Michael W. Frohlich scite author profile

Gene duplication plays important roles in organismal evolution, because duplicate genes provide raw materials for the evolution of mechanisms controlling physiological and/or morphological novelties. Gene duplication can occur via several mechanisms, including segmental duplication, tandem duplication and retroposition. Although segmental and tandem duplications have been found to be important for the expansion of a number of multigene families, the contribution of retroposition is not clear. Here we show that plant SKP1 genes have evolved by multiple duplication events from a single ancestral copy in the most recent common ancestor (MRCA) of eudicots and monocots, resulting in 19 ASK (Arabidopsis SKP1-like) and 28 OSK (Oryza SKP1-like) genes. The estimated birth rates are more than ten times the average rate of gene duplication, and are even higher than that of other rapidly duplicating plant genes, such as type I MADS box genes, R genes, and genes encoding receptor-like kinases. Further analyses suggest that a relatively large proportion of the duplication events may be explained by tandem duplication, but few, if any, are likely to be due to segmental duplication. In addition, by mapping the gain/loss of a specific intron on gene phylogenies, and by searching for the features that characterize retrogenes/retrosequences, we show that retroposition is an important mechanism for expansion of the plant SKP1 gene family. Specifically, we propose that two and three ancient retroposition events occurred in lineages leading to Arabidopsis and rice, respectively, followed by repeated tandem duplications and chromosome rearrangements. Our study represents a thorough investigation showing that retroposition can play an important role in the evolution of a plant gene family whose members do not encode mobile elements.

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The Mostly Male Theory of Flower Evolutionary Origins: From Genes to Fossils

Frohlich¹,

Parker²

2000

Systematic Botany

258

155

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Asterid Phylogenomics/Phylotranscriptomics Uncover Morphological Evolutionary Histories and Support Phylogenetic Placement for Numerous Whole-Genome Duplications

et al. 2020

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Abstract Asterids are one of the most successful angiosperm lineages, exhibiting extensive morphological diversity and including a number of important crops. Despite their biological prominence and value to humans, the deep asterid phylogeny has not been fully resolved, and the evolutionary landscape underlying their radiation remains unknown. To resolve the asterid phylogeny, we sequenced 213 transcriptomes/genomes and combined them with other datasets, representing all accepted orders and nearly all families of asterids. We show fully supported monophyly of asterids, Berberidopsidales as sister to asterids, monophyly of all orders except Icacinales, Aquifoliales and Bruniales, and monophyly of all families except Icacinaceae and Ehretiaceae. Novel taxon placements benefited from the expanded sampling with living collections from botanical gardens, resolving hitherto uncertain relationships. The remaining ambiguous placements here are likely due to limited sampling and could be addressed in the future with relevant additional taxa. Using our well-resolved phylogeny as reference, divergence time estimates support an Aptian (Early Cretaceous) origin of asterids and the origin of all orders before the K-Pg boundary. Ancestral state reconstruction at the family level suggests that the asterid ancestor was a woody terrestrial plant with simple leaves, bisexual and actinomorphic flowers with free petals and free anthers, a superior ovary with a style, and drupaceous fruits. WGD analyses provide strong evidence for 33 WGDs in asterids and one in Berberidopsidales, including four supra-familial and seven familial/sub-familial WGDs. Our results advance the understanding of asterid phylogeny and provide numerous novel evolutionary insights into their diversification and morphological evolution.

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Characterization of C₃–C₄ intermediate species in the genus Heliotropium L. (Boraginaceae): anatomy, ultrastructure and enzyme activity

Muhaidat

Sage

Frohlich

et al. 2011

Plant Cell & Environment

126

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Photosynthetic pathway characteristics were studied in nine species of Heliotropium (sensu lato, including Euploca), using assessments of leaf anatomy and ultrastructure, activities of PEP carboxylase and C4 acid decarboxylases, and immunolocalization of ribulose 1·5-bisphosphate carboxylase/oxygenase (Rubisco) and the P-subunit of glycine decarboxylase (GDC). Heliotropium europaeum, Heliotropium calcicola and Heliotropium tenellum are C3 plants, while Heliotropium texanum and Heliotropium polyphyllum are C4 species. Heliotropium procumbens and Heliotropium karwinskyi are functionally C3, but exhibit 'proto-Kranz' anatomy where bundle sheath (BS) cells are enlarged and mitochondria primarily occur along the centripetal (inner) wall of the BS cells; GDC is present throughout the leaf. Heliotropium convolvulaceum and Heliotropium greggii are C3-C4 intermediates, with Kranzlike enlargement of the BS cells, localization of mitochondria along the inner BS wall and a loss of GDC in the mesophyll (M) tissue. These C3-C4 species of Heliotropium probably shuttle photorespiratory glycine from the M to the BS tissue for decarboxylation. Heliotropium represents an important new model for studying C4 evolution.Where existing models such as Flaveria emphasize diversification of C3-C4 intermediates, Heliotropium has numerous C3 species expressing proto-Kranz traits that could represent a critical initial phase in the evolutionary origin of C4 photosynthesis.

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