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Semelparity and iteroparity

March 03, 2023

Look up semelparous in Wiktionary, the free dictionary.
Look up iteroparous in Wiktionary, the free dictionary.

Semelparity and iteroparity are two contrasting reproductive strategies available to living organisms. A species is considered semelparous if it is characterized by a single reproductive episode before death, and iteroparous if it is characterized by multiple reproductive cycles over the course of its lifetime. Iteroparity can be further divided into continuous iteroparity (primates including humans and chimpanzees) and seasonal iteroparity (birds, dogs, etc.) Some botanists use the parallel terms monocarpy and polycarpy. (See also plietesials.)

In truly semelparous species, death after reproduction is part of an overall strategy that includes putting all available resources into maximizing reproduction, at the expense of future life (see § Trade-offs). In any iteroparous population there will be some individuals who die between their first and second reproductive episodes, but unless this is part of a syndrome of programmed death after reproduction, this would not be called semelparity.

This distinction is also related to the difference between annual and perennial plants. An annual is a plant that completes its life cycle in a single season, and is usually semelparous. Perennials live for more than one season and are usually (but not always) iteroparous.[1]

Semelparity and iteroparity are not, strictly speaking, alternative strategies, but extremes along a continuum of possible modes of reproduction. Many organisms considered to be semelparous can, under certain conditions, separate their single bout of reproduction into two or more episodes.[2][3]

Overview

Semelparity

 
Pacific salmon are examples of semelparous organisms

The word semelparity was coined by evolutionary biologist Lamont Cole,[4] and comes from the Latin semel 'once, a single time' and pario 'to beget'. This differs from iteroparity in that iteroparous species are able to have multiple reproductive cycles and therefore can mate more than once in their lifetime. Semelparity is also known as "big bang" reproduction, since the single reproductive event of semelparous organisms is usually large as well as fatal.[5] A classic example of a semelparous organism is Pacific salmon (Oncorhynchus spp.), which lives for many years in the ocean before swimming to the freshwater stream of its birth, spawning, and dying. Other semelparous animals include many insects, including some species of butterflies, cicadas, and mayflies, many arachnids, and some molluscs such as some species of squid and octopus.

Semelparity also occurs in smelt and capelin, but is very rare in vertebrates other than bony fish. In amphibians, it is known only among some Hyla frogs including the gladiator frog;[6] in reptiles only a few lizards such as Labord's chameleon of southwestern Madagascar,[7] Sceloporus bicanthalis of the high mountains of Mexico,[8] and some species of Ichnotropis from dry savanna areas of Africa.[9] Among mammals, it exists only in a few didelphid and dasyurid marsupials.[10] Annual plants, including all grain crops and most domestic vegetables, are semelparous. Long-lived semelparous plants include century plant (agave), Lobelia telekii, and some species of bamboo.[11]

This form of lifestyle is consistent with r-selected strategies as many offspring are produced and there is low parental input, as one or both parents die after mating. All of the male's energy is diverting into mating and the immune system is repressed. High levels of corticosteroids are sustained over long periods of time. This triggers immune and inflammatory system failure and gastrointestinal hemorrhage, which eventually leads to death.[12]

Iteroparity

 
An iteroparous organism is one that can undergo many reproductive events throughout its lifetime. The pig is an example of an iteroparous organism

The term iteroparity comes from the Latin itero, to repeat, and pario, to beget. An example of an iteroparous organism is a human—humans are biologically capable of having offspring many times over the course of their lives.

Iteroparous vertebrates include all birds, most reptiles, virtually all mammals, and most fish. Among invertebrates, most mollusca and many insects (for example, mosquitoes and cockroaches) are iteroparous. Most perennial plants are iteroparous.

Models

Trade-offs

It is a biological precept that within its lifetime an organism has a limited amount of energy/resources available to it, and must always partition it among various functions such as collecting food and finding a mate. Of relevance here is the trade-off between fecundity, growth, and survivorship in its life history strategy. These trade-offs come into play in the evolution of iteroparity and semelparity. It has been repeatedly demonstrated that semelparous species produce more offspring in their single fatal reproductive episode than do closely related iteroparous species in any one of theirs. However, the opportunity to reproduce more than once in a lifetime, and possibly with greater care for the development of offspring produced, can offset this strictly numerical benefit.

Models based on non-linear trade-offs

One class of models that tries to explain the differential evolution of semelparity and iteroparity examines the shape of the trade-off between offspring produced and offspring forgone. In economic terms, offspring produced is equivalent to a benefit function, while offspring forgone is comparable to a cost function. The reproductive effort of an organism—the proportion of energy that it puts into reproducing, as opposed to growth or survivorship—occurs at the point where the distance between offspring produced and offspring forgone is the greatest.[13]

 
Iteroparous reproductive effort

In some situations, the marginal cost of offspring produced decreases over time (each additional offspring is less "expensive" than the average of all previous offspring) and the marginal cost of offspring forgone increases. In these cases, the organism only devotes a portion of its resources to reproduction and uses the rest for growth and survivorship so that it can reproduce again in the future.[14]

 
Semelparous reproductive effort

In other situations, the marginal cost of offspring produced increases while the marginal cost of offspring forgone decreases. When this is the case, it is favorable for the organism to reproduce a single time. The individual devotes all of its resources to that one episode of reproduction, then dies as it has not reserved enough resources to meet its own ongoing survival needs.

Empirical, quantitative support for this mathematical mode is limited.

Bet-hedging models

A second set of models examines the possibility that iteroparity is a hedge against unpredictable juvenile survivorship (avoiding putting all one's eggs in one basket). Again, mathematical models have not found empirical support from real-world systems. In fact, many semelparous species live in habitats characterized by high (not low) environmental unpredictability, such as deserts and early successional habitats.

Cole's paradox and demographic models

The models that have the strongest support from living systems are demographic. In Lamont Cole's classic 1954 paper, he came to the conclusion that:

For an annual species, the absolute gain in intrinsic population growth which could be achieved by changing to the perennial reproductive habit would be exactly equivalent to adding one individual to the average litter size.[15]

For example, imagine two species—an iteroparous species that has annual litters averaging three offspring each, and a semelparous species that has one litter of four, and then dies. These two species have the same rate of population growth, which suggests that even a tiny fecundity advantage of one additional offspring would favor the evolution of semelparity. This is known as Cole's paradox.

In his analysis, Cole assumed that there was no mortality of individuals of the iteroparous species, even seedlings. Twenty years later, Charnov and Schaffer[16] showed that reasonable differences in adult and juvenile mortality yield much more reasonable costs of semelparity, essentially solving Cole's paradox. An even more general demographic model was produced by Young.[17]

These demographic models have been more successful than the other models when tested with real-world systems. It has been shown that semelparous species have higher expected adult mortality, making it more economical to put all reproductive effort into the first (and therefore final) reproductive episode.[18][19]

Semelparity

Semelparity in mammals

 
Antechinus agilis

In Dasyuridae

Small Dasyuridae
 
Phascogale calura

Semelparous species of Dasyuridae are typically small and carnivorous, with the exception of the northern quoll (Dasyurus hallucatus), which is large. Species with this reproductive strategy include members of the genus AntechinusPhascogale tapoatafa and Phascogale culura. The males of all three groups exhibit similar characteristics that classify them as semelparous. First, all of the males of each species disappear immediately after the mating season. Also, males that are captured and isolated from others live for 2 to 3 years.[20] If these captured males are allowed to mate, they die immediately after the mating season, like those in the wild. Their behaviour also changes drastically before and after the mating season. Before mating, males are extremely aggressive and will fight with other males if placed close together. Males that are captured before they are allowed to mate remain aggressive through the winter months. After the mating season, if allowed to mate, males become extremely lethargic and never regain their aggressiveness even if they survive to the next mating season.[20] Other changes that occur post-mating include fur degradation and testicular degeneration. During adolescence, male fur is thick and becomes dull and thin after mating, but regains its original condition if the individual manages to survive past the mating season. The fur on the scrotum completely falls off and does not grow back, even if the male survives months after the first mating season. As the marsupial ages, its testicles grow until they reach a peak size and weight at the beginning of the mating season. After the individual mates, the weight and size of the testes and scrotum decrease. They remain small and do not produce spermatozoa later in life, if maintained in a laboratory.[20] The 1966 Woolley study on Antechinus spp. noticed that males were only able to be maintained past mating in the laboratory and no senile males were found in the wild, suggesting that all males die shortly after mating.[20]

Corticosteroid concentration and increased male mortality
 
Antechinus stuartii

Studies on Antechinus stuartii reveal that male mortality is highly correlated to stress and andrenocortical activity. The study measured the corticosteroid concentration in males in the wild, males injected with cortisol, males injected with saline, and females in the wild. While both males and females exhibit high levels of corticosteroid concentration in the wild, this proves fatal only to males due to females having a higher maximum high affinity corticosteroid binding capacity (MCBC).[21] Thus, free corticosteroid in the plasma of male A. stuartii rises sharply, while it remains constant in females. High levels of free corticosteroid, resulting from mating in wild males and injected cortisol in laboratory males, resulted in stomach ulcersgastrointestinal hemorrhaging, and liver abscesses, all of which increased mortality. These side effects were not found in the males that were injected with saline,[21] strengthening the hypothesis that high free corticosteroids results in higher mortality in male Dasyurids. A similar study on Phascogale calura showed that similar endocrine system changes happen in P. calura as A. stuartii.[22] This supports stress-induced mortality as a characteristic of small Dasyurid semelparity.

Large Dasyuridae
 
Dasyurus hallucatus

Dasyurus hallucatus, the northern quoll, is a large dasyurid and exhibits increased male mortality after the mating season. Unlike smaller dasyurids, male die-off in D. hallucatus is not due to endocrine system changes and there was no spermatogenic failure after the mating season ended.[12] If male D. hallucatus survive past their first mating season, they may be able to engage in a second mating season. While the individuals in a 2001 study mostly died from vehicles or predation, researchers found evidence of physiological degradation in males, similar to the physiological degradation in small dasyurids. This includes fur loss, parasite infestations, and weight loss. As the mating period went on, males became increasingly anemic, but the anemia was not due to ulceration or gastrointestinal bleeding.[12] Lack of elevated cortisol levels during mating periods in D. hallucatus means that there is no current universal explanation for the mechanism behind increased male mortality in Dasyuridae. Post-reproductive senescence has also been proposed as an explanation.[23]

In opossums

Grey slender mouse opossum (Marmosops incanus)
 
Marmosops incanus

The grey slender mouse opossum exhibits a semelparous reproductive strategy in both males and females. Males disappear from their endemic area after the reproductive season (February–May). Males found months later (June–August) are of lighter body weight and the molar teeth are less worn down, suggesting these males belong to a different generation. There is a drop off in the female population, but during the months of July and August, evidence of a gap between generations like the male gap. There is also lower body weight and less molar wear observed in females found after August. This is further supported by the evidence that females that reproduce are not observed the following year.[24] This species has been compared to a related species, Marmosa robinsoni, in order to answer what would happen if a female that has reproduced were to survive to the next mating season. M. robinsoni has a monoestrus reproductive cycle, like M. incanus, and females are no longer fertile after 17 months so it is unlikely that females that survive past the drop off in female populations would be able to reproduce a second time.[24]

 
Gracilinanus microtarsus
Other mouse opossums

Gracilinanus microtarsus, or the Brazilian gracile opossum, is considered to be partially semelparous because male mortality increases significantly after the mating season, but some males survive to mate again in the next reproductive cycle. The males also exhibit similar physiological degradation demonstrated in Antechinus and other semelparous marsupials such as fur loss and increase of infection from parasites.[25]

Semelparity in fish

Pacific salmon

Highly elevated cortisol levels mediate the post-spawning death of semelparous Oncorhynchus Pacific salmon by causing tissue degeneration, suppressing the immune system, and impairing various homeostatic mechanisms.[26] After swimming for such a long distance, salmon expend all of their energy on reproduction. One of the key factors in salmon rapid senescence is that these fish do not feed during reproduction so body weight is extremely reduced.[27] In addition to physiological degradation, pacific salmon become more lethargic as mating goes on, which makes some individuals more susceptible to predation because they have less energy to avoid predators.[28] This also increases mortality rates of adults post-mating.

Semelparity in insects

 
Gypsy Moth

Traditionally, semelparity was usually defined within the time frame of a year. Critics of this criterion note that this scale is inappropriate in discussing patterns of insect reproduction because many insects breed more than once within one annual period, but generation times of less than one year. Under the traditional definition, insects are considered semelparous as a consequence of time scale rather than the distribution of reproductive effort over their adult life span.[29] In order to resolve this inconsistency, Fritz et al. define semelparous insects as "Insects that lay a single clutch of eggs in their lifetime and deposit them at one place are clearly semelparous or big bang reproducers. Their entire reproductive effort is committed at one time and they die shortly after oviposition".[29] Semelparous insects are found in Lepidoptera, Ephemeroptera, Dermaptera, Plecoptera, Strepsiptera, Trichoptera, and Hemiptera.

Examples in Lepidoptera

Females of certain families of Lepidoptera, like the Gypsy Moth of Psychidae, have reduced mobility or apterous so the insects' dispersal is in the larval stage, as opposed to in the adult stage. In iteroparous insects, major dispersal occurs in the adult stage. All semelparous Lepidopterans share similar characteristics: Larva only feed in restricted periods of the year because of the nutritional state of their host plants (as a result, they are univoltine), initial food supply is predictably abundant, and larval host plants are abundant and adjacent.[29] Death most commonly occurs by starvation. In the case of the gypsy moth, adults do not possess an active digestive system and cannot feed, but can drink moisture. Mating occurs fairly rapidly after adults emerge from their pupal form and, without a way to digest food, the adult moths die after about a week.[30]

Evolutionary advantages to semelparity

Current evolutionary advantages hypothesis

 
Antechinus agilis showing offspring inside pouch

The evolution for semelparity in both sexes has occurred many times in plants, invertebrates, and fish. It is rare in mammals because mammals have obligate maternal care due to internal fertilization and incubation of offspring and nursing young after birth, which requires high maternal survival rate after fertilization and offspring weaning. Also, female mammals have relatively low reproductive rates compared to invertebrates or fish because they invest a lot of energy in maternal care. However, male reproductive rate is much less constrained in mammals because only females bear young. A male that dies after one mating season can still produce a large number of offspring if he invests all of his energy in mating with many females.[31]

Evolution in mammals

Scientists have hypothesized that natural selection has allowed semelparity to evolve in Dasyuridae and Didelphidae because of certain ecological constraints. Female mammals ancestral to these groups may have shortened their mating period to coincide with peak prey abundance. Because this window is so small, the females of these species exhibit a reproduction pattern where the estrous of all females occurs simultaneously. Selection would then favor aggressive males due to increased competition between males for access to females. Since the mating period is so short, it is more beneficial for males to expend all their energy on mating, even more so if they are unlikely to survive to the next mating season.[32]

Evolution in fish

 
Dead salmon after spawning

Reproduction is costly for anadromous salmonids because their life history requires transition from saltwater to freshwater streams and long migrations, which can be physiologically taxing. The transition between cold oceanic water to warm freshwater and steep elevation changes in Northern Pacific rivers could explain the evolution of semelparity because it would be extremely difficult to return to the ocean. A noticeable difference between semelparous fish and iteroparous salmonids is that egg size varies between the two types of reproductive strategies. Studies show that egg size is also affected by migration and body size. Egg number, however, shows little variation between semelparous and iteroparous populations or between resident and anadromous populations for females of the same body size.[33] The current hypothesis behind this reason is that iteroparous species reduce the size of their eggs in order to improve the mother's chances of survival, since she invests less energy in gamete formation. Semelparous species do not expect to live past one mating season, so females invest a lot more energy in gamete formation resulting in large eggs. Anadromous salmonids may also have evolved semelparity to boost the nutrition density of the spawning grounds. The most productive Pacific salmon spawning grounds contain the most carcasses of spawned adults. The dead bodies of the adult salmon decompose and provide nitrogen and phosphorus for algae to grow in the nutrient-poor water. Zooplankton then feed on the algae, and newly hatched salmon feed on the zooplankton.[34]

Evolution in insects

 
Earwig guarding eggs

An interesting trait has evolved in semelparous insects, especially in those that have evolved from parasitic ancestors, like in all subsocial and eusocial aculeate Hymenoptera. This is because larvae are morphologically specialized for development within a host's innards and thus are entirely helpless outside of that environment. Females would need to invest a lot of energy in protecting their eggs and hatched offspring. They do this through such behaviours as egg guarding. Mothers that actively defend offspring, for example, risk injury or death by doing so.[35] This is not beneficial in an iteroparous species because the female risks dying and not reaching her full reproductive potential by not being able to reproduce in all reproductive periods in her lifetime. Since semelparous insects only live for one reproductive cycle, they can afford to expend energy on maternal care because those offspring are her only offspring. An iteroparous insect does not need to expend energy on the eggs of one mating period because it is likely that she will mate again. There is ongoing research in maternal care in semelparous insects from lineages not descended from parasites to further understand this relationship between semelparity and maternal care.

See also

  • Annual plant – Plant which completes its life cycle within one growing season and then dies
  • Behavioral ecology – Study of the evolutionary basis for animal behavior due to ecological pressures
  • Ecology – Study of organisms and their environment
  • Life history theory – Analytical framework to study life history strategies used by organisms
  • Perennial plant – Plant that lives for more than two years
  • r/K selection theory – Ecological theory concerning the selection of life history traits

References

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  12. ^ a b c Oakwood, Meri; Bradley, Adrian J.; Cockburn, Andrew (2001-02-22). "Semelparity in a large marsupial". Proceedings of the Royal Society of London B: Biological Sciences. 268 (1465): 407–411. doi:10.1098/rspb.2000.1369. ISSN 0962-8452. PMC 1088621. PMID 11270438.
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  28. ^ Gende, Scott M.; Quinn, Thomas P.; Hilborn, Ray; Hendry, Andrew P.; Dickerson, Bobette (2004-03-01). "Brown bears selectively kill salmon with higher energy content but only in habitats that facilitate choice". Oikos. 104 (3): 518–528. doi:10.1111/j.0030-1299.2004.12762.x. ISSN 1600-0706. S2CID 5961141.
  29. ^ a b c Fritz, Robert S.; Stamp, Nancy E.; Halverson, Timothy G. (1982). "Iteroparity and Semelparity in Insects". The American Naturalist. 120 (2): 264–268. doi:10.1086/283987. JSTOR 2461222. S2CID 85228942.
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Further reading

  • (peer-reviewed) Nature Education Knowledge entry on Semelparity
  • De Wreede, R.E, and T. Klinger. Reproductive strategies in algae. pp. 267–276 in: Plant Reproductive Ecology: Patterns and Strategies. J.L Lovett-Doust & L.L Lovett-Doust (eds). Oxford University Press.
  • Fritz, R.S.; Stamp, N.E.; Halverson, T.G. (1982). "Iteroparity and semelparity in insects". The American Naturalist. 120 (2): 264–68. doi:10.1086/283987. S2CID 85228942.
  • Ranta, E.; Tesar, D.; Kaitala, V. (2002). "Environmental variability and semelparity vs. iteroparity as life histories". Journal of Theoretical Biology. 217 (3): 391–398. Bibcode:2002JThBi.217..391R. doi:10.1006/jtbi.2002.3029. PMID 12270282.

March 03, 2023
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Look up semelparous in Wiktionary the free dictionary Look up iteroparous in Wiktionary the free dictionary Semelparity and iteroparity are two contrasting reproductive strategies available to living organisms A species is considered semelparous if it is characterized by a single reproductive episode before death and iteroparous if it is characterized by multiple reproductive cycles over the course of its lifetime Iteroparity can be further divided into continuous iteroparity primates including humans and chimpanzees and seasonal iteroparity birds dogs etc Some botanists use the parallel terms monocarpy and polycarpy See also plietesials In truly semelparous species death after reproduction is part of an overall strategy that includes putting all available resources into maximizing reproduction at the expense of future life see Trade offs In any iteroparous population there will be some individuals who die between their first and second reproductive episodes but unless this is part of a syndrome of programmed death after reproduction this would not be called semelparity This distinction is also related to the difference between annual and perennial plants An annual is a plant that completes its life cycle in a single season and is usually semelparous Perennials live for more than one season and are usually but not always iteroparous 1 Semelparity and iteroparity are not strictly speaking alternative strategies but extremes along a continuum of possible modes of reproduction Many organisms considered to be semelparous can under certain conditions separate their single bout of reproduction into two or more episodes 2 3 Contents 1 Overview 1 1 Semelparity 1 2 Iteroparity 2 Models 2 1 Trade offs 2 2 Models based on non linear trade offs 2 3 Bet hedging models 2 4 Cole s paradox and demographic models 3 Semelparity 3 1 Semelparity in mammals 3 1 1 In Dasyuridae 3 1 1 1 Small Dasyuridae 3 1 1 2 Corticosteroid concentration and increased male mortality 3 1 1 3 Large Dasyuridae 3 1 2 In opossums 3 1 2 1 Grey slender mouse opossum Marmosops incanus 3 1 2 2 Other mouse opossums 3 2 Semelparity in fish 3 2 1 Pacific salmon 3 3 Semelparity in insects 3 3 1 Examples in Lepidoptera 4 Evolutionary advantages to semelparity 4 1 Current evolutionary advantages hypothesis 4 1 1 Evolution in mammals 4 1 2 Evolution in fish 4 1 3 Evolution in insects 5 See also 6 References 7 Further readingOverview EditSemelparity Edit Pacific salmon are examples of semelparous organismsThe word semelparity was coined by evolutionary biologist Lamont Cole 4 and comes from the Latin semel once a single time and pario to beget This differs from iteroparity in that iteroparous species are able to have multiple reproductive cycles and therefore can mate more than once in their lifetime Semelparity is also known as big bang reproduction since the single reproductive event of semelparous organisms is usually large as well as fatal 5 A classic example of a semelparous organism is Pacific salmon Oncorhynchus spp which lives for many years in the ocean before swimming to the freshwater stream of its birth spawning and dying Other semelparous animals include many insects including some species of butterflies cicadas and mayflies many arachnids and some molluscs such as some species of squid and octopus Semelparity also occurs in smelt and capelin but is very rare in vertebrates other than bony fish In amphibians it is known only among some Hyla frogs including the gladiator frog 6 in reptiles only a few lizards such as Labord s chameleon of southwestern Madagascar 7 Sceloporus bicanthalis of the high mountains of Mexico 8 and some species of Ichnotropis from dry savanna areas of Africa 9 Among mammals it exists only in a few didelphid and dasyurid marsupials 10 Annual plants including all grain crops and most domestic vegetables are semelparous Long lived semelparous plants include century plant agave Lobelia telekii and some species of bamboo 11 This form of lifestyle is consistent with r selected strategies as many offspring are produced and there is low parental input as one or both parents die after mating All of the male s energy is diverting into mating and the immune system is repressed High levels of corticosteroids are sustained over long periods of time This triggers immune and inflammatory system failure and gastrointestinal hemorrhage which eventually leads to death 12 Iteroparity Edit An iteroparous organism is one that can undergo many reproductive events throughout its lifetime The pig is an example of an iteroparous organism The term iteroparity comes from the Latin itero to repeat and pario to beget An example of an iteroparous organism is a human humans are biologically capable of having offspring many times over the course of their lives Iteroparous vertebrates include all birds most reptiles virtually all mammals and most fish Among invertebrates most mollusca and many insects for example mosquitoes and cockroaches are iteroparous Most perennial plants are iteroparous Models EditTrade offs Edit It is a biological precept that within its lifetime an organism has a limited amount of energy resources available to it and must always partition it among various functions such as collecting food and finding a mate Of relevance here is the trade off between fecundity growth and survivorship in its life history strategy These trade offs come into play in the evolution of iteroparity and semelparity It has been repeatedly demonstrated that semelparous species produce more offspring in their single fatal reproductive episode than do closely related iteroparous species in any one of theirs However the opportunity to reproduce more than once in a lifetime and possibly with greater care for the development of offspring produced can offset this strictly numerical benefit Models based on non linear trade offs Edit One class of models that tries to explain the differential evolution of semelparity and iteroparity examines the shape of the trade off between offspring produced and offspring forgone In economic terms offspring produced is equivalent to a benefit function while offspring forgone is comparable to a cost function The reproductive effort of an organism the proportion of energy that it puts into reproducing as opposed to growth or survivorship occurs at the point where the distance between offspring produced and offspring forgone is the greatest 13 Iteroparous reproductive effort In some situations the marginal cost of offspring produced decreases over time each additional offspring is less expensive than the average of all previous offspring and the marginal cost of offspring forgone increases In these cases the organism only devotes a portion of its resources to reproduction and uses the rest for growth and survivorship so that it can reproduce again in the future 14 Semelparous reproductive effort In other situations the marginal cost of offspring produced increases while the marginal cost of offspring forgone decreases When this is the case it is favorable for the organism to reproduce a single time The individual devotes all of its resources to that one episode of reproduction then dies as it has not reserved enough resources to meet its own ongoing survival needs Empirical quantitative support for this mathematical mode is limited Bet hedging models Edit A second set of models examines the possibility that iteroparity is a hedge against unpredictable juvenile survivorship avoiding putting all one s eggs in one basket Again mathematical models have not found empirical support from real world systems In fact many semelparous species live in habitats characterized by high not low environmental unpredictability such as deserts and early successional habitats Cole s paradox and demographic models EditThe models that have the strongest support from living systems are demographic In Lamont Cole s classic 1954 paper he came to the conclusion that For an annual species the absolute gain in intrinsic population growth which could be achieved by changing to the perennial reproductive habit would be exactly equivalent to adding one individual to the average litter size 15 For example imagine two species an iteroparous species that has annual litters averaging three offspring each and a semelparous species that has one litter of four and then dies These two species have the same rate of population growth which suggests that even a tiny fecundity advantage of one additional offspring would favor the evolution of semelparity This is known as Cole s paradox In his analysis Cole assumed that there was no mortality of individuals of the iteroparous species even seedlings Twenty years later Charnov and Schaffer 16 showed that reasonable differences in adult and juvenile mortality yield much more reasonable costs of semelparity essentially solving Cole s paradox An even more general demographic model was produced by Young 17 These demographic models have been more successful than the other models when tested with real world systems It has been shown that semelparous species have higher expected adult mortality making it more economical to put all reproductive effort into the first and therefore final reproductive episode 18 19 Semelparity EditSemelparity in mammals Edit Antechinus agilis In Dasyuridae Edit Small Dasyuridae Edit Phascogale calura Semelparous species of Dasyuridae are typically small and carnivorous with the exception of the northern quoll Dasyurus hallucatus which is large Species with this reproductive strategy include members of the genus Antechinus Phascogale tapoatafa and Phascogale culura The males of all three groups exhibit similar characteristics that classify them as semelparous First all of the males of each species disappear immediately after the mating season Also males that are captured and isolated from others live for 2 to 3 years 20 If these captured males are allowed to mate they die immediately after the mating season like those in the wild Their behaviour also changes drastically before and after the mating season Before mating males are extremely aggressive and will fight with other males if placed close together Males that are captured before they are allowed to mate remain aggressive through the winter months After the mating season if allowed to mate males become extremely lethargic and never regain their aggressiveness even if they survive to the next mating season 20 Other changes that occur post mating include fur degradation and testicular degeneration During adolescence male fur is thick and becomes dull and thin after mating but regains its original condition if the individual manages to survive past the mating season The fur on the scrotum completely falls off and does not grow back even if the male survives months after the first mating season As the marsupial ages its testicles grow until they reach a peak size and weight at the beginning of the mating season After the individual mates the weight and size of the testes and scrotum decrease They remain small and do not produce spermatozoa later in life if maintained in a laboratory 20 The 1966 Woolley study on Antechinus spp noticed that males were only able to be maintained past mating in the laboratory and no senile males were found in the wild suggesting that all males die shortly after mating 20 Corticosteroid concentration and increased male mortality Edit Antechinus stuartii Studies on Antechinus stuartii reveal that male mortality is highly correlated to stress and andrenocortical activity The study measured the corticosteroid concentration in males in the wild males injected with cortisol males injected with saline and females in the wild While both males and females exhibit high levels of corticosteroid concentration in the wild this proves fatal only to males due to females having a higher maximum high affinity corticosteroid binding capacity MCBC 21 Thus free corticosteroid in the plasma of male A stuartii rises sharply while it remains constant in females High levels of free corticosteroid resulting from mating in wild males and injected cortisol in laboratory males resulted in stomach ulcers gastrointestinal hemorrhaging and liver abscesses all of which increased mortality These side effects were not found in the males that were injected with saline 21 strengthening the hypothesis that high free corticosteroids results in higher mortality in male Dasyurids A similar study on Phascogale calura showed that similar endocrine system changes happen in P calura as A stuartii 22 This supports stress induced mortality as a characteristic of small Dasyurid semelparity Large Dasyuridae Edit Dasyurus hallucatus Dasyurus hallucatus the northern quoll is a large dasyurid and exhibits increased male mortality after the mating season Unlike smaller dasyurids male die off in D hallucatus is not due to endocrine system changes and there was no spermatogenic failure after the mating season ended 12 If male D hallucatus survive past their first mating season they may be able to engage in a second mating season While the individuals in a 2001 study mostly died from vehicles or predation researchers found evidence of physiological degradation in males similar to the physiological degradation in small dasyurids This includes fur loss parasite infestations and weight loss As the mating period went on males became increasingly anemic but the anemia was not due to ulceration or gastrointestinal bleeding 12 Lack of elevated cortisol levels during mating periods in D hallucatus means that there is no current universal explanation for the mechanism behind increased male mortality in Dasyuridae Post reproductive senescence has also been proposed as an explanation 23 In opossums Edit Grey slender mouse opossum Marmosops incanus Edit Marmosops incanus The grey slender mouse opossum exhibits a semelparous reproductive strategy in both males and females Males disappear from their endemic area after the reproductive season February May Males found months later June August are of lighter body weight and the molar teeth are less worn down suggesting these males belong to a different generation There is a drop off in the female population but during the months of July and August evidence of a gap between generations like the male gap There is also lower body weight and less molar wear observed in females found after August This is further supported by the evidence that females that reproduce are not observed the following year 24 This species has been compared to a related species Marmosa robinsoni in order to answer what would happen if a female that has reproduced were to survive to the next mating season M robinsoni has a monoestrus reproductive cycle like M incanus and females are no longer fertile after 17 months so it is unlikely that females that survive past the drop off in female populations would be able to reproduce a second time 24 Gracilinanus microtarsus Other mouse opossums Edit Gracilinanus microtarsus or the Brazilian gracile opossum is considered to be partially semelparous because male mortality increases significantly after the mating season but some males survive to mate again in the next reproductive cycle The males also exhibit similar physiological degradation demonstrated in Antechinus and other semelparous marsupials such as fur loss and increase of infection from parasites 25 Semelparity in fish Edit Pacific salmon Edit Highly elevated cortisol levels mediate the post spawning death of semelparous Oncorhynchus Pacific salmon by causing tissue degeneration suppressing the immune system and impairing various homeostatic mechanisms 26 After swimming for such a long distance salmon expend all of their energy on reproduction One of the key factors in salmon rapid senescence is that these fish do not feed during reproduction so body weight is extremely reduced 27 In addition to physiological degradation pacific salmon become more lethargic as mating goes on which makes some individuals more susceptible to predation because they have less energy to avoid predators 28 This also increases mortality rates of adults post mating Semelparity in insects Edit Gypsy Moth Traditionally semelparity was usually defined within the time frame of a year Critics of this criterion note that this scale is inappropriate in discussing patterns of insect reproduction because many insects breed more than once within one annual period but generation times of less than one year Under the traditional definition insects are considered semelparous as a consequence of time scale rather than the distribution of reproductive effort over their adult life span 29 In order to resolve this inconsistency Fritz et al define semelparous insects as Insects that lay a single clutch of eggs in their lifetime and deposit them at one place are clearly semelparous or big bang reproducers Their entire reproductive effort is committed at one time and they die shortly after oviposition 29 Semelparous insects are found in Lepidoptera Ephemeroptera Dermaptera Plecoptera Strepsiptera Trichoptera and Hemiptera Examples in Lepidoptera Edit Females of certain families of Lepidoptera like the Gypsy Moth of Psychidae have reduced mobility or apterous so the insects dispersal is in the larval stage as opposed to in the adult stage In iteroparous insects major dispersal occurs in the adult stage All semelparous Lepidopterans share similar characteristics Larva only feed in restricted periods of the year because of the nutritional state of their host plants as a result they are univoltine initial food supply is predictably abundant and larval host plants are abundant and adjacent 29 Death most commonly occurs by starvation In the case of the gypsy moth adults do not possess an active digestive system and cannot feed but can drink moisture Mating occurs fairly rapidly after adults emerge from their pupal form and without a way to digest food the adult moths die after about a week 30 Evolutionary advantages to semelparity EditCurrent evolutionary advantages hypothesis Edit Antechinus agilis showing offspring inside pouch The evolution for semelparity in both sexes has occurred many times in plants invertebrates and fish It is rare in mammals because mammals have obligate maternal care due to internal fertilization and incubation of offspring and nursing young after birth which requires high maternal survival rate after fertilization and offspring weaning Also female mammals have relatively low reproductive rates compared to invertebrates or fish because they invest a lot of energy in maternal care However male reproductive rate is much less constrained in mammals because only females bear young A male that dies after one mating season can still produce a large number of offspring if he invests all of his energy in mating with many females 31 Evolution in mammals Edit Scientists have hypothesized that natural selection has allowed semelparity to evolve in Dasyuridae and Didelphidae because of certain ecological constraints Female mammals ancestral to these groups may have shortened their mating period to coincide with peak prey abundance Because this window is so small the females of these species exhibit a reproduction pattern where the estrous of all females occurs simultaneously Selection would then favor aggressive males due to increased competition between males for access to females Since the mating period is so short it is more beneficial for males to expend all their energy on mating even more so if they are unlikely to survive to the next mating season 32 Evolution in fish Edit Dead salmon after spawning Reproduction is costly for anadromous salmonids because their life history requires transition from saltwater to freshwater streams and long migrations which can be physiologically taxing The transition between cold oceanic water to warm freshwater and steep elevation changes in Northern Pacific rivers could explain the evolution of semelparity because it would be extremely difficult to return to the ocean A noticeable difference between semelparous fish and iteroparous salmonids is that egg size varies between the two types of reproductive strategies Studies show that egg size is also affected by migration and body size Egg number however shows little variation between semelparous and iteroparous populations or between resident and anadromous populations for females of the same body size 33 The current hypothesis behind this reason is that iteroparous species reduce the size of their eggs in order to improve the mother s chances of survival since she invests less energy in gamete formation Semelparous species do not expect to live past one mating season so females invest a lot more energy in gamete formation resulting in large eggs Anadromous salmonids may also have evolved semelparity to boost the nutrition density of the spawning grounds The most productive Pacific salmon spawning grounds contain the most carcasses of spawned adults The dead bodies of the adult salmon decompose and provide nitrogen and phosphorus for algae to grow in the nutrient poor water Zooplankton then feed on the algae and newly hatched salmon feed on the zooplankton 34 Evolution in insects Edit Earwig guarding eggs An interesting trait has evolved in semelparous insects especially in those that have evolved from parasitic ancestors like in all subsocial and eusocial aculeate Hymenoptera This is because larvae are morphologically specialized for development within a host s innards and thus are entirely helpless outside of that environment Females would need to invest a lot of energy in protecting their eggs and hatched offspring They do this through such behaviours as egg guarding Mothers that actively defend offspring for example risk injury or death by doing so 35 This is not beneficial in an iteroparous species because the female risks dying and not reaching her full reproductive potential by not being able to reproduce in all reproductive periods in her lifetime Since semelparous insects only live for one reproductive cycle they can afford to expend energy on maternal care because those offspring are her only offspring An iteroparous insect does not need to expend energy on the eggs of one mating period because it is likely that she will mate again There is ongoing research in maternal care in semelparous insects from lineages not descended from parasites to further understand this relationship between semelparity and maternal care See also EditAnnual plant Plant which completes its life cycle within one growing season and then dies Behavioral ecology Study of the evolutionary basis for animal behavior due to ecological pressures Ecology Study of organisms and their environment Life history theory Analytical framework to study life history strategies used by organisms Perennial plant Plant that lives for more than two years r K selection theory Ecological theory concerning the selection of life history traitsReferences Edit Gotelli Nicholas J 2008 A Primer of Ecology Sunderland Mass Sinauer Associates Inc ISBN 978 0 87893 318 1 Futami Kyoko Akimoto Shin ichi 2005 12 01 Facultative Second Oviposition as an Adaptation to Egg Loss in a Semelparous Crab Spider Ethology 111 12 1126 1138 doi 10 1111 j 1439 0310 2005 01126 x ISSN 1439 0310 Hughes P William Simons Andrew M 2014 08 01 Changing reproductive effort within a semelparous reproductive episode American Journal of Botany 101 8 1323 1331 doi 10 3732 ajb 1400283 ISSN 0002 9122 PMID 25156981 Cole Lamont C June 1954 The Population Consequences of Life History Phenomena The Quarterly Review of Biology 29 2 103 137 doi 10 1086 400074 JSTOR 2817654 PMID 13177850 S2CID 26986186 Robert E Ricklefs and Gary Leon Miller 1999 Ecology Macmillan ISBN 0 7167 2829 X Andersson Matle Sexual Selection p 242 ISBN 0691000573 Karsten KB Andriamandimbiarisoa LN Fox SF Raxworthy CJ 2008 A unique life history among tetrapods an annual chameleon living mostly as an egg Proc Natl Acad Sci U S A 105 26 8980 4 Bibcode 2008PNAS 105 8980K doi 10 1073 pnas 0802468105 PMC 2449350 PMID 18591659 Demography of a Semelparous High Elevation Population of Sceloporus bicanthalis Lacertilia Phrynosomatidae from the Nevado de Toluca Volcano Mexico in The Southwestern Naturalist 56 1 71 77 2011 Broadley D G 1967 The life cycle of two sympatric species of Ichnotropis Sauria Lacertidae Zoologica Africana 3 1 1 2 doi 10 1080 00445096 1965 11447347 Leiner NO Setz EF Silva WR February 2008 Semelparity and Factors Affecting the Reproductive Activity of the Brazilian Slender Opossum Marmosps paulensis in Southeastern Brazil Journal of Mammalogy 89 1 153 158 doi 10 1644 07 MAMM A 083 1 Young Truman P Carol K Augspurger 1991 Ecology and evolution of long lived semelparous plants Trends in Ecology and Evolution 6 9 285 289 doi 10 1016 0169 5347 91 90006 J PMID 21232483 a b c Oakwood Meri Bradley Adrian J Cockburn Andrew 2001 02 22 Semelparity in a large marsupial Proceedings of the Royal Society of London B Biological Sciences 268 1465 407 411 doi 10 1098 rspb 2000 1369 ISSN 0962 8452 PMC 1088621 PMID 11270438 Paul Moorcroft Life History Strategies lecture Harvard University Cambridge MA 9 February 2009 Roff Derek A 1992 The Evolution of Life Histories Springer ISBN 0 412 02391 1 Lamont C Cole The Population Consequences of Life History Phenomena The Quarterly Review of Biology 29 no 2 June 1954 103 137 Charnov E L Schaffer W M 1973 Life history consequences of natural selection Cole s result revisited PDF American Naturalist 107 958 791 793 doi 10 1086 282877 S2CID 83561052 Young T P 1981 A general model of comparative fecundity for semelparous and iteroparous life histories American Naturalist 118 27 36 doi 10 1086 283798 S2CID 83860904 Young T P 1990 The evolution of semelparity in Mount Kenya lobelias Evolutionary Ecology 4 2 157 171 doi 10 1007 bf02270913 S2CID 25993809 Lesica P Young T P 2005 Demographic model explains life history evolution in Arabis fecunda Functional Ecology 19 3 471 477 doi 10 1111 j 1365 2435 2005 00972 x S2CID 31222891 a b c d Woolley Patricia 1966 01 01 Reproduction in Antechinus spp and other Dasyurid marsupials Symposia of the Zoological Society of London 15 281 294 a b Bradley A J McDonald I R Lee A K 1980 Stress and mortality in a small marsupial Antechinus stuartii Macleay General and Comparative Endocrinology 40 2 188 200 doi 10 1016 0016 6480 80 90122 7 PMID 6245013 Bradley A J July 1987 Stress and mortality in the red tailed phascogale Phascogale calura Marsupialia Dasyuridae General and Comparative Endocrinology 67 1 85 100 doi 10 1016 0016 6480 87 90208 5 ISSN 0016 6480 PMID 3623073 Cockburn A Living slow and dying young senescence in marsupials Marsupial Biology Recent Research New Perspectives University of New South Wales Press Sydney 1997 163 171 a b Lucia Maria Annual age structure and reproductive patterns in Marmosa incana Lund 1841 Didelphidae Marsupialia 1994 Martins Eduardo G Bonato Vinicius da Silva Cibele Q Reis Dos F Sergio 2006 10 17 Partial Semelparity in the Neotropical Didelphid Marsupial Gracilinanus microtarsus Journal of Mammalogy 87 5 915 920 doi 10 1644 05 mamm a 403r1 1 ISSN 0022 2372 Dickhoff Walton W 1989 Salmonids and Annual Fishes Death After Sex Development Maturation and Senescence of Neuroendocrine Systems pp 253 266 doi 10 1016 b978 0 12 629060 8 50017 5 ISBN 9780126290608 Morbey Yolanda E Brassil Chad E Hendry Andrew P 2005 Rapid Senescence in Pacific Salmon The American Naturalist 166 5 556 568 doi 10 1086 491720 PMID 16224721 S2CID 13880884 Gende Scott M Quinn Thomas P Hilborn Ray Hendry Andrew P Dickerson Bobette 2004 03 01 Brown bears selectively kill salmon with higher energy content but only in habitats that facilitate choice Oikos 104 3 518 528 doi 10 1111 j 0030 1299 2004 12762 x ISSN 1600 0706 S2CID 5961141 a b c Fritz Robert S Stamp Nancy E Halverson Timothy G 1982 Iteroparity and Semelparity in Insects The American Naturalist 120 2 264 268 doi 10 1086 283987 JSTOR 2461222 S2CID 85228942 The Gypsy Moth Research Toward Integrated Pest Management United States Department of Agriculture 1981 Fisher Diana O Dickman Christopher R Jones Menna E Blomberg Simon P 2013 10 29 Sperm competition drives the evolution of suicidal reproduction in mammals Proceedings of the National Academy of Sciences 110 44 17910 17914 Bibcode 2013PNAS 11017910F doi 10 1073 pnas 1310691110 ISSN 0027 8424 PMC 3816400 PMID 24101455 Braithwaite Richard W Lee Anthony K 1979 A Mammalian Example of Semelparity The American Naturalist 113 1 151 155 doi 10 1086 283372 JSTOR 2459950 S2CID 84672183 Kindsvater Holly K Braun Douglas C Otto Sarah P Reynolds John D 2016 HUL Access 2 0 Ecology Letters 19 6 687 696 doi 10 1111 ele 12607 PMID 27146705 S2CID 205108696 Kline Thomas C Goering John J Piorkowski Robert J 1997 Freshwaters of Alaska Ecological Studies Springer New York NY pp 179 204 doi 10 1007 978 1 4612 0677 4 7 ISBN 9781461268666 Tallamy Douglas W Brown William P 1999 Semelparity and the evolution of maternal care in insects Animal Behaviour 57 3 727 730 doi 10 1006 anbe 1998 1008 PMID 10196065 S2CID 2260549 Further reading Edit peer reviewed Nature Education Knowledge entry on Semelparity De Wreede R E and T Klinger Reproductive strategies in algae pp 267 276 in Plant Reproductive Ecology Patterns and Strategies J L Lovett Doust amp L L Lovett Doust eds Oxford University Press Fritz R S Stamp N E Halverson T G 1982 Iteroparity and semelparity in insects The American Naturalist 120 2 264 68 doi 10 1086 283987 S2CID 85228942 Ranta E Tesar D Kaitala V 2002 Environmental variability and semelparity vs iteroparity as life histories Journal of Theoretical Biology 217 3 391 398 Bibcode 2002JThBi 217 391R doi 10 1006 jtbi 2002 3029 PMID 12270282 Retrieved from https en wikipedia org w index php title Semelparity and iteroparity amp 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