Evolution of Salamander Life Cycles: a Major-effect Quantitative Trait Locus Contributes to Discrete and Continuous Variation for Metamorphic Timing

Overview

Journal Genetics

Publisher Oxford University Press

Specialty Genetics

Date 2005 Mar 23

PMID 15781701

Citations 25

Authors

S R Voss

J J Smith

Affiliations

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Abstract

The evolution of alternate modes of development may occur through genetic changes in metamorphic timing. This hypothesis was examined by crossing salamanders that express alternate developmental modes: metamorphosis vs. paedomorphosis. Three strains were used in the crossing design: Ambystoma tigrinum tigrinum (Att; metamorph), wild-caught A. mexicanum (Am; paedomorph), and laboratory Am (paedomorph). Att/Am hybrids were created for each Am strain and then backcrossed to their respective Am line. Previous studies have shown that a dominant allele from Att (met(Att)) and a recessive allele from lab Am (met(lab)) results in metamorphosis in Att/Am hybrids, and met(Att)/met(lab) and met(lab)/met(lab) backcross genotypes are strongly associated with metamorphosis and paedomorphosis, respectively. We typed a molecular marker (contig325) linked to met and found that met(Att)/met(lab) and met(Att)/met(wild) were associated with metamorphosis in 99% of the cases examined. However, the frequency of paedomorphosis was 4.5 times higher for met(lab)/met(lab) than for met(wild)/met(wild). We also found that met(Att)/met(wild) and met(wild)/met(wild) genotypes discriminated distributions of early and late metamorphosing individuals. Two forms of phenotypic variation are contributed by met: continuous variation of metamorphic age and expression of discrete, alternate morphs. We suggest that the evolution of paedomorphosis is associated with genetic changes that delay metamorphic timing in biphasic life cycles.

Citing Articles

Large-scale variation in single nucleotide polymorphism density within the laboratory axolotl (Ambystoma mexicanum).

Timoshevskaya N, Voss S, Labianca C, High C, Smith J Dev Dyn. 2020; 250(6):822-837.

PMID: 33001517 PMC: 8715502. DOI: 10.1002/dvdy.257.

Rediscovering the Axolotl as a Model for Thyroid Hormone Dependent Development.

Crowner A, Khatri S, Blichmann D, Voss S Front Endocrinol (Lausanne). 2019; 10:237.

PMID: 31031711 PMC: 6473073. DOI: 10.3389/fendo.2019.00237.

The role of predation risk in metamorphosis versus behavioural avoidance: a sex-specific study in a facultative paedomorphic amphibian.

Denoel M, Drapeau L, Oromi N, Winandy L Oecologia. 2019; 189(3):637-645.

PMID: 30809707 DOI: 10.1007/s00442-019-04362-8.

A chromosome-scale assembly of the axolotl genome.

Smith J, Timoshevskaya N, Timoshevskiy V, Keinath M, Hardy D, Voss S Genome Res. 2019; 29(2):317-324.

PMID: 30679309 PMC: 6360810. DOI: 10.1101/gr.241901.118.

The 'male escape hypothesis': sex-biased metamorphosis in response to climatic drivers in a facultatively paedomorphic amphibian.

Mathiron A, Lena J, Baouch S, Denoel M Proc Biol Sci. 2017; 284(1853).

PMID: 28424346 PMC: 5413923. DOI: 10.1098/rspb.2017.0176.

References

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Voss S, Prudic K, Oliver J, Shaffer H . Candidate gene analysis of metamorphic timing in ambystomatid salamanders. Mol Ecol. 2003; 12(5):1217-23. DOI: 10.1046/j.1365-294x.2003.01806.x. View

Putta S, Smith J, Walker J, Rondet M, Weisrock D, Monaghan J . From biomedicine to natural history research: EST resources for ambystomatid salamanders. BMC Genomics. 2004; 5(1):54. PMC: 509418. DOI: 10.1186/1471-2164-5-54. View

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