Your search keyword '"Davies Km"' showing total 5 results

1. The evolution of flavonoid biosynthesis.

Author

Davies KM, Andre CM, Kulshrestha S, Zhou Y, Schwinn KE, Albert NW, Chagné D, van Klink JW, Landi M, and Bowman JL

Subjects

Evolution, Molecular, Biosynthetic Pathways, Embryophyta genetics, Plants genetics, Plants metabolism, Flavonoids biosynthesis

Abstract

The flavonoid pathway is characteristic of land plants and a central biosynthetic component enabling life in a terrestrial environment. Flavonoids provide tolerance to both abiotic and biotic stresses and facilitate beneficial relationships, such as signalling to symbiont microorganisms, or attracting pollinators and seed dispersal agents. The biosynthetic pathway shows great diversity across species, resulting principally from repeated biosynthetic gene duplication and neofunctionalization events during evolution. Such events may reflect a selection for new flavonoid structures with novel functions that enable occupancy of varied ecological niches. However, the biochemical and genetic diversity of the pathway also likely resulted from evolution along parallel trends across land plant lineages, producing variant compounds with similar biological functions. Analyses of the wide range of whole-plant genome sequences now available, particularly for archegoniate plants, have enabled proposals on which genes were ancestral to land plants and which arose within the land plant lineages. In this review, we discuss the emerging proposals for how the flavonoid pathway may have evolved and diversified. This article is part of the theme issue 'The evolution of plant metabolism'.

Published

2024

2. The auronidin flavonoid pigments of the liverwort Marchantia polymorpha form polymers that modify cell wall properties.

Author

Jibran R, Hill SJ, Lampugnani ER, Hao P, Doblin MS, Bacic A, Vaidya AA, O'Donoghue EM, McGhie TK, Albert NW, Zhou Y, Raymond LG, Schwinn KE, Jordan BR, Bowman JL, Davies KM, and Brummell DA

Subjects

Pigments, Biological metabolism, Cell Wall metabolism, Cell Wall chemistry, Marchantia genetics, Marchantia metabolism, Flavonoids metabolism, Plants, Genetically Modified

Abstract

Plant adaptation from aquatic to terrestrial environments required modifications to cell wall structure and function to provide tolerance to new abiotic and biotic stressors. Here, we investigate the nature and function of red auronidin pigment accumulation in the cell wall of the liverwort Marchantia polymorpha. Transgenic plants with auronidin production either constitutive or absent were analysed for their cell wall properties, including fractionation of polysaccharide and phenolic components. While small amounts of auronidin and other flavonoids were loosely associated with the cell wall, the majority of the pigments were tightly associated, similar to what is observed in angiosperms for polyphenolics such as lignin. No evidence of covalent binding to a polysaccharide component was found: we propose auronidin is present in the wall as a physically entrapped large molecular weight polymer. The results suggested auronidin is a dual function molecule that can both screen excess light and increase wall strength, hydrophobicity and resistance to enzymatic degradation by pathogens. Thus, liverworts have expanded the core phenylpropanoid toolkit that was present in the ancestor of all land plants, to deliver a lineage-specific solution to some of the environmental stresses faced from a terrestrial lifestyle., (© 2024 The Author(s). The Plant Journal published by Society for Experimental Biology and John Wiley & Sons Ltd.)

Published

2024

3. Painted flowers: Eluta generates pigment patterning in Antirrhinum.

Author

Moss SMA, Zhou Y, Butelli E, Waite CN, Yeh SM, Cordiner SB, Harris NN, Copsey L, Schwinn KE, Davies KM, Hudson A, Martin C, and Albert NW

Subjects

Plants, Genetically Modified, Genes, Plant, Nicotiana genetics, Promoter Regions, Genetic genetics, DNA Transposable Elements genetics, Alleles, Antirrhinum genetics, Flowers genetics, Flowers physiology, Pigmentation genetics, Plant Proteins genetics, Plant Proteins metabolism, Gene Expression Regulation, Plant, Anthocyanins metabolism, Phenotype

Abstract

In the early 1900s, Erwin Baur established Antirrhinum majus as a model system, identifying and characterising numerous flower colour variants. This included Picturatum/Eluta, which restricts the accumulation of magenta anthocyanin pigments, forming bullseye markings on the flower face. We identified the gene underlying the Eluta locus by transposon-tagging, using an Antirrhinum line that spontaneously lost the nonsuppressive el phenotype. A candidate MYB repressor gene at this locus contained a CACTA transposable element. We subsequently identified plants where this element excised, reverting to a suppressive Eluta phenotype. El alleles inhibit expression of anthocyanin biosynthetic genes, confirming it to be a regulatory locus. The modes of action of Eluta were investigated by generating stable transgenic tobacco lines, biolistic transformation of Antirrhinum petals and promoter activation/repression assays. Eluta competes with MYB activators for promoter cis-elements, and also by titrating essential cofactors (bHLH proteins) to reduce transcription of target genes. Eluta restricts the pigmentation established by the R2R3-MYB factors, Rosea and Venosa, with the greatest repression on those parts of the petals where Eluta is most highly expressed. Baur questioned the origin of heredity units determining flower colour variation in cultivated A. majus. Our findings support introgression from wild species into cultivated varieties., (© 2024 The Authors. New Phytologist © 2024 New Phytologist Foundation.)

Published

2024

4. DWARF27 and CAROTENOID CLEAVAGE DIOXYGENASE 7 genes regulate release, germination and growth of gemma in Marchantia polymorpha .

Author

Jibran R, Tahir J, Andre CM, Janssen BJ, Drummond RSM, Albert NW, Zhou Y, Davies KM, and Snowden KC

Abstract

Strigolactones (SLs), a class of carotenoid-derived hormones, play a crucial role in flowering plants by regulating underground communication with symbiotic arbuscular mycorrhizal fungi (AM) and controlling shoot and root architecture. While the functions of core SL genes have been characterized in many plants, their roles in non-tracheophyte plants like liverworts require further investigation. In this study, we employed the model liverwort species Marchantia polymorpha , which lacks detectable SL production and orthologs of key SL biosynthetic genes, including CAROTENOID CLEAVAGE DIOXYGENASE 8 ( CCD8 ) and MORE AXILLARY GROWTH 1 ( MAX1 ). However, it retains some SL pathway components, including DWARF27 ( D27 ) and CCD7 . To help elucidate the function of these remaining components in M. polymorpha , knockout mutants were generated for MpD27-1 , MpD27-2 and MpCCD7 . Phenotypic comparisons of these mutants with the wild-type control revealed a novel role for these genes in regulating the release of gemmae from the gemma cup and the germination and growth of gemmae in the dark. Mpd27-1 , Mpd27-2 , and Mpccd7 mutants showed lower transcript abundance of genes involved in photosynthesis, such as EARLY LIGHT INDUCED ( ELI ), and stress responses such as LATE EMBRYOGENESIS ABUNDANT ( LEA ) but exhibited higher transcript levels of ETHYLENE RESPONSE FACTORS ( ERFs ) and SL and carotenoid related genes, such as TERPENE SYNTHASE ( TS ), CCD7 and LECITHIN-RETINAL ACYL TRANSFERASE (LRAT) . Furthermore, the mutants of M. polymorpha in the SL pathway exhibited increased contents of carotenoid. This unveils a previously unrecognized role for MpD27-1, MpD27-2 and MpCCD7 in controlling release, germination, and growth of gemmae in response to varying light conditions. These discoveries enhance our comprehension of the regulatory functions of SL biosynthesis genes in non-flowering plants., Competing Interests: Authors RJ, JT, CA, BJ, RD, NA, YZ, KD and KS were employed by the company The New Zealand Institute for Plant and Food Research Limited. The author(s) declared that they were an editorial board member of Frontiers, at the time of submission. This had no impact on the peer review process and the final decision., (Copyright © 2024 Jibran, Tahir, Andre, Janssen, Drummond, Albert, Zhou, Davies and Snowden.)

Published

2024

5. A phosphatase gene is linked to nectar dihydroxyacetone accumulation in mānuka (Leptospermum scoparium).

Author

Grierson ERP, Thrimawithana AH, van Klink JW, Lewis DH, Carvajal I, Shiller J, Miller P, Deroles SC, Clearwater MJ, Davies KM, Chagné D, and Schwinn KE

Subjects

Phosphoric Monoester Hydrolases genetics, Phosphoric Monoester Hydrolases metabolism, Genes, Plant, Genotype, Chromosome Mapping, Chromosomes, Plant genetics, Plant Proteins genetics, Plant Proteins metabolism, Quantitative Trait Loci genetics, Plant Nectar metabolism, Dihydroxyacetone metabolism, Gene Expression Regulation, Plant, Leptospermum metabolism

Abstract

Floral nectar composition beyond common sugars shows great diversity but contributing genetic factors are generally unknown. Mānuka (Leptospermum scoparium) is renowned for the antimicrobial compound methylglyoxal in its derived honey, which originates from the precursor, dihydroxyacetone (DHA), accumulating in the nectar. Although this nectar trait is highly variable, genetic contribution to the trait is unclear. Therefore, we investigated key gene(s) and genomic regions underpinning this trait. We used RNAseq analysis to identify nectary-associated genes differentially expressed between high and low nectar DHA genotypes. We also used a mānuka high-density linkage map and quantitative trait loci (QTL) mapping population, supported by an improved genome assembly, to reveal genetic regions associated with nectar DHA content. Expression and QTL analyses both pointed to the involvement of a phosphatase gene, LsSgpp2. The expression pattern of LsSgpp2 correlated with nectar DHA accumulation, and it co-located with a QTL on chromosome 4. The identification of three QTLs, some of the first reported for a plant nectar trait, indicates polygenic control of DHA content. We have established plant genetics as a key influence on DHA accumulation. The data suggest the hypothesis of LsSGPP2 releasing DHA from DHA-phosphate and variability in LsSgpp2 gene expression contributing to the trait variability., (© 2024 The Authors. New Phytologist © 2024 New Phytologist Foundation.)

Published

2024