Your search keyword '"Preston JC"' showing total 4 results

1. Shedding light on the role of seasonal flowering in plant niche transitions.

Author

Fjellheim S and Preston JC

Subjects

Magnoliopsida growth & development, Seasons, Biological Evolution, Ecosystem, Flowers growth & development, Magnoliopsida physiology

Published

2018

2. Organ boundary NAC-domain transcription factors are implicated in the evolution of petal fusion.

Author

Zhong J, Powell S, and Preston JC

Subjects

Biological Evolution, Cotyledon anatomy & histology, Cotyledon genetics, Flowers anatomy & histology, Gene Silencing, Mutation, Petunia anatomy & histology, Phenotype, Phylogeny, Plant Proteins metabolism, Transcription Factors genetics, Transcription Factors metabolism, Flowers genetics, Petunia genetics, Plant Proteins genetics

Abstract

Research rationale: Evolution of fused petals (sympetaly) is considered to be an important innovation that has repeatedly led to increased pollination efficiency, resulting in accelerated rates of plant diversification. Although little is known about the underlying regulation of sympetaly, genetic pathways ancestrally involved in organ boundary establishment (e.g. CUP SHAPED COTYLEDON [CUC] 1-3 genes) are strong candidates. In sympetalous petunia, mutations in the CUC1/2-like orthologue NO APICAL MERISTEM (NAM) inhibit shoot apical meristem formation. Despite this, occasional 'escape shoots' develop flowers with extra petals and fused inter-floral whorl organs. Central methods: To To determine if petunia CUC-like genes regulate additional floral patterning, we used virus-induced silencing (VIGS) following establishment of healthy shoot apices to re-examine the role of NAM in petunia petal development, and uniquely characterise the CUC3 orthologue NH16., Key Results: Confirming previous results, we found that reduced floral NAM/NH16 expression caused increased petal-stamen and stamen-carpel fusion, and often produced extra petals. However, further to previous results, all VIGS plants infected with NAM or NH16 constructs exhibited reduced fusion in the petal whorl compared to control plants., Main Conclusions: Together with previous data, our results demonstrate conservation of petunia CUC-like genes in establishing inter-floral whorl organ boundaries, as well as functional evolution to affect the fusion of petunia petals., (© 2016 German Botanical Society and The Royal Botanical Society of the Netherlands.)

Published

2016

3. Reduce, reuse, and recycle: developmental evolution of trait diversification.

Author

Preston JC, Hileman LC, and Cubas P

Subjects

Flowers anatomy & histology, Flowers genetics, Flowers growth & development, Flowers ultrastructure, Genetic Pleiotropy, Plants genetics, Biological Evolution, Genetic Variation, Plant Development, Quantitative Trait, Heritable

Abstract

A major focus of evolutionary developmental (evo-devo) studies is to determine the genetic basis of variation in organismal form and function, both of which are fundamental to biological diversification. Pioneering work on metazoan and flowering plant systems has revealed conserved sets of genes that underlie the bauplan of organisms derived from a common ancestor. However, the extent to which variation in the developmental genetic toolkit mirrors variation at the phenotypic level is an active area of research. Here we explore evidence from the angiosperm evo-devo literature supporting the frugal use of genes and genetic pathways in the evolution of developmental patterning. In particular, these examples highlight the importance of genetic pleiotropy in different developmental modules, thus reducing the number of genes required in growth and development, and the reuse of particular genes in the parallel evolution of ecologically important traits.

Published

2011

4. MADS-box gene expression and implications for developmental origins of the grass spikelet.

Author

Preston JC, Christensen A, Malcomber ST, and Kellogg EA

Abstract

Basic questions regarding the origin and evolution of grass (Poaceae) inflorescence morphology remain unresolved, including the developmental genetic basis for evolution of the highly derived outer spikelet organs. To evaluate homologies between the outer sterile organs of grass spikelets and inflorescence structures of nongrass monocot flowers, we describe expression patterns of APETALA1/FRUITFULL-like (AP1/FUL) and LEAFY HULL STERILE-like (LHS1) MADS-box genes in an early-diverging grass (Streptochaeta angustifolia) and a nongrass outgroup (Joinvillea ascendens). AP1/FUL-like genes are expressed only in floral organs of J. ascendens, supporting the hypothesis that they mark the floral boundary in nongrass monocots, and JaLHS1/OsMADS5 is expressed in the inner and outer tepals, stamen filaments and pistil. In S. angustifolia, SaFUL2 is expressed in all 11 (or 12) bracts of the primary inflorescence branch, but not in the suppressed floral bract below the abscission zone. In contrast, SaLHS1 is only expressed in bracts 6-11 (or 12). Together, these data are consistent with the hypotheses that (1) bracts 1-5 of S. angustifolia primary inflorescence branches and glumes of grass spikelets are homologous and that (2) the outer tepals of immediate grass relatives, bracts 6-8 of S. angustifolia, and the lemma/palea are homologous, although other explanations are possible.

Published

2009