Speciation is the evolutionary process by which new biological species arise. Biologists research species using different theoretical frameworks for what constitutes a species (see
species problem and
species complex) and there exists debate with regard to delineation. Nevertheless, much of the current research suggests that, "...speciation is a process of emerging genealogical distinctness, rather than a discontinuity affecting all genes simultaneously" and, in allopatry (the most common form of speciation), "reproductive isolation is a byproduct of evolutionary change in isolated populations, and thus can be considered an evolutionary accident". Speciation occurs as the result of the latter (allopatry); however, a variety of differing agents have been documented and are often defined and classified in various forms (e.g. peripatric, parapatric, sympatric, polyploidization, hybridization, etc.). Instances of speciation have been observed in both nature and the laboratory. A.-B Florin and A. Ödeen note that, "strong laboratory evidence for allopatric speciation is lacking..."; however, contrary to laboratory studies (focused specifically on models of allopatric speciation), "speciation most definitely occurs; [and] the vast amount of evidence from nature makes it unreasonable to argue otherwise". Coyne and Orr compiled a list of 19 laboratory experiments on
Drosophila presenting examples of allopatric speciation by divergent selection concluding that, "reproductive isolation in allopatry can evolve as a byproduct of divergent selection". Research documenting speciation is abundant. Biologists have documented numerous examples of speciation in nature—with evolution having produced far more species than any observer would consider necessary. For example, there are well over 350,000 described species of beetles. Examples of speciation come from the observations of island biogeography and the process of adaptive radiation, both explained previously. Evidence of common descent can also be found through paleontological studies of speciation within geologic strata. The examples described below represent different modes of speciation and provide strong evidence for common descent. Not all speciation research directly observes divergence from "start-to-finish". This is by virtue of research delimitation and definition ambiguity, and occasionally leads research towards historical reconstructions. In light of this, examples abound, and the following are by no means exhaustive—comprising only a small fraction of the instances observed. Once again, take note of the established fact that, "...natural selection is a ubiquitous part of speciation...", Extensive investigation of the fossil record has led to numerous theories concerning speciation (in the context of paleontology) with many of the studies suggesting that stasis,
punctuation, and lineage branching are common. In 1995, D. H. Erwin, et al. published a major work—
New Approaches to Speciation in the Fossil Record—which compiled 58 studies of fossil speciation (between 1972 and 1995) finding most of the examples suggesting stasis (involving
anagenesis or punctuation) and 16 studies suggesting speciation. Many of the studies conducted utilize
seafloor sediments that can provide a significant amount of data concerning
planktonic microfossils. See figure 6a.
Radiolaria In a large study of five species of
radiolarians (
Calocycletta caepa,
Pterocanium prismatium,
Pseudoculous vema,
Eucyrtidium calvertense, and
Eucyrtidium matuyamai), the researchers documented considerable evolutionary change in each lineage. Alongside this, trends with the closely related species
E. calvertense and
E. matuyamai showed that about 1.9
Mya
E. calvertense invaded a new region of the Pacific, becoming isolated from the main population. The stratigraphy of this species clearly shows that this isolated population evolved into
E. matuyamai. It then reinvaded the region of the still-existing and static
E. calvertense population whereby a sudden decrease in body size occurred. Eventually the invader
E. matuyamai disappeared from the stratum (presumably due to extinction) coinciding with a desistance of size reduction of the
E. calvertense population. From that point on, the change in size leveled to a constant. The authors suggest competition-induced
character displacement.
Rhizosolenia Researchers conducted measurements on 5,000
Rhizosolenia (a planktonic
diatom) specimens from eight sedimentary cores in the Pacific Ocean. The core samples spanned two million years and were chronologized using sedimentary magnetic field reversal measurements. All the core samples yielded a similar pattern of divergence: with a single lineage (
R. bergonii) occurring before 3.1
Mya and two morphologically distinct lineages (daughter species:
R. praebergonii) appearing after. The parameters used to measure the samples were consistent throughout each core. An additional study of the daughter species
R. praebergonii found that, after the divergence, it invaded the Indian Ocean.
Turborotalia A recent study was conducted involving the planktonic
foraminifer Turborotalia. The authors extracted "51 stratigraphically ordered samples from a site within the oceanographically stable tropical
North Pacific gyre". Two hundred individual species were examined using ten specific morphological traits (size, compression index, chamber aspect ratio, chamber inflation, aperture aspect ratio, test height, test expansion, umbilical angle, coiling direction, and the number of chambers in the final whorl). Utilizing multivariate statistical
clustering methods, the study found that the species continued to evolve non-directionally within the
Eocene from 45
Ma to about 36
Ma. However, from 36
Ma to approximately 34
Ma, the stratigraphic layers showed two distinct clusters with significantly defining characteristics distinguishing one another from a single species. The authors concluded that speciation must have occurred and that the two new species were descended from the prior species.
Vertebrates There exists evidence for vertebrate speciation despite limitations imposed by the fossil record. Studies have been conducted documenting similar patterns seen in marine invertebrates. A study of four mammalian genera:
Hyopsodus,
Pelycodus,
Haplomylus (three from the Eocene), and
Plesiadapis (from the Paleocene) found that—through a large number of stratigraphic layers and specimen sampling—each group exhibited, "gradual phyletic evolution, overall size increase, iterative evolution of small species, and character divergence following the origin of each new lineage". The authors of this study concluded that speciation was discernible. In another study concerning morphological trends and rates of evolution found that the European
arvicolid rodent radiated into 52 distinct lineages over a time frame of 5
million years while documenting examples of phyletic gradualism, punctuation, and stasis.
Invertebrates Drosophila melanogaster '') William R. Rice and George W. Salt found experimental evidence of
sympatric speciation in the
common fruit fly. They collected a population of
Drosophila melanogaster from
Davis, California, and placed the pupae into a habitat maze. Newborn flies had to investigate the maze to find food. The flies had three choices to take in finding food. Light and dark (
phototaxis), up and down (
geotaxis), and the scent of
acetaldehyde and the scent of ethanol (
chemotaxis) were the three options. This eventually divided the flies into 42 spatio-temporal habitats. They then cultured two strains that chose opposite habitats. One of the strains emerged early, immediately flying upward in the dark attracted to the
acetaldehyde. The other strain emerged late and immediately flew downward, attracted to light and ethanol. Pupae from the two strains were then placed together in the maze and allowed to mate at the food site. They then were collected. A selective penalty was imposed on the female flies that switched habitats. This entailed that none of their
gametes would pass on to the next generation. After 25 generations of this mating test, it showed reproductive isolation between the two strains. They repeated the experiment again without creating the penalty against habitat switching and the result was the same; reproductive isolation was produced.
Gall wasps A study of the
gall-forming wasp species
Belonocnema treatae found that populations inhabiting different host plants (
Quercus geminata and
Q. virginiana) exhibited different body size and
gall morphology alongside a strong expression of sexual isolation. The study hypothesized that
B. treatae populations inhabiting different host plants would show evidence of
divergent selection promoting speciation. The researchers sampled gall wasp species and oak tree localities, measured body size (right hand
tibia of each wasp), and counted gall chamber numbers. In addition to measurements, they conducted mating assays and statistical analyses. Genetic analysis was also conducted on two
mtDNA sites (416 base pairs from cytochrome C and 593 base pairs from cytochrome oxidase ) to "control for the confounding effects of time since divergence among
allopatric populations". In an additional study, the researchers studied two gall wasp species
B. treatae and
Disholcaspis quercusvirens and found strong morphological and behavioral variation among host-associated populations. This study further confounded prerequisites to speciation.
Hawthorn fly One example of evolution at work is the case of the hawthorn fly,
Rhagoletis pomonella, also known as the apple maggot fly, which appears to be undergoing
sympatric speciation. Different populations of hawthorn fly feed on different fruits. A distinct population emerged in North America in the 19th century some time after
apples, a non-native species, were introduced. This apple-feeding population normally feeds only on apples and not on the historically preferred fruit of
hawthorns. The current hawthorn feeding population does not normally feed on apples. Some evidence, such as the fact that six out of thirteen
allozyme loci are different, that hawthorn flies mature later in the season and take longer to mature than apple flies; and that there is little evidence of interbreeding (researchers have documented a 4–6% hybridization rate) suggests that speciation is occurring.
London Underground mosquito The
London Underground mosquito is a species of
mosquito in the genus
Culex found in the
London Underground. It evolved from the overground species
Culex pipiens. This mosquito, although first discovered in the London Underground system, has been found in underground systems around the world. It is suggested that it may have adapted to human-made underground systems since the last century from local above-ground
Culex pipiens, are extremely difficult to mate, and with different allele frequency, consistent with genetic drift during a
founder event. More specifically, this mosquito,
Culex pipiens molestus, breeds all-year round, is cold intolerant, and bites rats, mice, and humans, in contrast to the above ground species
Culex pipiens that is cold tolerant, hibernates in the winter, and bites only birds. When the two varieties were cross-bred the eggs were infertile suggesting reproductive isolation. a single fixed
microsatellite difference in populations spanning Europe, Japan, Australia, the middle East and Atlantic islands.
Snapping shrimp and the isthmus of Panama Debate exists determining when the
isthmus of Panama closed. Much of the evidence supports a closure approximately 2.7 to 3.5
mya using "...multiple lines of evidence and independent surveys". However, a recent study suggests an earlier, transient bridge existed 13 to 15
mya. Regardless of the timing of the isthmus closer, biologists can study the species on the Pacific and Caribbean sides in, what has been called, "one of the greatest natural experiments in evolution." and contributed to the literature concerning rates of
molecular evolution. Phylogenetic reconstructions using "multilocus datasets and coalescent-based analytical methods" support the relationships of the species in the group As stated before, many biologists rely on the biological species concept, with some modern researchers utilizing the
phylogenetic species concept. Debate exists in the field concerning which framework should be applied in the research. With the advent of molecular markers, "hybridization [is] considerably more frequent than previously believed".
Hybridization between two different species sometimes leads to a distinct phenotype. This phenotype can also be fitter than the parental lineage and as such, natural selection may then favor these individuals. Eventually, if reproductive isolation is achieved, it may lead to a separate species. However, reproductive isolation between hybrids and their parents is particularly difficult to achieve and thus
hybrid speciation is considered a rare event. However, hybridization resulting in reproductive isolation is considered an important means of speciation in plants, since polyploidy (having more than two copies of each chromosome) is tolerated in plants more readily than in animals.
Polyploidy is important in hybrids as it allows reproduction, with the two different sets of chromosomes each being able to pair with an identical partner during meiosis. Hybridization without change in chromosome number is called homoploid hybrid speciation. It is considered very rare but has been shown in
Heliconius butterflies and
sunflowers. Polyploid speciation, which involves changes in chromosome number, is a more common phenomenon, especially in plant species. Polyploidy is a mechanism that has caused many rapid speciation events in sympatry because offspring of, for example, tetraploid x diploid matings often result in triploid sterile progeny. Not all polyploids are reproductively isolated from their parental plants, and gene flow may still occur for example through triploid hybrid x diploid matings that produce tetraploids, or matings between
meiotically unreduced gametes from diploids and gametes from tetraploids. It has been suggested that many of the existing plant and most animal species have undergone an event of polyploidization in their evolutionary history. Reproduction of successful polyploid species is sometimes asexual, by
parthenogenesis or
apomixis, as for unknown reasons many asexual organisms are polyploid. Rare instances of polyploid mammals are known, but most often result in prenatal death. Researchers consider reproductive isolation as key to speciation. A major aspect of speciation research is to determine the nature of the barriers that inhibit reproduction. Botanists often consider the zoological classifications of prezygotic and postzygotic barriers as inadequate.
Raphanobrassica Raphanobrassica includes all intergeneric hybrids between the genera
Raphanus (radish) and
Brassica (cabbages, etc.). The
Raphanobrassica is an
allopolyploid cross between the
radish (
Raphanus sativus) and
cabbage (
Brassica oleracea). Plants of this parentage are now known as radicole. Two other fertile forms of
Raphanobrassica are known. Raparadish, an allopolyploid hybrid between
Raphanus sativus and
Brassica rapa is grown as a fodder crop. "Raphanofortii" is the allopolyploid hybrid between
Brassica tournefortii and
Raphanus caudatus. The
Raphanobrassica is a fascinating plant, because (in spite of its hybrid nature), it is not sterile. This has led some botanists to propose that the accidental hybridization of a flower by pollen of another species in nature could be a mechanism of speciation common in higher plants.
Senecio (groundsel) The Welsh groundsel is an allopolyploid, a plant that contains sets of chromosomes originating from two different species. Its ancestor was
Senecio × baxteri, an infertile hybrid that can arise spontaneously when the closely related groundsel (
Senecio vulgaris) and Oxford ragwort (
Senecio squalidus) grow alongside each other. Sometime in the early 20th century, an accidental doubling of the number of chromosomes in an
S. × baxteri plant led to the formation of a new fertile species. The
York groundsel (
Senecio eboracensis) is a hybrid species of the
self-incompatible Senecio squalidus (also known as Oxford ragwort) and the self-compatible
Senecio vulgaris (also known as common groundsel). Like
S. vulgaris,
S. eboracensis is self-compatible; however, it shows little or no natural crossing with its parent species, and is therefore reproductively isolated, indicating that strong breed barriers exist between this new hybrid and its parents. It resulted from a
backcrossing of the
F1 hybrid of its parents to
S. vulgaris.
S. vulgaris is native to Britain, while
S. squalidus was introduced from Sicily in the early 18th century; therefore,
S. eboracensis has speciated from those two species within the last 300 years. Other hybrids descended from the same two parents are known. Some are infertile, such as
S. x
baxteri. Other fertile hybrids are also known, including
S. vulgaris var. hibernicus, now common in Britain, and the
allohexaploid S. cambrensis, which according to molecular evidence probably originated independently at least three times in different locations. Morphological and genetic evidence support the status of
S. eboracensis as separate from other known hybrids.
Thale cress '' (colloquially known as thale cress, mouse-ear cress or arabidopsis)
Kirsten Bomblies et al. from the
Max Planck Institute for Developmental Biology discovered two genes in the thale cress plant,
Arabidopsis thaliana. When both genes are inherited by an individual, it ignites a reaction in the hybrid plant that turns its own immune system against it. In the parents, the genes were not detrimental, but they evolved separately to react defectively when combined. To test this, Bomblies crossed 280 genetically different strains of
Arabidopsis in 861 distinct ways and found that 2 percent of the resulting hybrids were necrotic. Along with allocating the same indicators, the 20 plants also shared a comparable collection of genetic activity in a group of 1,080 genes. In almost all of the cases, Bomblies discovered that only two genes were required to cause the autoimmune response. Bomblies looked at one hybrid in detail and found that one of the two genes belonged to the
NB-LRR class, a common group of disease resistance genes involved in recognizing new infections. When Bomblies removed the problematic gene, the hybrids developed normally.
Tragopogon (salsify) ''
Tragopogon is one example where hybrid speciation has been observed. In the early 20th century, humans introduced three species of salsify into North America. These species, the western salsify (
Tragopogon dubius), the meadow salsify (
Tragopogon pratensis), and the
oyster plant (
Tragopogon porrifolius), are now common weeds in urban wastelands. In the 1950s, botanists found two new species in the regions of
Idaho and
Washington, where the three already known species overlapped. One new species,
Tragopogon miscellus, is a
tetraploid hybrid of
T. dubius and
T. pratensis. The other new species,
Tragopogon mirus, is also an allopolyploid, but its ancestors were
T. dubius and
T. porrifolius. These new species are usually referred to as "the Ownbey hybrids" after the botanist who first described them. The
T. mirus population grows mainly by reproduction of its own members, but additional episodes of hybridization continue to add to the
T. mirus population.
T. dubius and
T. pratensis mated in Europe but were never able to hybridize. A study published in March 2011 found that when these two plants were introduced to North America in the 1920s, they mated and doubled the number of chromosomes in there hybrid
Tragopogon miscellus allowing for a "reset" of its genes, which in turn, allows for greater genetic variation. Professor Doug Soltis of the
University of Florida said, "We caught evolution in the act...New and diverse patterns of gene expression may allow the new species to rapidly adapt in new environments".
Vertebrates Blackcap The bird species,
Sylvia atricapilla, commonly referred to as blackcaps, lives in Germany and flies southwest to Spain while a smaller group flies northwest to Great Britain during the winter. Gregor Rolshausen from the
University of Freiburg found that the genetic separation of the two populations is already in progress. The differences found have arisen in about 30 generations. With DNA sequencing, the individuals can be assigned to a correct group with an 85% accuracy. Stuart Bearhop from the
University of Exeter reported that birds wintering in England tend to mate only among themselves, and not usually with those wintering in the Mediterranean. It is still inference to say that the populations will become two different species, but researchers expect it due to the continued genetic and geographic separation.
Mollies The shortfin molly (
Poecilia mexicana) is a small fish that lives in the
Sulfur Caves of Mexico. Years of study on the species have found that two distinct populations of mollies—the dark interior fish and the bright surface water fish—are becoming more genetically divergent. The populations have no obvious barrier separating the two; however, it was found that the mollies are hunted by a large water bug (
Belostoma spp). Tobler collected the bug and both types of mollies, placed them in large plastic bottles, and put them back in the cave. After a day, it was found that, in the light, the cave-adapted fish endured the most damage, with four out of every five stab-wounds from the water bugs sharp mouthparts. In the dark, the situation was the opposite. The mollies' senses can detect a predator's threat in their own habitats, but not in the other ones. Moving from one habitat to the other significantly increases the risk of dying. Tobler plans on further experiments, but believes that it is a good example of the rise of a new species.
Polar bear Natural selection, geographic isolation, and speciation in progress are illustrated by the relationship between the
polar bear (
Ursus maritimus) and the
brown bear (
Ursus arctos). Considered separate species throughout their ranges; however, it has been documented that they possess the capability to interbreed and produce fertile offspring. This
introgressive hybridization has occurred both in the wild and in captivity and has been documented and verified with DNA testing. The oldest known fossil evidence of polar bears dates around 130,000 to 110,000 years ago; however, molecular data has revealed varying estimates of divergence time. Mitochondrial DNA analysis has given an estimate of 150,000 years ago Recent research using the complete genomes (rather than mtDNA or partial nuclear genomes) establishes the divergence of polar and brown bears between 479 and 343 thousand years ago. Despite the differences in divergence rates, molecular research suggests the sister species have undergone a highly complex process of speciation and admixture between the two. The polar bear has acquired anatomical and physiological differences from the brown bear that allow it to comfortably survive in conditions that the brown bear likely could not. Notable examples include the ability to swim sixty miles or more at a time in freezing waters, fur that blends with the snow, and to stay warm in the arctic environment, an elongated neck that makes it easier to keep their heads above water while swimming, and oversized and heavy-matted webbed feet that act as paddles when swimming. It has also evolved small papillae and vacuole-like suction cups on the soles to make them less likely to slip on the ice, alongside smaller ears for a reduction of heat loss, eyelids that act like sunglasses, accommodations for their all-meat diet, a large stomach capacity to enable opportunistic feeding, and the ability to fast for up to nine months while recycling their urea. ==Evidence from coloration==