The Evolution of Mating Systems Chapter 11 Alcock (Animal Behavior) Tom Wenseleers
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The Evolution of Mating Systems Chapter 11 Alcock (Animal Behavior) Tom Wenseleers Ethology & Ethology & Behavioural Behavioural Ecology Ecology
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The Evolution of Mating Systems Chapter 11 Alcock (Animal Behavior) Tom Wenseleers. Ethology & Behavioural Ecology. Aims & Objectives. Aims Present the concept of alternative "mating systems" Present a simple mathematical model for male monogyny - PowerPoint PPT Presentation
Transcript of The Evolution of Mating Systems Chapter 11 Alcock (Animal Behavior) Tom Wenseleers
The Evolution of Mating SystemsChapter 11 Alcock (Animal Behavior)
Tom Wenseleers
Ethology & Ethology & Behavioural Behavioural
EcologyEcology
Aims & Objectives• Aims
– Present the concept of alternative "mating systems"– Present a simple mathematical model for male monogyny– Present examples of different mating systems and factors
that favour these particular mating systems
• Objectives– Learn examples– Understand the underlying logic in the model of male
monogyny– Understand why different conditions can favour different
mating systems
Mating SystemsThere are many different mating systems including
Monogamy one partnerPolygamy more than one partner
Polygyny one male, multiple femalesPolyandry one female, multiple malesPolygynandry multiple females, multiple males
Social monogamy nesting with one partnerGenetic monogamy offspring from one partnerEPC extra-pair copulation
What is the cause of these different mating systems? Why, for example, does the male honeybee have a maximum of one partner and one mating while a male wool carder bee may mate hundreds of times with many different partners?
1. Monogamy
Prolonged, essentially exclusive bond maintained with one member of opposite sex.
Generally a rare system.
Rare in mammals (except for some rodents,primates and dogs).
However, is commonest avian mating system.
Monogamy
Evolutionary puzzle: Males generally provide little resources to young and have an abudance of sperm with which they could fertilize several females. Hence, males would be expected to benefit from seeking extra mates (see previous lecture)
Why don’t they?
Monogamy is an armed compromise rather than a happy collaboration.
Puzzle: Male monogamy
Several hypotheses:
1. Mate-guarding hypothesis
2. Mate-assistance hypothesis
3. Female-enforced monogamy
Male monogamy
Monogamy may be best choice if female would mate again if male deserted her and if 2nd male would fertilize eggs.
1. Mate-guarding hypothesis (MGH)
Mate guarding should pay off when females:1. Are scarce and hard to find.2. Remain receptive after mating.
Example:Clown shrimp
Receptive females are scarce and widely distributed
1. Mate-guarding hypothesis (MGH)
Honeybee drones mate only once and die after mating. The drone's genitalia break off during mating to form a mating plug. This does not stop the queen from mating with additional males during her mating flight, but it does prevent sperm from leaking out.
Male suicide as mate-guarding
As we saw in previous lecture, the male redback spider may sacrifice his life during mating by placing his body directly into the female's jaws.
Benefit: greater paternity from current mating. If the male was the first male to mate the female then the female is less likely to remate. If the male was the second male to mate the female then more of his sperm will fertilize her eggs.
Cost: reduced or zero future matings.
Cost vs. Benefit: when is male sacrifice favoured?
Male suicide as mate-guarding
Costs vs. benefits of male sacrificeIn most animals: equal numbers of mature males and females Redback spiders & honey bees: excess of males
Redbacks: males mature when small, so lower mortalityHoneybees: 1000s of males reared for each queen
Large male:female ratio favours male monogamy. Males will have lower mating success than females and males are less likely to have multiple partners simply because females are rarer than males.
Makes it more worthwile to increase the paternity success of the current mating even at a cost of fewer additional matings.
The current mating is made more successful by plugging the queen to stop sperm leaking out or by prolonging the mating of the female spider to reduce her chances of remating.
• Simple mathematical model to investigate when male sacrifice is worthwile. Under what circumstances will a male who is mating with an unmated female have more offspring if he sacrifices his life to prevent her from mating again?
• We set up the following parameters
X = the ratio of mature males to femalesfor an even sex-ratio X=1, for male bias X>1
Y = the number of offspring that a female has (cancels out)
N = the number of mates per female, if not prevented by a male
• The number of offspring of a sacrificing male who is mating with a previously unmated female = Y
• The number of offspring of a non-sacrificing male who is mating with a previously unmated female = Y/N + Y/X. The Y/X is from future mating opportunities and the 1/X comes about because the male must compete with all the other males.
Costs vs. benefits of male sacrifice
not in textbook!
• The sacrificing male strategy is better if it results in more offspring. That is, if the following inequality is true:Y > Y/N + Y/X1 > 1/N + 1/X
• This is more likely to be true ifN is large females mate with many malesX is large male biased sex ratio
• It can never be true ifN is one females only ever mate to one maleX is one or less males not more numerous than females
• Translate back to biologyMale sacrifice is more likely when females mate with many males and when the sex ratio is highly male biased. This confirms our intuition.
Costs vs. benefits of male sacrifice
Male stays with partner because male assistance increases youngs’ survival.
Increased survival of young outweighs extra young gained by seeking extra mate.
2. Mate-assistance hypothesis (MAH)
2. Mate-assistance hypothesis (MAH)
Example: Seahorse Hippocampus sp.
Males carry eggs in a sealed brood pouch for over ca. 3 weeks.
Male-female relationship is durable. They greet each other in the morning and ignore other seahorses of the opposite sex.
Male can hold only one clutch, so no benefit in courting extra females.
Females choose monogamy because males are scarce and because females are poor swimmers and thus vulnerable to predators.
In some species females actively preventmales obtaining extra mates.
3. Female-enforced monogamy hypothesis (FEMH)
Burying beetles, Necrophorus spp., are common in Belgium. The beetles are attracted to small mammal and bird corpses which they bury. The male and female and sometimes additional males and females build a nest containing the corpses and tend the larvae. Males benefit from attracting a second female, but first female does not. Hence, a female burying beetle will attack her mate ifhe tries to release pheromones to attract other females.
Burying beetle: female-enforced monogamy
Burying beetle
After setting up the nest with the female, the male may try to attract a second female by emitting pheromone. This will be good for the male but not so good for the female as there will be increased competition for the food to rear the offspring. When the first female smells pheromone she pushes the male off his signalling perch. If the female is tethered she cannot do this and the male can signal more.
Burying beetle: female-enforced monogamy
Razorbills: female enforced monogamy
Males might benefit from additional partners but females may prevent them from doing so to monopolise their parental assistance.
Razorbills nest in aggregations on cliffs.
Females attack males that show an interest in a neighbouring female.
Monogamy in mammals• The mammalian traits of pregnancy and milk production by
females make parental investment and care of offspring female biased. This should select for polygyny. Most mammals indeed are, but monogamy occurs in a few rare cases.
• Monogamy in mammals may be connected with mate guarding. Social monogamy is correlated with situations in which females live apart in small territories, e.g. in possums. Mate assistance hypothesis may also apply to species with male parental care, e.g. some primates incl. humans, some rodents.
• Polygynous males would have to leave a female while looking for other females. When they do this they leave themselves open to cuckoldry.
Mate guarding: rock-haunting possum
Mate-guarding is facilitated by thesmall, discrete home ranges occupiedby females of the rock-haunting possum.
Mate assistance: Djungarian hamster Monogamous & male parental care
Male helps infants being born.
But: association between monogamy and male care not significant for all rodents or for primates overall.
Mate assistance: male care increases offspring numbers
Male care of offspring affects fitness in the California mouse.
Monogamy in birds
Most, 90%, of bird species have social monogamy. In some birds there is also genetic monogamy, but in ca. 70% of birds with social monogamy some of the female's offspring result from "extra-pair copulation" (EPCs) from non-partner males.
Similar in Florida Scub Jay(struikgaai)
Common Loon (ijsduiker). DNA study of 58 youngfrom 47 families. All were offspring of the birdsthat raised them.
Comparing birds and mammals
Why is social monogamy more common in birds than in mammals?
Male assistance hypothesis: male birds, unlike male mammals, can feed young as well as females.
A key prediction is that male parental care should increase the number of surviving young. This can be readily tested.
Male parental care in birds increases the number of surviving young
(zwarte spreeuw)
In the spotless starling, males whose testosterone levels were reduced by the anti-androgen cyproterone acetate (CA) provided more food for their broods and had the highest fledging rate per brood. Males given extra testosterone (T) provided less food and had the lowest fledging rate. Untreated controls were intermediate with respect to both feeding and fledging rates.
Male assistance in Snow Buntings (sneeuwgors) is essential to rearing young.
Females whose males were removed reared fewer than 3 young. Those with males reared 4 or more.
Male parental care in birds increases the number of surviving young
In a population of starlings (spreeuwen) where some males helped their mates incubate their eggs and others did not, the clutches with biparental care stayed warmer. As a result, 97% of the eggs with biparental care hatched, vs. 75% for eggs with female uniparental care.
Male parental care in birds increases the number of surviving young
In many birds raising young is so hard, it takes a pair to rear even one young (e.g. albatrosses).
Monogyny in albatross: MAH
In Tree Swallows polygynous males with multiple female partners father fewer surviving young (0.8 fledglings) than monogamous males (3.0 fledglings). MAH: More offspring of polygynous males die because male can’t help both females.MGH: Females of polygynous males also mate with other males because male cannot guard two females effectively.Monogamy best for both male and female Tree Swallows.
Monogyny in tree swallow: MAH & MGH
2a. Polyandry
Puzzle: Female polyandryAnother evolutionary puzzle is female polyandry. Expected that females cannot greatly increase the number of offspring by having multiple partners.
However, by having multiple partners a female may be able to increase the number of offspring somewhat. For example, by mating with two males she is less likely not to be fertilized successfully.
In addition, by mating with several males a female may benefit from additional paternal care to her young.
By mating with several males, a female may also be able to increase the quality of her young.
There are a wide range of hypotheses for "multiple mating" by females, all based on the idea that the female benefits from mating with multiple males.
Even though monogamous males assistone primary female, males also seek EPC’s.
DNA fingerprinting and microsatellite analysishas shown EPC’s to be very common, occuringin ca. 70% of all socially monogamous birds.
Male benefits of EPC’s are obvious (increased offspring at low cost).But why would females seek EPC’s?
Extra-pair copulations (EPC’s) in birds
Why Female Polyandry or EPCs?
Fertility insurance: Gunnison' prairy dogs
Monandrous females pregant 92% of the time.
Polyandrous females pregnant 100% of the time.
Female red-winged blackbirds (epauletspreeuw) who mate with multiple males have higher egg hatching rates.
Fertility insurance: EPCs in red-winged blackbird
Female yellow-toothed guinea pigs who mate with multiple males have fewer stillborn young.
Fertility insurance: yellow-toothed guinea pigs
Good genes: Crickets
Female crickets were given a choice of two males. They mated with one (S) and not the other (U). Male offspring of the S and U males were reared and themselves tested. Offspring of S males were more attractive to females. This shows that a female who is already mated may benefit from mating with a "sexy" male as her own male offspring will be more successful. The female will then have more grand-offspring.
Genetic compatibility: bluethroat
Young of the bluethroat have a stronger immune response when they are the result of an extra-pair copulation (EPY) than when they are the result of a within-pair copulation (WPY).
Genetic compatibility: pseudoscorpions
Polyandry boosts female reproductive success in a pseudoscorpion in the lab. Genetic analysis has shown that also in the field females mate with several males.
More resources: blackbirds
Red-winged blackbird (epauletspreeuw) females are allowed to forage on territories of males with whom they've engaged in EPCs. Truly monogamous females are chased away.
More resources: megachilid bees
By mating with many males, females of this megachilid bee gain access to pollen and nectar in those males' territories.
More resources: butterflies
In many insects (including hanging flies, crickets, butterflies) males transfer resources to the female during mating. Extra partners may mean extra nuptial gifts. This is supported by these data from 8 species of Pierid butterflies where males transfer a nutritionally valuable spermatophore.
More resources: Dunnocks
In Dunnocks, a female may have two partners. However, a male will only provide parental care if there is a chance that he is a father of the female's offspring. He does not determine this directly, but indirectly by whether or not he mated with the female. By allowing both males to mate with her, the female gets both to help feed the offspring.
2b. Polygyny
Examples : Birds: Lark Bunting (dikbekgors),
Red-winged Blackbird (epauletspreeuw)Dunnock (heggemus)Marsh Wren (moeraswinterkoning)
Marsh Wren
Polygyny: One male mates with two or more females
Mammals: Lions, Gorillas, Bats.Also found in many fish, insects, etc.
1. Female defense Polygyny
2. Resource defense Polygyny
3. Scramble competition Polygyny
4. Lek Polygyny
Four basic types of polygyny
PolygynyFemale defence polygyny
Females in breeding condition aggregate. Males may then be able to monopolise a group of females. For example, male red deer or elephant seals. Males often fight with each other to control the females.
Resource defence polygyny
Females in breeding condition need access to some scarce resource. Males may be able to monopolize this resource. Females must allow the male to mate with them to have access to the resource. For example, wool carder bees. Males often fight with each other to control the resource.
Common when females cluster in groups thatare defensible.
Males then become polygynous by defendingsuch clusters against other males.
1. Female defense Polygyny
E.g. Elephant seals, lion prides, elk and deerherds.
In some marine siphonoecetine amphipods,which build protective cases out of gravel and shells, males collect females and glue their houses to their own.
Female defense polygyny in the greater spear-nosed bat
Large male (bottom) guards a roosting cluster of smaller females.
In general, female defense polygyny possible because females cluster for their own reasonsand males exploit this.
E.g. Lionesses cluster to defend feeding territories.
Deer gather for protection.
Elephant seals gather on the few suitable nursery beaches.
Polygyny may be costly for females
Number of offspring per female decreases with the number of females in themale harem. Females still remain part of the harem simply because driving off all other females might be costly.
Male becomes polygynous by defending a resource that females need to produce young (food, nesting sites).
2. Resource defense polygyny
Resource defense polygyny in an African cichlid
African cichlid fish Lamprologus callipterus exhibits extreme sexual dimorphism (males 13X times larger than females).
Females lay eggs inside empty snail shells and remain inside shell until eggs hatch.
Males gather shells into large collections and defend them from rival males. The more shells the male can collect the more nesting sites it provides for females. Up to 86 shells have been recorded in one collection and up to 14 females at once. Extremely large male body size has been selected for because it enables males to collect shells and to defend their territories. But small sneaker-males co-occur in some species (e.g. Telmatochromis vittatus).
Resource defense polygyny in an African cichlid
Resource defense polygyny in the black winged damselfly
Male black-winged damselflies defend territories containing floating aquatic vegetation that females prefer to lay eggs on.
male(grote wolbij)
Resource defense polygyny in the carder bee (Anthidium manicatum)
Females collect plant hairs to use in nest building, hence the name wool carder bee. The males defend patches of flowers and aggressively drive off or even kill other bees.
The female has to mate with the male to be allowed to forage on his patch of flowers. This is termed resource defence polygyny.
The male gets to have more than one female as he controls a resource that is valuable to the females.
female
Some females choose to mate with males that already have a mate and who will not help them feed their chicks even though males without a mate with territories are still available.
Why would a female do this?
Polygyny threshold model: predicts that female will accept role of 2nd mate (polygyny) when superior resources on males territory mean that female would do better there than as 1st mate on a poor territory.
Polygyny threshold model
Polygyny threshold model
Curves represent payoffs to female. Femalecan choose between males A and B. A hasa mate, B is unmated.
Male Red-winged Blackbirds hold territoryon marshes. Males with the best territoriesattract harems of up to 15 females.
Females choose males on the basis ofterritory quality.
Male’s red epaulettes are essential in male-malecompetition.
Resource defense polygyny in red-winged blackbird
Male Lark Buntings (dikbekgors) establish territories in grassy, open habitats. Mate with > 1 female but assist only first female to settle on their territory. Some female LB’s accept secondary female role on good territory to obtain a high quality nesting site. In bad nest sites young die from exposure to the sun.
Polygyny threshold model: Lark Bunting
Some male Pied Flycatchers establish two territories. Sing to attract a female. Males provide little help to female on 2nd territory, so female has low reproductive success.
Polygyny threshold model: pied flycatcher
Each female mated to a polygynous male has lower reproductive success than a monogamous female. However, males' r.s. is higher than that of a monogamous male.
Male Pied Flycatchers clearly try to deceive females into polygyny.
Not clear yet if females really fooled or have no better alternative.
Polygyny threshold model: pied flycatcher
3. Scamble competition Polygyny
When receptive females are widely dispersed males are best off not be territorial, but just to try the hardest to find a female. May result in one male mating with several females. E.g. Photinus fireflies.
Other type of scramble competition polygyny: explosive breeding assemblage, when breeding season is highly compressed. Mad scramble for position to fertilize eggs. E.g. frogs, horseshoe crab. Usually associated with external fertilisation.
In lekking species males display for females at a predictable location (a lek) and females come to the site to choose mates.
Males provide no resources except sperm, they do not help in raising the young.
4. Lek Polygyny
Examples: Grouse (korhoen)Ruffs (kemphaan) manakinsCock-of-the-rock (rotshaan)
Sage Grouse (waaierhoen) displaying on a lek
Males display for females. Females choose males on basis of appearance and displays (sexual selection).
Highly skewed mating success is normal inlekking systems. A few males obtain most of the matings.
By mating with best possible male, females obtain the best available genes for their offspring.
In well-studied Black Grouse (korhoen) and Sage Grouse (waaierhoen) lekking systems <10% of males obtain 70-80% of the copulations.
Three most favored hypotheses forevolution of lekking are:
1.“Hot-spots” hypothesis
2. “Hot-shots” hypothesis
3. Female preference hypothesis.
1. Hot-spots Hypothesis: males gather at sites where they are likely to encounter females.
Lekking bees, wasps and other insects often use same locations for leks.
Territories of lekking flycatchers, manakins and hummingbirds also often overlap.
Gather along streams or ridgelines thatact as highways for female movement.
1. Hotspots hypothesis
2. Hot-shots Hypothesis: subordinate males cluster around most attractive males ― “hot-shots” ― in order to be seen by or tointercept females attracted to these males.
In Great Snipe (poelsnip) removing central dominant bird caused neighbors to leave territories.
Removal of subordinates resulted in their territories being refilled.
2. Hotshot hypothesis: great snipe
3. Female Preference Hypothesis: females prefer to choose from groups of males because comparisons are easier to make.
Female ruffs (kemphaan) prefer groups of at least fivemales and visit such groups more often.
3. Female preference hypothesis: ruff
