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  1. Article ; Online: Asymmetric Evolution of Protein Domains in the Leucine-Rich Repeat Receptor-Like Kinase Family of Plant Signaling Proteins.

    Man, Jarrett / Harrington, T A / Lally, Kyra / Bartlett, Madelaine E

    Molecular biology and evolution

    2023  Volume 40, Issue 10

    Abstract: The coding sequences of developmental genes are expected to be deeply conserved, with cis-regulatory change driving the modulation of gene function. In contrast, proteins with roles in defense are expected to evolve rapidly, in molecular arms races with ... ...

    Abstract The coding sequences of developmental genes are expected to be deeply conserved, with cis-regulatory change driving the modulation of gene function. In contrast, proteins with roles in defense are expected to evolve rapidly, in molecular arms races with pathogens. However, some gene families include both developmental and defense genes. In these families, does the tempo and mode of evolution differ between genes with divergent functions, despite shared ancestry and structure? The leucine-rich repeat receptor-like kinase (LRR-RLKs) protein family includes members with roles in plant development and defense, thus providing an ideal system for answering this question. LRR-RLKs are receptors that traverse plasma membranes. LRR domains bind extracellular ligands; RLK domains initiate intracellular signaling cascades in response to ligand binding. In LRR-RLKs with roles in defense, LRR domains evolve faster than RLK domains. To determine whether this asymmetry extends to LRR-RLKs that function primarily in development, we assessed evolutionary rates and tested for selection acting on 11 subfamilies of LRR-RLKs, using deeply sampled protein trees. To assess functional evolution, we performed heterologous complementation assays in Arabidopsis thaliana (Arabidopsis). We found that the LRR domains of all tested LRR-RLK proteins evolved faster than their cognate RLK domains. All tested subfamilies of LRR-RLKs had strikingly similar patterns of molecular evolution, despite divergent functions. Heterologous transformation experiments revealed that multiple mechanisms likely contribute to the evolution of LRR-RLK function, including escape from adaptive conflict. Our results indicate specific and distinct evolutionary pressures acting on LRR versus RLK domains, despite diverse organismal roles for LRR-RLK proteins.
    MeSH term(s) Plant Proteins/genetics ; Plant Proteins/metabolism ; Leucine/genetics ; Protein Domains ; Protein Kinases/genetics ; Arabidopsis/genetics ; Arabidopsis/metabolism ; Protein-Tyrosine Kinases/genetics ; Evolution, Molecular ; Phylogeny
    Chemical Substances Plant Proteins ; Leucine (GMW67QNF9C) ; Protein Kinases (EC 2.7.-) ; Protein-Tyrosine Kinases (EC 2.7.10.1)
    Language English
    Publishing date 2023-10-31
    Publishing country United States
    Document type Journal Article
    ZDB-ID 998579-7
    ISSN 1537-1719 ; 0737-4038
    ISSN (online) 1537-1719
    ISSN 0737-4038
    DOI 10.1093/molbev/msad220
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    Zs.A 2137: Show issues Location:
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  2. Article ; Online: Structural evolution drives diversification of the large LRR-RLK gene family.

    Man, Jarrett / Gallagher, Joseph P / Bartlett, Madelaine

    The New phytologist

    2020  Volume 226, Issue 5, Page(s) 1492–1505

    Abstract: Cells are continuously exposed to chemical signals that they must discriminate between and respond to appropriately. In embryophytes, the leucine-rich repeat receptor-like kinases (LRR-RLKs) are signal receptors critical in development and defense. LRR- ... ...

    Abstract ●Cells are continuously exposed to chemical signals that they must discriminate between and respond to appropriately. In embryophytes, the leucine-rich repeat receptor-like kinases (LRR-RLKs) are signal receptors critical in development and defense. LRR-RLKs have diversified to hundreds of genes in many plant genomes. Although intensively studied, a well-resolved LRR-RLK gene tree has remained elusive. ●To resolve the LRR-RLK gene tree, we developed an improved gene discovery method based on iterative hidden Markov model searching and phylogenetic inference. We used this method to infer complete gene trees for each of the LRR-RLK subclades and reconstructed the deepest nodes of the full gene family. ●We discovered that the LRR-RLK gene family is even larger than previously thought, and that protein domain gains and losses are prevalent. These structural modifications, some of which likely predate embryophyte diversification, led to misclassification of some LRR-RLK variants as members of other gene families. Our work corrects this misclassification. ●Our results reveal ongoing structural evolution generating novel LRR-RLK genes. These new genes are raw material for the diversification of signaling in development and defense. Our methods also enable phylogenetic reconstruction in any large gene family.
    MeSH term(s) Evolution, Molecular ; Genome, Plant ; Phylogeny ; Protein Domains
    Language English
    Publishing date 2020-02-29
    Publishing country England
    Document type Journal Article ; Research Support, Non-U.S. Gov't ; Research Support, U.S. Gov't, Non-P.H.S.
    ZDB-ID 208885-x
    ISSN 1469-8137 ; 0028-646X
    ISSN (online) 1469-8137
    ISSN 0028-646X
    DOI 10.1111/nph.16455
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  3. Article ; Online: The Power and Perils of De Novo Domestication Using Genome Editing.

    Bartlett, Madelaine E / Moyers, Brook T / Man, Jarrett / Subramaniam, Banu / Makunga, Nokwanda P

    Annual review of plant biology

    2022  Volume 74, Page(s) 727–750

    Abstract: There is intense interest in using genome editing technologies to domesticate wild plants, or accelerate the improvement of weakly domesticated crops, in de novo domestication. Here, we discuss promising genetic strategies, with a focus on plant ... ...

    Abstract There is intense interest in using genome editing technologies to domesticate wild plants, or accelerate the improvement of weakly domesticated crops, in de novo domestication. Here, we discuss promising genetic strategies, with a focus on plant development. Importantly, genome editing releases us from dependence on random mutagenesis or intraspecific diversity, allowing us to draw solutions more broadly from diversity. However, sparse understanding of the complex genetics of diversity limits innovation. Beyond genetics, we urge the ethical use of indigenous knowledge, indigenous plants, and ethnobotany. De novo domestication still requires conventional breeding by phenotypic selection, especially in the development of crops for diverse environments and cultures. Indeed, uniting genome editing with selective breeding could facilitate faster and better outcomes than either technology alone. Domestication is complex and incompletely understood, involving changes to many aspects of plant biology and human culture. Success in de novo domestication requires careful attention to history and collaboration across traditional boundaries.
    MeSH term(s) Humans ; Domestication ; Gene Editing ; Plant Breeding ; Crops, Agricultural/genetics ; Ethnobotany
    Language English
    Publishing date 2022-11-22
    Publishing country United States
    Document type Journal Article ; Review ; Research Support, U.S. Gov't, Non-P.H.S. ; Research Support, Non-U.S. Gov't
    ZDB-ID 2098209-4
    ISSN 1545-2123 ; 1543-5008
    ISSN (online) 1545-2123
    ISSN 1543-5008
    DOI 10.1146/annurev-arplant-053122-030653
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  4. Article ; Online: GRASSY TILLERS1

    Gallagher, Joseph P / Man, Jarrett / Chiaramida, Adriana / Rozza, Isabella K / Patterson, Erin L / Powell, Morgan M / Schrager-Lavelle, Amanda / Multani, Dilbag S / Meeley, Robert B / Bartlett, Madelaine E

    Proceedings of the National Academy of Sciences of the United States of America

    2023  Volume 120, Issue 51, Page(s) e2311961120

    Abstract: Crop engineering and de novo domestication using gene editing are new frontiers in agriculture. However, outside of well-studied crops and model systems, prioritizing engineering targets remains challenging. Evolution can guide us, revealing genes with ... ...

    Abstract Crop engineering and de novo domestication using gene editing are new frontiers in agriculture. However, outside of well-studied crops and model systems, prioritizing engineering targets remains challenging. Evolution can guide us, revealing genes with deeply conserved roles that have repeatedly been selected in the evolution of plant form. Homologs of the transcription factor genes
    MeSH term(s) Arabidopsis/genetics ; Arabidopsis/metabolism ; Phenotype ; Flowers/metabolism ; Plant Proteins/genetics ; Plant Proteins/metabolism ; Gene Expression Regulation, Plant
    Chemical Substances Plant Proteins
    Language English
    Publishing date 2023-12-14
    Publishing country United States
    Document type Journal Article
    ZDB-ID 209104-5
    ISSN 1091-6490 ; 0027-8424
    ISSN (online) 1091-6490
    ISSN 0027-8424
    DOI 10.1073/pnas.2311961120
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    In stock of ZB MED Cologne/Königswinter

    Zs.A 1148: Show issues Location:
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  5. Article ; Online: Evolutionary Variation in MADS Box Dimerization Affects Floral Development and Protein Abundance in Maize.

    Abraham-Juárez, María Jazmín / Schrager-Lavelle, Amanda / Man, Jarrett / Whipple, Clinton / Handakumbura, Pubudu / Babbitt, Courtney / Bartlett, Madelaine

    The Plant cell

    2020  Volume 32, Issue 11, Page(s) 3408–3424

    Abstract: Interactions between MADS box transcription factors are critical in the regulation of floral development, and shifting MADS box protein-protein interactions are predicted to have influenced floral evolution. However, precisely how evolutionary variation ... ...

    Abstract Interactions between MADS box transcription factors are critical in the regulation of floral development, and shifting MADS box protein-protein interactions are predicted to have influenced floral evolution. However, precisely how evolutionary variation in protein-protein interactions affects MADS box protein function remains unknown. To assess the impact of changing MADS box protein-protein interactions on transcription factor function, we turned to the grasses, where interactions between B-class MADS box proteins vary. We tested the functional consequences of this evolutionary variability using maize (
    MeSH term(s) Chromatin Assembly and Disassembly ; Evolution, Molecular ; Flowers/genetics ; Flowers/growth & development ; Gene Expression Regulation, Plant ; Genetic Pleiotropy ; MADS Domain Proteins/genetics ; MADS Domain Proteins/metabolism ; Mutation ; Plant Proteins/genetics ; Plant Proteins/metabolism ; Plants, Genetically Modified ; Protein Multimerization ; Protein Processing, Post-Translational ; Ubiquitination ; Zea mays/genetics ; Zea mays/growth & development ; Zea mays/metabolism
    Chemical Substances MADS Domain Proteins ; Plant Proteins
    Language English
    Publishing date 2020-09-01
    Publishing country England
    Document type Journal Article ; Research Support, Non-U.S. Gov't ; Research Support, U.S. Gov't, Non-P.H.S.
    ZDB-ID 623171-8
    ISSN 1532-298X ; 1040-4651
    ISSN (online) 1532-298X
    ISSN 1040-4651
    DOI 10.1105/tpc.20.00300
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    In stock of ZB MED Bonn / Germany

    Z 4952: Show issues

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  6. Article ; Online: Engineering Quantitative Trait Variation for Crop Improvement by Genome Editing.

    Rodríguez-Leal, Daniel / Lemmon, Zachary H / Man, Jarrett / Bartlett, Madelaine E / Lippman, Zachary B

    Cell

    2017  Volume 171, Issue 2, Page(s) 470–480.e8

    Abstract: Major advances in crop yields are needed in the coming decades. However, plant breeding is currently limited by incremental improvements in quantitative traits that often rely on laborious selection of rare naturally occurring mutations in gene- ... ...

    Abstract Major advances in crop yields are needed in the coming decades. However, plant breeding is currently limited by incremental improvements in quantitative traits that often rely on laborious selection of rare naturally occurring mutations in gene-regulatory regions. Here, we demonstrate that CRISPR/Cas9 genome editing of promoters generates diverse cis-regulatory alleles that provide beneficial quantitative variation for breeding. We devised a simple genetic scheme, which exploits trans-generational heritability of Cas9 activity in heterozygous loss-of-function mutant backgrounds, to rapidly evaluate the phenotypic impact of numerous promoter variants for genes regulating three major productivity traits in tomato: fruit size, inflorescence branching, and plant architecture. Our approach allows immediate selection and fixation of novel alleles in transgene-free plants and fine manipulation of yield components. Beyond a platform to enhance variation for diverse agricultural traits, our findings provide a foundation for dissecting complex relationships between gene-regulatory changes and control of quantitative traits.
    MeSH term(s) CRISPR-Cas Systems ; Crops, Agricultural/genetics ; Gene Editing ; Genome, Plant ; Promoter Regions, Genetic ; Quantitative Trait Loci
    Language English
    Publishing date 2017-10-05
    Publishing country United States
    Document type Journal Article
    ZDB-ID 187009-9
    ISSN 1097-4172 ; 0092-8674
    ISSN (online) 1097-4172
    ISSN 0092-8674
    DOI 10.1016/j.cell.2017.08.030
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    In stock of ZB MED Cologne/Königswinter

    Zs.A 1167: Show issues Location:
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    Zs.MG 58: Show issues

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  7. Article ; Online: Evolution of buffering in a genetic circuit controlling plant stem cell proliferation.

    Rodriguez-Leal, Daniel / Xu, Cao / Kwon, Choon-Tak / Soyars, Cara / Demesa-Arevalo, Edgar / Man, Jarrett / Liu, Lei / Lemmon, Zachary H / Jones, Daniel S / Van Eck, Joyce / Jackson, David P / Bartlett, Madelaine E / Nimchuk, Zachary L / Lippman, Zachary B

    Nature genetics

    2019  Volume 51, Issue 5, Page(s) 786–792

    Abstract: Precise control of plant stem cell proliferation is necessary for the continuous and reproducible development of plant ... ...

    Abstract Precise control of plant stem cell proliferation is necessary for the continuous and reproducible development of plant organs
    MeSH term(s) Arabidopsis/cytology ; Arabidopsis/genetics ; Arabidopsis/growth & development ; Arabidopsis Proteins/genetics ; Cell Proliferation/genetics ; Evolution, Molecular ; Gene Expression Regulation, Plant ; Gene Regulatory Networks ; Genes, Plant ; Intercellular Signaling Peptides and Proteins/genetics ; Ligands ; Lycopersicon esculentum/cytology ; Lycopersicon esculentum/genetics ; Lycopersicon esculentum/growth & development ; Meristem/cytology ; Meristem/genetics ; Models, Genetic ; Mutation ; Plant Development/genetics ; Plants, Genetically Modified ; Protein-Serine-Threonine Kinases/genetics ; Signal Transduction/genetics ; Stem Cells/cytology ; Zea mays/cytology ; Zea mays/genetics ; Zea mays/growth & development
    Chemical Substances AT2G27250 protein, Arabidopsis ; Arabidopsis Proteins ; Intercellular Signaling Peptides and Proteins ; Ligands ; CLV1 protein, Arabidopsis (EC 2.7.11.1) ; Protein-Serine-Threonine Kinases (EC 2.7.11.1)
    Language English
    Publishing date 2019-04-15
    Publishing country United States
    Document type Journal Article ; Research Support, N.I.H., Extramural ; Research Support, Non-U.S. Gov't ; Research Support, U.S. Gov't, Non-P.H.S.
    ZDB-ID 1108734-1
    ISSN 1546-1718 ; 1061-4036
    ISSN (online) 1546-1718
    ISSN 1061-4036
    DOI 10.1038/s41588-019-0389-8
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