Revel S.M. Drummond scite author profile

Strigolactones are a recently discovered class of plant hormone involved in branching, leaf senescence, root development, and plant-microbe interactions. They are carotenoid-derived lactones, synthesized in the roots and transported acropetally to modulate axillary bud outgrowth (i.e., branching). However, a receptor for strigolactones has not been identified. We have identified the DAD2 gene from petunia, an ortholog of the rice and Arabidopsis D14 genes, and present evidence for its roles in strigolactone perception and signaling. DAD2 acts in the strigolactone pathway, and the dad2 mutant is insensitive to the strigolactone analog GR24. The crystal structure of DAD2 reveals an α/β hydrolase fold containing a canonical catalytic triad with a large internal cavity capable of accommodating strigolactones. In the presence of GR24 DAD2 interacts with PhMAX2A, a central component of strigolactone signaling, in a GR24 concentration-dependent manner. DAD2 can hydrolyze GR24, with mutants of the catalytic triad abolishing both this activity and the ability of DAD2 to interact with PhMAX2A. The hydrolysis products can neither stimulate the protein-protein interaction nor modulate branching. These observations suggest that DAD2 acts to bind the mobile strigolactone signal and then interacts with PhMAX2A during catalysis to initiate an SCF-mediated signal transduction pathway.

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A manually annotated Actinidia chinensis var. chinensis (kiwifruit) genome highlights the challenges associated with draft genomes and gene prediction in plants

Pilkington

et al. 2018

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BackgroundMost published genome sequences are drafts, and most are dominated by computational gene prediction. Draft genomes typically incorporate considerable sequence data that are not assigned to chromosomes, and predicted genes without quality confidence measures. The current Actinidia chinensis (kiwifruit) ‘Hongyang’ draft genome has 164 Mb of sequences unassigned to pseudo-chromosomes, and omissions have been identified in the gene models.ResultsA second genome of an A. chinensis (genotype Red5) was fully sequenced. This new sequence resulted in a 554.0 Mb assembly with all but 6 Mb assigned to pseudo-chromosomes. Pseudo-chromosomal comparisons showed a considerable number of translocation events have occurred following a whole genome duplication (WGD) event some consistent with centromeric Robertsonian-like translocations. RNA sequencing data from 12 tissues and ab initio analysis informed a genome-wide manual annotation, using the WebApollo tool. In total, 33,044 gene loci represented by 33,123 isoforms were identified, named and tagged for quality of evidential support. Of these 3114 (9.4%) were identical to a protein within ‘Hongyang’ The Kiwifruit Information Resource (KIR v2). Some proportion of the differences will be varietal polymorphisms. However, as most computationally predicted Red5 models required manual re-annotation this proportion is expected to be small. The quality of the new gene models was tested by fully sequencing 550 cloned ‘Hort16A’ cDNAs and comparing with the predicted protein models for Red5 and both the original ‘Hongyang’ assembly and the revised annotation from KIR v2. Only 48.9% and 63.5% of the cDNAs had a match with 90% identity or better to the original and revised ‘Hongyang’ annotation, respectively, compared with 90.9% to the Red5 models.ConclusionsOur study highlights the need to take a cautious approach to draft genomes and computationally predicted genes. Our use of the manual annotation tool WebApollo facilitated manual checking and correction of gene models enabling improvement of computational prediction. This utility was especially relevant for certain types of gene families such as the EXPANSIN like genes. Finally, this high quality gene set will supply the kiwifruit and general plant community with a new tool for genomics and other comparative analysis.Electronic supplementary materialThe online version of this article (10.1186/s12864-018-4656-3) contains supplementary material, which is available to authorized users.

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A Novel Family of Magnesium Transport Genes in Arabidopsis

et al. 2001

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Magnesium (Mg 2 ؉ ) is the most abundant divalent cation in plant cells and plays a critical role in many physiological processes. We describe the identification of a 10-member Arabidopsis gene family ( AtMGT ) encoding putative Mg 2 ؉ transport proteins. Most members of the AtMGT family are expressed in a range of Arabidopsis tissues. One member of this family, AtMGT1 , functionally complemented a bacterial mutant lacking Mg 2 ؉ transport capability. A second member, AtMGT10 , complemented a yeast mutant defective in Mg 2 ؉ uptake and increased the cellular Mg 2 ؉ content of starved cells threefold during a 60-min uptake period. 63 Ni tracer studies in bacteria showed that AtMGT1 has highest affinity for Mg 2 ؉ but may also be capable of transporting several other divalent cations, including Ni 2 ؉ , Co 2 ؉ , Fe 2 ؉ , Mn 2 ؉ , and Cu 2 ؉ . However, the concentrations required for transport of these other cations are beyond normal physiological ranges. Both AtMGT1 and AtMGT10 are highly sensitive to Al 3 ؉ inhibition, providing potential molecular targets for Al 3 ؉ toxicity in plants. Using green fluorescence protein as a reporter, we localized AtMGT1 protein to the plasma membrane in Arabidopsis plants. We suggest that the AtMGT gene family encodes a Mg 2 ؉ transport system in higher plants. . Article, publication date, and citation information can be found at www.plantcell.org/cgi/

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Petunia hybrida CAROTENOID CLEAVAGE DIOXYGENASE7 Is Involved in the Production of Negative and Positive Branching Signals in Petunia

et al. 2009

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One of the key factors that defines plant form is the regulation of when and where branches develop. The diversity of form observed in nature results, in part, from variation in the regulation of branching between species. Two CAROTENOID CLEAVAGE DIOXYGENASE (CCD) genes, CCD7 and CCD8, are required for the production of a branch-suppressing plant hormone. Here, we report that the decreased apical dominance3 (dad3) mutant of petunia (Petunia hybrida) results from the mutation of the PhCCD7 gene and has a less severe branching phenotype than mutation of PhCCD8 (dad1). An analysis of the expression of this gene in wild-type, mutant, and grafted petunia suggests that in petunia, CCD7 and CCD8 are coordinately regulated. In contrast to observations in Arabidopsis (Arabidopsis thaliana), ccd7ccd8 double mutants in petunia show an additive phenotype. An analysis using dad3 or dad1 mutant scions grafted to wild-type rootstocks showed that when these plants produce adventitious mutant roots, branching is increased above that seen in plants where the mutant roots are removed. The results presented here indicate that mutation of either CCD7 or CCD8 in petunia results in both the loss of an inhibitor of branching and an increase in a promoter of branching.

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Identification and Validation of Reference Genes for Normalization of Transcripts from Virus-InfectedArabidopsis thaliana

Lilly¹,

Drummond²,

Pearson³

et al. 2011

MPMI

101

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Real-time quantitative polymerase chain reaction (qPCR) of complementary DNA is now a standard method for studies of gene expression. However, qPCR can identify genuine variation only when transcript quantities are accurately normalized to an appropriate reference. To identify the most reliable reference genes for transcript quantification by qPCR, we describe a systematic evaluation of candidate reference genes of Arabidopsis thaliana ecotype Columbia-0 (Col-0). Twelve genes were selected for transcript stability studies by qPCR of complementary DNA prepared from Arabidopsis leaf tissue infected with one of five plant viruses (Cauliflower mosaic virus, Tobacco mosaic virus, Tomato spotted wilt virus, Turnip mosaic virus, and Turnip yellow mosaic virus). The F-box family protein, elongation factor 1-α, sand family protein, and protodermal factor 2 gene transcripts showed the most stable accumulation, whereas a traditionally used reference gene, Actin8, showed the least stable accumulation as measured by the geNorm algorithm. The data furnish plant virologists with reference genes for normalization of qPCR-derived gene expression in virus-infected Arabidopsis and will be beneficial to the selection and design of primers targeting orthologous genes in other plant species.

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Regulation of axillary shoot development

Janssen

Drummond

Snowden

2014

Current Opinion in Plant Biology

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Mutagenesis of kiwifruit CENTRORADIALIS‐like genes transforms a climbing woody perennial with long juvenility and axillary flowering into a compact plant with rapid terminal flowering

Varkonyi‐Gasic

Wang

Voogd

et al. 2018

Plant Biotechnology Journal

107

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Summary Annualization of woody perennials has the potential to revolutionize the breeding and production of fruit crops and rapidly improve horticultural species. Kiwifruit ( Actinidia chinensis ) is a recently domesticated fruit crop with a short history of breeding and tremendous potential for improvement. Previously, multiple kiwifruit CENTRORADIALIS ( CEN )‐like genes have been identified as potential repressors of flowering. In this study, CRISPR /Cas9‐ mediated manipulation enabled functional analysis of kiwifruit CEN ‐like genes Ac CEN 4 and Ac CEN . Mutation of these genes transformed a climbing woody perennial, which develops axillary inflorescences after many years of juvenility, into a compact plant with rapid terminal flower and fruit development. The number of affected genes and alleles and severity of detected mutations correlated with the precocity and change in plant stature, suggesting that a bi‐allelic mutation of either Ac CEN 4 or Ac CEN may be sufficient for early flowering, whereas mutations affecting both genes further contributed to precocity and enhanced the compact growth habit. CRISPR /Cas9‐mediated mutagenesis of Ac CEN 4 and Ac CEN may be a valuable means to engineer Actinidia amenable for accelerated breeding, indoor farming and cultivation as an annual crop.

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A putative magnesium transporter AtMRS2-11 is localized to the plant chloroplast envelope membrane system

Drummond

Tutone

et al. 2006

Plant Science

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