Your search keyword '"Curran, Emma V."' showing total 11 results

1. Contrasted histories of organelle and nuclear genomes underlying physiological diversification in a grass species

Author

Bianconi, Matheus E., Dunning, Luke T., Curran, Emma V., Hidalgo, Oriane, Powell, Robyn F., Mian, Sahr, Leitch, Ilia J., Lundgren, Marjorie R., Manzi, Sophie, Vorontsova, Maria S., Besnard, Guillaume, Osborne, Colin P., Olofsson, Jill K., and Christin, Pascal-Antoine

Published

2020

2. Leaf anatomy explains the strength of C4 activity within the grass species Alloteropsis semialata.

Author

Alenazi, Ahmed S., Bianconi, Matheus E., Middlemiss, Ella, Milenkovic, Vanja, Curran, Emma V., Sotelo, Graciela, Lundgren, Marjorie R., Nyirenda, Florence, Pereira, Lara, Christin, Pascal‐Antoine, Dunning, Luke T., and Osborne, Colin P.

Subjects

LEAF anatomy, CARBON 4 photosynthesis, ANATOMICAL variation, CARBON isotopes, COMPARATIVE method

Abstract

C4 photosynthesis results from anatomical and biochemical characteristics that together concentrate CO2 around ribulose‐1,5‐bisphosphate carboxylase/oxygenase (Rubisco), increasing productivity in warm conditions. This complex trait evolved through the gradual accumulation of components, and particular species possess only some of these, resulting in weak C4 activity. The consequences of adding C4 components have been modelled and investigated through comparative approaches, but the intraspecific dynamics responsible for strengthening the C4 pathway remain largely unexplored. Here, we evaluate the link between anatomical variation and C4 activity, focusing on populations of the photosynthetically diverse grass Alloteropsis semialata that fix various proportions of carbon via the C4 cycle. The carbon isotope ratios in these populations range from values typical of C3 to those typical of C4 plants. This variation is statistically explained by a combination of leaf anatomical traits linked to the preponderance of bundle sheath tissue. We hypothesize that increased investment in bundle sheath boosts the strength of the intercellular C4 pump and shifts the balance of carbon acquisition towards the C4 cycle. Carbon isotope ratios indicating a stronger C4 pathway are associated with warmer, drier environments, suggesting that incremental anatomical alterations can lead to the emergence of C4 physiology during local adaptation within metapopulations. Summary Statement: Intraspecific analyses of photosynthetically diverse Alloteropsis semialata populations show that strengthening of the C4 photosynthetic pathway is associated with changes in multiple leaf anatomical traits. Stronger C4 activity is correlated with warmer, drier habitats, indicating local adaptation. [ABSTRACT FROM AUTHOR]

Published

2023

3. The genetic basis of structural colour variation in mimetic Heliconius butterflies.

Author

Brien, Melanie N., Enciso-Romero, Juan, Lloyd, Victoria J., Curran, Emma V., Parnell, Andrew J., Morochz, Carlos, Salazar, Patricio A., Rastas, Pasi, Zinn, Thomas, and Nadeau, Nicola J.

Subjects

STRUCTURAL colors, LOCUS (Genetics), BUTTERFLIES, OPTICAL reflection, SURFACE brightness (Astronomy)

Abstract

Structural colours, produced by the reflection of light from ultrastructures, have evolved multiple times in butterflies. Unlike pigmentary colours and patterns, little is known about the genetic basis of these colours. Reflective structures on wing-scale ridges are responsible for iridescent structural colour in many butterflies, including the Müllerian mimics Heliconius erato and Heliconius melpomene. Here, we quantify aspects of scale ultrastructure variation and colour in crosses between iridescent and non-iridescent subspecies of both of these species and perform quantitative trait locus (QTL) mapping. We show that iridescent structural colour has a complex genetic basis in both species, with offspring from crosses having a wide variation in blue colour (both hue and brightness) and scale structure measurements. We detect two different genomic regions in each species that explain modest amounts of this variation, with a sex-linked QTL in H. erato but not H. melpomene. We also find differences between species in the relationships between structure and colour, overall suggesting that these species have followed different evolutionary trajectories in their evolution of structural colour. We then identify genes within the QTL intervals that are differentially expressed between subspecies and/or wing regions, revealing likely candidates for genes controlling structural colour formation. This article is part of the theme issue 'Genetic basis of adaptation and speciation: from loci to causative mutations'. [ABSTRACT FROM AUTHOR]

Published

2022

4. Upregulation of C4 characteristics does not consistently improve photosynthetic performance in intraspecific hybrids of a grass.

Author

Bianconi, Matheus E., Sotelo, Graciela, Curran, Emma V., Milenkovic, Vanja, Samaritani, Emanuela, Dunning, Luke T., Bertolino, Lígia T., Osborne, Colin P., and Christin, Pascal‐Antoine

Subjects

CARBON 4 photosynthesis, GENE expression profiling, CARBON fixation, LEAF anatomy, BIOCHEMISTRY, CARBON isotopes

Abstract

C4 photosynthesis is thought to have evolved via intermediate stages, with changes towards the C4 phenotype gradually enhancing photosynthetic performance. This hypothesis is widely supported by modelling studies, but experimental tests are missing. Mixing of C4 components to generate artificial intermediates can be achieved via crossing, and the grass Alloteropsis semialata represents an outstanding study system since it includes C4 and non‐C4 populations. Here, we analyse F1 hybrids between C3 and C4, and C3+C4 and C4 genotypes to determine whether the acquisition of C4 characteristics increases photosynthetic performance. The hybrids have leaf anatomical characters and C4 gene expression profiles that are largely intermediate between those of their parents. Carbon isotope ratios are similarly intermediate, which suggests that a partial C4 cycle coexists with C3 carbon fixation in the hybrids. This partial C4 phenotype is associated with C4‐like photosynthetic efficiency in C3+C4 × C4, but not in C3 × C4 hybrids, which are overall less efficient than both parents. Our results support the hypothesis that the photosynthetic gains from the upregulation of C4 characteristics depend on coordinated changes in anatomy and biochemistry. The order of acquisition of C4 components is thus constrained, with C3+C4 species providing an essential step for C4 evolution. Summary statement: We analyse hybrids between C3 and C4, and C3+C4 and C4 accessions of the grass Alloteropsis semialata. While hybrids have upregulated C4 features, these do not consistently increase photosynthetic efficiency, highlighting the importance of the order of acquisition of components during C4 evolution. [ABSTRACT FROM AUTHOR]

Published

2022

5. Hybridization boosts dispersal of two contrasted ecotypes in a grass species.

Author

Curran, Emma V., Scott, Matilda S., Olofsson, Jill K., Nyirenda, Florence, Sotelo, Graciela, Bianconi, Matheus E., Manzi, Sophie, Besnard, Guillaume, Pereira, Lara, and Christin, Pascal-Antoine

Subjects

*SPECIES hybridization, *CHLOROPLAST DNA, *SPECIES, *GENE flow, *GRASSES, *PLANT hybridization

Abstract

Genetic exchanges between closely related groups of organisms with different adaptations have well-documented beneficial and detrimental consequences. In plants, pollen-mediated exchanges affect the sorting of alleles across physical landscapes and influence rates of hybridization. How these dynamics affect the emergence and spread of novel phenotypes remains only partially understood. Here, we use phylogenomics and population genomics to retrace the origin and spread of two geographically overlapping ecotypes of the African grass Alloteropsis angusta. In addition to an ecotype inhabiting wetlands, we report the existence of a previously undescribed ecotype inhabiting Miombo woodlands and grasslands. The two ecotypes are consistently associated with different nuclear groups, which represent an advanced stage of divergence with secondary lowlevel gene flow. However, the seed-transported chloroplast genomes are consistently shared by distinct ecotypes inhabiting the same region. These patterns suggest that the nuclear genome of one ecotype can enter the seeds of the other via occasional pollen movements with sorting of nuclear groups in subsequent generations. The contrasting ecotypes of A. angusta can thus use each other as a gateway to new locations across a large part of Africa, showing that hybridization can facilitate the geographical dispersal of distinct ecotypes of the same grass species. [ABSTRACT FROM AUTHOR]

Published

2022

6. Low dispersal and ploidy differences in a grass maintain photosynthetic diversity despite gene flow and habitat overlap.

Author

Olofsson, Jill K., Curran, Emma V., Nyirenda, Florence, Bianconi, Matheus E., Dunning, Luke T., Milenkovic, Vanja, Sotelo, Graciela, Hidalgo, Oriane, Powell, Robyn F., Lundgren, Marjorie R., Leitch, Ilia J., Nosil, Patrik, Osborne, Colin P., and Christin, Pascal‐Antoine

Subjects

*PLOIDY, *CARBON 4 photosynthesis, *HABITATS, *CURRENT distribution, *SPECIES diversity, *POPULATION genetics, *GENE flow, *PLANT ecology

Abstract

Geographical isolation facilitates the emergence of distinct phenotypes within a single species, but reproductive barriers or selection are needed to maintain the polymorphism after secondary contact. Here, we explore the processes that maintain intraspecific variation of C4 photosynthesis, a complex trait that results from the combined action of multiple genes. The grass Alloteropsis semialata includes C4 and non‐C4 populations, which have coexisted as a polyploid series for more than 1 million years in the miombo woodlands of Africa. Using population genomics, we show that there is genome‐wide divergence for the photosynthetic types, but the current geographical distribution does not reflect a simple habitat displacement scenario as the genetic clusters overlap, being occasionally mixed within a given habitat. Despite evidence of recurrent introgression between non‐C4 and C4 groups, in both diploids and polyploids, the distinct genetic lineages retain their identity, potentially because of selection against hybrids. Coupled with strong isolation by distance within each genetic group, this selection created a geographical mosaic of photosynthetic types. Diploid C4 and non‐C4 types never grew together, and the C4 type from mixed populations constantly belonged to the hexaploid lineage. By limiting reproductive interactions between photosynthetic types, the ploidy difference probably allows their co‐occurrence, reinforcing the functional diversity within this species. Together, these factors enabled the persistence of divergent physiological traits of ecological importance within a single species despite gene flow and habitat overlap. [ABSTRACT FROM AUTHOR]

Published

2021

7. Müllerian mimicry of a quantitative trait despite contrasting levels of genomic divergence and selection.

Author

Curran, Emma V., Stankowski, Sean, Pardo‐Diaz, Carolina, Salazar, Camilo, Linares, Mauricio, and Nadeau, Nicola J.

Subjects

*HYBRID zones, *MIMICRY (Biology), *GENE flow, *AIRPLANE wings, *MELANOGENESIS, *ORNITHOPTERS

Abstract

Hybrid zones, where distinct populations meet and interbreed, give insight into how differences between populations are maintained despite gene flow. Studying clines in genetic loci and adaptive traits across hybrid zones is a powerful method for understanding how selection drives differentiation within a single species, but can also be used to compare parallel divergence in different species responding to a common selective pressure. Here, we study parallel divergence of wing colouration in the butterflies Heliconius erato and H. melpomene, which are distantly related Müllerian mimics which show parallel geographic variation in both discrete variation in pigmentation, and quantitative variation in structural colour. Using geographic cline analysis, we show that clines in these traits are positioned in roughly the same geographic region for both species, which is consistent with direct selection for mimicry. However, the width of the clines varies markedly between species. This difference is explained in part by variation in the strength of selection acting on colour traits within each species, but may also be influenced by differences in the dispersal rate and total strength of selection against hybrids between the species. Genotyping‐by‐sequencing also revealed weaker population structure in H. melpomene, suggesting the hybrid zones may have evolved differently in each species, which may also contribute to the patterns of phenotypic divergence in this system. Overall, we conclude that multiple factors are needed to explain patterns of clinal variation within and between these species, although mimicry has probably played a central role. [ABSTRACT FROM AUTHOR]

Published

2020

8. Leaf anatomy explains the strength of C 4 activity within the grass species Alloteropsis semialata.

Author

Alenazi AS, Bianconi ME, Middlemiss E, Milenkovic V, Curran EV, Sotelo G, Lundgren MR, Nyirenda F, Pereira L, Christin PA, Dunning LT, and Osborne CP

Subjects

Photosynthesis physiology, Carbon metabolism, Carbon Isotopes metabolism, Plant Leaves metabolism, Carbon Dioxide metabolism, Poaceae metabolism, Plants metabolism

Abstract

C 4 photosynthesis results from anatomical and biochemical characteristics that together concentrate CO 2 around ribulose-1,5-bisphosphate carboxylase/oxygenase (Rubisco), increasing productivity in warm conditions. This complex trait evolved through the gradual accumulation of components, and particular species possess only some of these, resulting in weak C 4 activity. The consequences of adding C 4 components have been modelled and investigated through comparative approaches, but the intraspecific dynamics responsible for strengthening the C 4 pathway remain largely unexplored. Here, we evaluate the link between anatomical variation and C 4 activity, focusing on populations of the photosynthetically diverse grass Alloteropsis semialata that fix various proportions of carbon via the C 4 cycle. The carbon isotope ratios in these populations range from values typical of C 3 to those typical of C 4 plants. This variation is statistically explained by a combination of leaf anatomical traits linked to the preponderance of bundle sheath tissue. We hypothesize that increased investment in bundle sheath boosts the strength of the intercellular C 4 pump and shifts the balance of carbon acquisition towards the C 4 cycle. Carbon isotope ratios indicating a stronger C 4 pathway are associated with warmer, drier environments, suggesting that incremental anatomical alterations can lead to the emergence of C 4 physiology during local adaptation within metapopulations., (© 2023 The Authors. Plant, Cell & Environment published by John Wiley & Sons Ltd.)

Published

2023

9. Upregulation of C 4 characteristics does not consistently improve photosynthetic performance in intraspecific hybrids of a grass.

Author

Bianconi ME, Sotelo G, Curran EV, Milenkovic V, Samaritani E, Dunning LT, Bertolino LT, Osborne CP, and Christin PA

Subjects

Carbon Cycle, Plant Leaves physiology, Up-Regulation genetics, Photosynthesis physiology, Poaceae genetics

Abstract

C 4 photosynthesis is thought to have evolved via intermediate stages, with changes towards the C 4 phenotype gradually enhancing photosynthetic performance. This hypothesis is widely supported by modelling studies, but experimental tests are missing. Mixing of C 4 components to generate artificial intermediates can be achieved via crossing, and the grass Alloteropsis semialata represents an outstanding study system since it includes C 4 and non-C 4 populations. Here, we analyse F1 hybrids between C 3 and C 4 , and C 3 +C 4 and C 4 genotypes to determine whether the acquisition of C 4 characteristics increases photosynthetic performance. The hybrids have leaf anatomical characters and C 4 gene expression profiles that are largely intermediate between those of their parents. Carbon isotope ratios are similarly intermediate, which suggests that a partial C 4 cycle coexists with C 3 carbon fixation in the hybrids. This partial C 4 phenotype is associated with C 4 -like photosynthetic efficiency in C 3 +C 4  × C 4 , but not in C 3  × C 4 hybrids, which are overall less efficient than both parents. Our results support the hypothesis that the photosynthetic gains from the upregulation of C 4 characteristics depend on coordinated changes in anatomy and biochemistry. The order of acquisition of C 4 components is thus constrained, with C 3 +C 4 species providing an essential step for C 4 evolution., (© 2022 The Authors. Plant, Cell & Environment published by John Wiley & Sons Ltd.)

Published

2022

10. Phenotypic variation in Heliconius erato crosses shows that iridescent structural colour is sex-linked and controlled by multiple genes.

Author

Brien MN, Enciso-Romero J, Parnell AJ, Salazar PA, Morochz C, Chalá D, Bainbridge HE, Zinn T, Curran EV, and Nadeau NJ

Abstract

Bright, highly reflective iridescent colours can be seen across nature and are produced by the scattering of light from nanostructures. Heliconius butterflies have been widely studied for their diversity and mimicry of wing colour patterns. Despite iridescence evolving multiple times in this genus, little is known about the genetic basis of the colour and the development of the structures which produce it. Heliconius erato can be found across Central and South America, but only races found in western Ecuador and Colombia have developed blue iridescent colour. Here, we use crosses between iridescent and non-iridescent races of H. erato to study phenotypic variation in the resulting F 2 generation. Using measurements of blue colour from photographs, we find that iridescent structural colour is a quantitative trait controlled by multiple genes, with strong evidence for loci on the Z sex chromosome. Iridescence is not linked to the Mendelian colour pattern locus that also segregates in these crosses (controlled by the gene cortex ). Small-angle X-ray scattering data show that spacing between longitudinal ridges on the scales, which affects the intensity of the blue reflectance, also varies quantitatively in F 2 crosses., Competing Interests: We declare we have no competing interests.

Published

2019

11. Wing scale ultrastructure underlying convergent and divergent iridescent colours in mimetic Heliconius butterflies.

Author

Parnell AJ, Bradford JE, Curran EV, Washington AL, Adams G, Brien MN, Burg SL, Morochz C, Fairclough JPA, Vukusic P, Martin SJ, Doak S, and Nadeau NJ

Subjects

Animals, Biological Evolution, Butterflies anatomy & histology, Butterflies genetics, Color, Genotype, Microscopy, Electron, Scanning, Phylogeny, Scattering, Small Angle, Spectrum Analysis, Butterflies ultrastructure, Iridescence, Wings, Animal ultrastructure

Abstract

Iridescence is an optical phenomenon whereby colour changes with the illumination and viewing angle. It can be produced by thin film interference or diffraction. Iridescent optical structures are fairly common in nature, but relatively little is known about their production or evolution. Here we describe the structures responsible for producing blue-green iridescent colour in Heliconius butterflies. Overall the wing scale structures of iridescent and non-iridescent Heliconius species are very similar, both having longitudinal ridges joined by cross-ribs. However, iridescent scales have ridges composed of layered lamellae, which act as multilayer reflectors. Differences in brightness between species can be explained by the extent of overlap of the lamellae and their curvature as well as the density of ridges on the scale. Heliconius are well known for their Müllerian mimicry. We find that iridescent structural colour is not closely matched between co-mimetic species. Differences appear less pronounced in models of Heliconius vision than models of avian vision, suggesting that they are not driven by selection to avoid heterospecific courtship by co-mimics. Ridge profiles appear to evolve relatively slowly, being similar between closely related taxa, while ridge density evolves faster and is similar between distantly related co-mimics., (© 2018 The Authors.)

Published

2018