What are some forms of isolation that create pre-zygotic barriers leading to speciation.

18.2B: Reproductive Isolation

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Reproductive isolation, through mechanical, behavioral, and physiological barriers, is an important component of speciation.

Learning Objectives

• Explain how reproductive isolation can consequence in speciation

Cardinal Points

• Reproductive isolation can exist either prezygotic (barriers that prevent fertilization ) or postzygotic (barriers that occur after zygote formation such as organisms that die as embryos or those that are born sterile).
• Some species may be prevented from mating with each other by the incompatibility of their anatomical mating structures, or a resulting offspring may exist prevented by the incompatibility of their gametes.
• Postzygotic barriers include the creation of hybrid individuals that do not survive by the embryonic stages ( hybrid inviability ) or the creation of a hybrid that is sterile and unable to produce offspring ( hybrid sterility ).
• Temporal isolation can result in species that are physically similar and may even live in the aforementioned habitat, only if their breeding schedules practise non overlap and so interbreeding will never occur.
• Behavioral isolation, in which the behaviors involved in mating are and so unique as to prevent mating, is a prezygotic barrier that can cause two otherwise-compatible species to be uninterested in mating with each other.
• Behavioral isolation, in which the behaviors involved in mating are so unique equally to prevent mating, is a prezygotic bulwark that can cause two otherwise compatible species to exist uninterested in mating with each other.

Key Terms

• reproductive isolation: a drove of mechanisms, behaviors, and physiological processes that prevent two different species that mate from producing offspring, or which ensure that any offspring produced is not fertile
• temporal isolation: factors that forestall potentially fertile individuals from meeting that reproductively isolate the members of singled-out species
• behavioral isolation: the presence or absence of a specific behavior that prevents reproduction betwixt two species from taking place
• prezygotic barrier: a mechanism that blocks reproduction from taking place by preventing fertilization
• postzygotic barrier: a mechanism that blocks reproduction afterward fertilization and zygote formation
• hybrid inviability: a situation in which a mating between 2 individuals creates a hybrid that does not survive by the embryonic stages
• hybrid sterility: a situation in which a mating between ii individuals creates a hybrid that is sterile

Reproductive Isolation

Given plenty time, the genetic and phenotypic departure between populations will bear upon characters that influence reproduction: if individuals of the two populations were to be brought together, mating would be improbable, simply if mating did occur, offspring would be not-viable or infertile. Many types of diverging characters may affect reproductive isolation, the ability to interbreed, of the ii populations. Reproductive isolation is a collection of mechanisms, behaviors, and physiological processes that preclude the members of 2 different species that cross or mate from producing offspring, or which ensure that whatever offspring that may be produced is not fertile.

Scientists classify reproductive isolation in 2 groups: prezygotic barriers and postzygotic barriers. Recall that a zygote is a fertilized egg: the first cell of the development of an organism that reproduces sexually. Therefore, a prezygotic barrier is a mechanism that blocks reproduction from taking place; this includes barriers that forbid fertilization when organisms endeavour reproduction. A postzygotic barrier occurs after zygote formation; this includes organisms that don't survive the embryonic stage and those that are born sterile.

Some types of prezygotic barriers preclude reproduction entirely. Many organisms only reproduce at sure times of the year, often just annually. Differences in breeding schedules, called temporal isolation, tin can act as a class of reproductive isolation. For example, ii species of frogs inhabit the aforementioned area, but 1 reproduces from January to March, whereas the other reproduces from March to May.

Figure \(\PageIndex{1}\): Temporal isolation: These two related frog species exhibit temporal reproductive isolation. (a) Rana aurora breeds earlier in the twelvemonth than (b) Rana boylii.

In some cases, populations of a species motility to a new habitat and take up residence in a place that no longer overlaps with other populations of the same species; this is called habitat isolation. Reproduction with the parent species ceases and a new group exists that is at present reproductively and genetically independent. For example, a cricket population that was divided later on a alluvion could no longer collaborate with each other. Over time, the forces of natural option, mutation, and genetic drift will probable result in the deviation of the two groups.

Figure \(\PageIndex{one}\): Habitat isolation: Speciation can occur when two populations occupy different habitats. The habitats demand not exist far apart. The cricket (a) Gryllus pennsylvanicus prefers sandy soil, while the cricket (b) Gryllus firmus prefers loamy soil. The two species tin live in close proximity, but because of their different soil preferences, they became genetically isolated.

Behavioral isolation occurs when the presence or absence of a specific behavior prevents reproduction from taking identify. For example, male person fireflies use specific light patterns to attract females. Diverse species display their lights differently; if a male of ane species tried to attract the female of another, she would non recognize the light blueprint and would not mate with the male person.

Other prezygotic barriers work when differences in their gamete cells prevent fertilization from taking place; this is called a gametic barrier. Similarly, in some cases, closely-related organisms try to mate, just their reproductive structures only do not fit together. For case, damselfly males of different species take differently-shaped reproductive organs. If one species tries to mate with the female of some other, their trunk parts simply do non fit together..

Effigy \(\PageIndex{1}\): Differences in reproductive structures in male damselflies: The shape of the male reproductive organ varies among male damselfly species and is only compatible with the female of that species. Reproductive organ incompatibility keeps the species reproductively isolated.

In plants, certain structures aimed to attract one blazon of pollinator simultaneously prevent a different pollinator from accessing the pollen. The tunnel through which an animal must admission nectar tin can vary in length and diameter, which prevents the plant from being cross-pollinated with a different species.

Figure \(\PageIndex{ane}\): Reproductive isolation in plants: Some flowers take evolved to attract certain pollinators. The (a) wide foxglove bloom is adapted for pollination by bees, while the (b) long, tube-shaped trumpet creeper flower is adapted for pollination by humming birds.

When fertilization takes place and a zygote forms, postzygotic barriers can foreclose reproduction. Hybrid individuals in many cases cannot form normally in the womb and just do not survive past the embryonic stages; this is called hybrid inviability. In another postzygotic situation, reproduction leads to the birth and growth of a hybrid that is sterile and unable to reproduce offspring of their own; this is called hybrid sterility.

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Source: https://bio.libretexts.org/Bookshelves/Introductory_and_General_Biology/Book:_General_Biology_%28Boundless%29/18:_Evolution_and_the_Origin_of_Species/18.2:_Formation_of_New_Species/18.2B:_Reproductive_Isolation

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