Drosophila americana as a Model Species for Comparative Studies on the Molecular Basis of Phenotypic Variation

AbstractPhenotypic plasticity, the ability of one genotype to produce different phenotypes in different environments, plays a central role in species’ response to environmental changes. Transgenerational plasticity (TGP) allows the transmission of this environmentally-induced phenotypic variation across generations, and can influence adaptation. To date, the genetic control of TGP, its long-term stability, and its potential costs remain largely unknown, mostly because empirical demonstrations of TGP across many generations in several genetic backgrounds are scarce. Here, we examined how genotype determines the TGP of dispersal, a fundamental process in ecology and evolution. We used an experimental approach involving ~200 clonal generations in a model-species of ciliate to determine if and how TGP influences the expression of dispersal-related traits in several genotypes. Our results show that morphological and movement traits associated with dispersal are plastic, and that these modifications are inherited over at least 35 generations. We also highlight that genotype modulates the fitness costs and benefits associated with plastic dispersal strategies. Our study suggests that genotype-dependent TGP could play a critical role in eco-evolutionary dynamics as dispersal determines gene flow and the long-term persistence of natural populations. More generally, it outlines the tremendous importance that genotype-dependent TGP could have in the ability of organisms to cope with current and future environmental changes.SignificanceThe genetic control of the transgenerational plasticity is still poorly understood despite its critical role in species responses to environmental changes. We examined how genotype determines transgenerational plasticity of a complex trait (i.e., dispersal) in a model-species of ciliate across ~200 clonal generations. Our results provide evidence that plastic phenotypic variation linked to dispersal is stably inherited over tens of generations and that cell genotype modulates the expression and fitness cost of transgenerational plasticity.

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Molecular genetic basis of flower colour variegation in Linaria

Genetics Research ◽

10.1017/s0016672307008786 ◽

2007 ◽

Vol 89 (3) ◽

pp. 129-134 ◽

Cited By ~ 8

Author(s):

LISETE GALEGO ◽

JORGE ALMEIDA

Keyword(s):

Molecular Basis ◽

Genetic Basis ◽

Anthocyanin Biosynthesis ◽

Molecular Genetic ◽

Flower Colour ◽

Close Relative ◽

Model Species ◽

Gene Encoding ◽

Genetic Studies ◽

Molecular Genetic Basis

SummaryTo identify transposons that may be of use for mutagenesis we investigated the genetic molecular basis of a case of flower colour variegation in Linaria, a close relative of the model species Antirrhinum majus. We show that this variegation is attributable to an unstable mutant allele of the gene encoding dihydroflavonol-4-reductase, one of the enzymes required for anthocyanin biosynthesis. This allele carries an insertion of a transposon belonging to the CACTA family (Tl1, Transposon Linaria 1) which blocks its expression thus conferring an ivory flower colour phenotype. Tl1 is occasionally excised in dividing epidermal cells to produce clonal patches of red tissue on the ivory background, and in cells giving rise to gametes to generate reversion alleles conferring a fully coloured phenotype. This finding may open the way for targeted transposon-mutagenesis in Linaria, and hence for using this genus in comparative genetic studies.

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Molecular basis of laccase bound to lignin: insight from comparative studies on the interaction of Trametes versicolor laccase with various lignin model compounds

RSC Advances ◽

10.1039/c5ra07916k ◽

2015 ◽

Vol 5 (65) ◽

pp. 52307-52313 ◽

Cited By ~ 31

Author(s):

Ming Chen ◽

Guangming Zeng ◽

Cui Lai ◽

Jian Li ◽

Piao Xu ◽

...

Keyword(s):

Comparative Studies ◽

Molecular Basis ◽

Trametes Versicolor ◽

Model Compounds ◽

Lignin Model Compounds ◽

Lignin Model ◽

Binding Orientation

Binding orientation of lignin model compounds in laccase.

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Arabidopsis thaliana: a Model Plant for Studying the Molecular Basis of Morphogenesis

Functional Plant Biology ◽

10.1071/pp9900323 ◽

1990 ◽

Vol 17 (3) ◽

pp. 323 ◽

Cited By ~ 6

Author(s):

DR Smyth

Keyword(s):

Arabidopsis Thaliana ◽

Life Cycle ◽

Genetic Control ◽

Molecular Basis ◽

Higher Plants ◽

Mutant Form ◽

Chromosome Walking ◽

Model Species ◽

Dna Hybridisation

Morphogenesis in higher plants is likely to be controlled by the serial activation of genes. These genes could be identified if the structure which they normally control is specifically disrupted when they are in mutant form. By cloning and characterising the products of such genes we could gain an understanding of the genetic control of morphogenesis. This report makes a case for following this strategy using Arabidopsis thaliana as a model species. This species is easily grown, has a short, 6-week life cycle and convenient genetics. Mutations affecting embryogenesis, trichome structure, the inflorescence and floral organs are already known. Because Arabidopsis has a tiny genome (70 000 kbp), cloning of genes known only by mutant phenotype is practicable by chromosome walking and DNA tagging. The role of their products in cellular and developmental decisions could then be investigated. Genes controlling morphogenesis are likely to be conserved across higher plants. Once they have been cloned from a model species their isolation from other species by DNA hybridisation is relatively simple. Generalisations about the origin, action and evolution of such genes would then be possible. Also artificial manipulation of morphogenesis may be achievable.

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