Laboratory experiments of speciation have been conducted for all four modes of speciation: allopatric, peripatric, parapatric, and sympatric; and various other processes involving speciation: hybridization, reinforcement, founder effects, among others. Most of the experiments have been done on flies, in particular Drosophila fruit flies.[1] However, more recent studies have tested yeasts, fungi, and even viruses.
It has been suggested that laboratory experiments are not conducive to vicariant speciation events (allopatric and peripatric) due to their small population sizes and limited generations.[2] Most estimates from studies of nature indicate that speciation takes hundreds of thousands to millions of years.[3] On the other hand, many species are thought to have speciated faster and more recently, such as the European flounders (Platichthys flesus) that spawn in pelagic and demersal zones—having allopatrically speciated in under 3000 generations.[4]
Table of experiments
editSix publications have attempted to compile, review, and analyze the experimental research on speciation:
- John Ringo, David Wood, Robert Rockwell, and Harold Dowse in 1985;[5]
- William R. Rice and Ellen E. Hostert in 1993;[6]
- Ann-Britt Florin and Anders Ödeen in 2002;[2]
- Mark Kirkpatrick and Virginie Ravigné in 2002;[7]
- Jerry A. Coyne and H. Allen Orr in 2004;[1] and
- James D. Fry in 2009.[8]
The table summarizes the studies and data reviewed in these publications. It also references several contemporary experiments and is non-exhaustive. In the table, multiple numbers separated by semi-colons in the generations column indicate that multiple experiments were conducted. The replications (in parentheses) indicates the number of populations used in the experiments—i.e. how many times the experiment was replicated. Various types of selection have been imposed on experimental populations and are indicated by the selection type column. Negative or positive results of each experiment are provided by the reproductive isolation column. Pre-zygotic reproductive isolation means that the reproducing individuals in the populations were unable to produce offspring (effectively a positive result). Post-zygotic isolation means that the reproducing individuals were able to produce offspring but they were either sterile or inviable (a positive result as well). Negative results are indicated by "none"—that is, the experiments did not result in reproductive isolation.
Species | Trait | Generations (replications) [duration] | Tested | Selection type | Studied genetic drift | Reproductive isolation | Reference | Year |
---|---|---|---|---|---|---|---|---|
Drosophila melanogaster | Escape response | 18 | Vicariant, reinforcement, parapatric/
sympatric |
Indirect; divergent | Yes | Pre-zygotic | Grant & Mettler[9] | 1969 |
D. melanogaster | Locomotion | 112 | Vicariant | Indirect; divergent | No | Pre-zygotic | Burnet & Connolly[10] | 1974 |
D. melanogaster | Temperature, humidity | 70–130 | Vicariant | Indirect; divergent | Yes | Pre-zygotic | Kilias et al.[11] | 1980 |
D. melanogaster | DDT adaptation | 600 [25 years, +15 years] | Vicariant | Direct | No | Pre-zygotic | Boake et al.[12] | 2003 |
D. melanogaster | 17, 9, 9, 1, 1, 7, 7, 7, 7 | Vicariant; parapatric/
sympatric |
Direct, divergent | Pre-zygotic in vicariance; none with gene flow | Barker & Karlsson[13] | 1974 | ||
D. melanogaster | 40; 50 | Reinforcement | Direct; divergent | Pre-zygotic | Crossley[14] | 1974 | ||
D. melanogaster | Locomotion | 45 | Vicariant | Direct; divergent | No | None | van Dijken & Scharloo[15][16] | 1979 |
D. melanogaster | Reinforcement | Direct; divergent | Pre-zygotic | Wallace[17] | 1953 | |||
D. melanogaster | 36; 31 | Reinforcement | Direct; divergent | Pre-zygotic | Knight[18] | 1956 | ||
D. melanogaster | EDTA adaptation | 25, 25, 25, 14 | Semi-allopatric, reinforcement | Indirect; divergent | No | Post-zygotic | Robertson[19][20] | 1966 |
D. melanogaster | 25 (8) | Vicariant; reinforcement; parapatric; sympatric | Direct | None | Hostert[21] | 1997 | ||
D. melanogaster | Abdominal chaeta
number |
21–31 | Vicariant | Direct | Yes | None | Santibanez & Waddington[22] | 1958 |
D. melanogaster | Sternopleural chaeta number | 32 | Vicariant, reinforcement, parapatric/
sympatric |
Direct | No | None | Barker & Cummins[23] | 1969 |
D. melanogaster | Phototaxis, geotaxis | 20 | Vicariant | No | None | Markow[24][25] | 1975; 1981 | |
D. melanogaster | Peripatric | Yes | Rundle et al.[26] | 1998 | ||||
D. melanogaster | Vicariant; peripatric | Yes | Mooers et al.[27] | 1999 | ||||
D. melanogaster | 12 | Reinforcement | Divergent | Pre-zygotic | Thoday & Gibson[28] | 1962 | ||
D. melanogaster | None | Thoday & Gibson[29][30] | 1970; 1971 | |||||
D. melanogaster | 16 | Reinforcement | Indirect | None | Spiess & Wilke[31] | 1954 | ||
D. melanogaster | Reinforcement | Direct; divergent | Pre-zygotic | Ehrman[32][33][34][35] | 1971; 1973; 1979; 1983 | |||
D. melanogaster | Sternopleural chaeta number | 5; 27; 27; 1; 1; 1; 1; 1 | Parapatric/
sympatric |
None | Chabora[36] | 1968 | ||
D. melanogaster | None | Scharloo[37] | 1967 | |||||
D. melanogaster | 1, 1 | Coyne & Grant[38] | 1972 | |||||
D. melanogaster | 25 | Rice[39] | 1985 | |||||
D. melanogaster | 25 | Disruptive | Pre-zygotic | Rice & Salt[40] | 1988 | |||
D. melanogaster | 35; 35 | Sympatric | Pre-zygotic | Rice & Salt[41] | 1990 | |||
D. melanogaster | NaCl and CuSO4 levels in food | [3 years in allopatry, 1 in sympatry] | Allopatric; reinforcement; sympatric | Pre-zygotic in allopatry, none in sympatry | Wallace[42] | 1982 | ||
D. melanogaster | Reinforcement | Ehrman et al.[43] | 1991 | |||||
D. melanogaster | Reinforcement | Fukatami & Moriwaki[44] | 1970 | |||||
Drosophila simulans | Scutellar bristles, development speed, wing width; desiccation resistance, fecundity, ethanol resistance; courtship display, re-mating speed, lek behavior; pupation height, clumped egg laying, general activity | [3 years] | Vicariant; peripatric | Yes | Post-zygotic | Ringo et al.[5] | 1985 | |
Drosophila paulistorum | 131; 131 | Reinforcement | Direct | Pre-zygotic | Dobzhansky et al.[45] | 1976 | ||
D. paulistorum | [5 years] | Vicariant | Dobzhansky and Pavlovsky[46] | 1966 | ||||
Drosophila willistoni | pH adaptation | 34–122 | Vicariant | Indirect; divergent | No | Pre-zygotic | Kalisz & Cordeiro[47] | 1980 |
Drosophila pseudoobscura | Carbohydrate source | 12 | Vicariant | Indirect | Yes | Pre-zygotic | Dodd[48] | 1989 |
D. pseudoobscura | Temperature adaptation | 25–60 | Vicariant | Direct | Ehrman[49][50][51][52][53] | 1964;
1969 | ||
D. pseudoobscura | Phototaxis, geotaxis | 5–11 | Vicariant | Indirect | No | Pre-zygotic | del Solar[54] | 1966 |
D. pseudoobscura | Vicariant; peripatric | Pre-zygotic | Powell[55][56] | 1978; 1985 | ||||
D. pseudoobscura | Peripatric; vicariant | Yes | Galiana et al.[57] | 1993 | ||||
D. pseudoobscura | Temperature photoperiod; food | 37 (78) [33–34 months] | Vicariant | Divergent | Yes | None | Rundle[58] | 2003 |
D. pseudoobscura & | 22; 16; 9 | Reinforcement | Direct; divergent | Pre-zygotic | Koopman[59] | 1950 | ||
D. pseudoobscura &
D. persimilis |
18 (4) | Direct | Pre-zygotic | Kessler[60] | 1966 | |||
Drosophila mojavensis | 12 | Direct | Pre-zygotic | Koepfer[61] | 1987 | |||
D. mojavensis | Development time | 13 | Divergent | Yes | None | Etges[62] | 1998 | |
Drosophila adiastola | Peripatric | Yes | Pre-zygotic | Arita & Kaneshiro[63] | 1974 | |||
Drosophila silvestris | Peripatric | Yes | Ahearn[64] | 1980 | ||||
Musca domestica | Geotaxis | 38 | Vicariant | Indirect | No | Pre-zygotic | Soans et al.[65] | 1974 |
M. domestica | Geotaxis | 16 | Vicariant | Direct; divergent | No | Pre-zygotic | Hurd & Eisenburg[66] | 1975 |
M. domestica | Peripatric | Yes | Meffert & Bryant[67] | 1991 | ||||
M. domestica | Regan et al.[68] | 2003 | ||||||
Bactrocera cucurbitae | Development time | 40–51 | Divergent | Yes | Pre-zygotic | Miyatake & Shimizu[69] | 1999 | |
Zea mays | 6; 6 | Reinforcement | Direct; divergent | Pre-zygotic | Paterniani[70] | 1969 | ||
Drosophila grimshawi | Peripatric | Jones, Widemo, & Arrendal[71] | N/A | |||||
Saccharomyces cerevisiae | Leu & Murry[72] | 2006 | ||||||
D. melanogaster | Reinforcement | Harper & Lambert[73] | 1983 | |||||
Tribolium castaneum | Pupal weight | 15 (6) | Disruptive | Halliburton & Gall[74] | 1983 | |||
D. melanogaster | Geotaxis | Divergent | Lofdahl et al.[75] | 1992 | ||||
D. pseudoobscura | [10 years] | Moya et al.[76] | 1995 | |||||
Neurospora | Divergent | Dettman et al.[77] | 2008 | |||||
S. cerevisiae | 500 | Divergent | Dettman et al.[78] | 2007 | ||||
Sepsis cynipsea | 35 | Martin & Hosken[79] | 2003 | |||||
D. melanogaster | Wigby & Chapman[80] | 2006 | ||||||
D. pseudoobscura | Sexual conflict | 48–52 (4; 4; 4) | Bacigalupe et al.[81] | 2007 | ||||
D. serrata | Rundle et al.[82] | 2005 | ||||||
Drosophila serrata & D. birchii | Mate recognition | 9 (3; 3) | Reinforcement | Natural | Pre-zygotic | Higgie et al.[83] | 2000 | |
Enterobacteria phage λ | Escherichia coli receptor exploitation | 35 cycles (6) | Vicariant, sympatric | Pre-zygotic | Meyer et al.[84] | 2016 | ||
Tetranychus urticae | Resistance to host plant toxin | Overmeer[85] | 1966 | |||||
T. urticae | Resistance to host plant toxin | Fry[86] | 1999 | |||||
Helianthus annus × H. petiolaris and H. anomalus | Hybrid | Rieseburg et al.[87] | 1996 | |||||
S. cerevisiae | Greig et al.[88] | 2002 | ||||||
D. melanogaster | Life history | Ghosh & Joshi[89] | 2012 | |||||
Drosophila subobscura | Mate behavior | Bárbaro et al.[90] | 2015 | |||||
Digital organisms | ~42,000; ~850 (20) | Ecological | Post-zygotic | Anderson & Harmon[91] | 2014 | |||
Schizosaccharomyces pombe | Complete reproductive isolation | Seike et al.[92] | 2015 | |||||
D. pseudoobscura | Courtship song | 130 | Debelle et al.[93] | 2014 | ||||
Callosobruchus maculatus | 40 (16) | Debelle et al.[94] | 2010 |
See also
editReferences
edit- ^ a b c Coyne, Jerry A.; Orr, H. Allen (2004), Speciation, Sinauer Associates, pp. 1–545, ISBN 978-0-87893-091-3
- ^ a b c Florin, Ann-Britt & Ödeen, Anders (2002), "Laboratory environments are not conducive for allopatric speciation", Journal of Evolutionary Biology, 15 (1): 10–19, doi:10.1046/j.1420-9101.2002.00356.x
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- ^ Momigliano, Paolo; Jokinen, Henri; Fraimout, Antoine; Florin, Ann-Britt; Norkko, Alf; Merilä, Juha (2017), "Extraordinarily rapid speciation in a marine fish" (PDF), PNAS, 114 (23): 6074–6079, Bibcode:2017PNAS..114.6074M, doi:10.1073/pnas.1615109114, PMC 5468626, PMID 28533412
- ^ a b Ringo, John; Wood, David; Rockwell, Robert; Dowse, Harold (1985), "An Experiment Testing Two Hypotheses of Speciation", The American Naturalist, 126 (5): 642–661, doi:10.1086/284445, S2CID 84819968
- ^ a b Rice, William R. & Hostert, Ellen E. (1993), "Laboratory Experiments on Speciation: What Have We Learned in 40 Years?", Evolution, 47 (6): 1637–1653, doi:10.1111/j.1558-5646.1993.tb01257.x, PMID 28568007, S2CID 42100751
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