One proposed hypothesis is that these populations undergo cycles of inbreeding. With high levels of inbreeding-mother-son and sister brother can rapid approach r>3/4 for both males and females.

22 But high levels of inbreeding can lead to inbreeding depression Thus inbreeding might alternate with some dispersal. A rare disperser morph is found in mole rats: it is fatter, attempts to disperse in captive settings, solicits mating with non- colony members. Once settled reverts to xenophobia and loses fat stores


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