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New Phytologist
@NewPhyt
Publishing, promoting and supporting rigorous plant science and its applications since 1902. Owned by the New Phytologist Foundation (newphytologist.org)
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    New Phytologist
    @NewPhyt
    Dec 19, 2021
    The Angiosperm Terrestrial Revolution and the origins of modern biodiversity @hsauquet_rbgsyd @RadioGondwana #TansleyReview nph.onlinelibrary.wiley.com/doi/10.1111/npโ€ฆ
    Evolution of hyperdiverse terrestrial life.
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    New Phytologist
    @NewPhyt
    Jan 23, 2022
    'When the notion of starting a new botanical journal in this country was mooted, we were told by a certain distinguished botanist that it was not enough to shew there was room for a new periodical, necessity for its existence must be established.' Happy 120th birthday to us! ๐ŸŽ‚
    Image of the first page of the first issue of New Phytologist
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    New Phytologist
    @NewPhyt
    Dec 25, 2017
    Season's greetings from all at New Phytologist!
    GIF
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    New Phytologist
    @NewPhyt
    Feb 4, 2024
    #TansleyReview The #mycorrhizal symbiosis: research frontiers in genomics, ecology, and agricultural application Martin & van der Heijden @fmartin1954 @vandeHeijdenLab ๐Ÿ“– ow.ly/t9V950QwO2B
    View of the soil mycorrhizal community in a hypothetical forest dominated by oak species associated with different types of mycorrhizal fungi that form separate underground networks (MN) that may possibly be used to transport amino acids, carbohydrates, fatty acids, signaling microRNAs or peptides and hormones. Illustration courtesy of Florian Gadenne.
    64K
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    New Phytologist
    @NewPhyt
    Sep 24, 2023
    Microbe-dependent and independent nitrogen and phosphate acquisition and regulation in plants Zhao et al. #TansleyReview ๐Ÿ“– ow.ly/4fXC50PNO3i
    Direct and indirect uptake pathways for plants to obtain nitrogen and phosphorus.
    35K
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    New Phytologist
    @NewPhyt
    Sep 9, 2023
    Genome evolution in plants and the origins of innovation James W. Clark @sometimesferns #TansleyInsight ๐Ÿ“– ow.ly/Fwz450PHoLY
    Genomic and phenotypic innovation across land plants (image of Coleochaetophyceae provided with permission by Philip Donoghue).
    26K
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    New Phytologist
    @NewPhyt
    May 28, 2022
    Crafting the plant root metabolome for improved microbe-assisted stress resilience #TansleyInsight nph.onlinelibrary.wiley.com/doi/10.1111/npโ€ฆ
    Overview of the stressโ€“metabolomeโ€“microbiota (SMM) sequence in plant roots. Plants can sense various abiotic and biotic stress signals, which induce the increased production of corresponding secondary metabolites.
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    New Phytologist
    @NewPhyt
    Feb 6, 2022
    The Angiosperm Terrestrial Revolution and the origins of modern biodiversity nph.onlinelibrary.wiley.com/doi/10.1111/npโ€ฆ #TansleyReview by Michael J. Benton, @RadioGondwana and @hsauquet_rbgsyd bristol.ac.uk/news/2021/noveโ€ฆ
    Evolution of hyperdiverse terrestrial life. Many of the most diverse organisms today, including angiosperms, spiders, insects (bugs, beetles, bees and wasps, butterflies and moths, flies), and vertebrates (lizards, birds, mammals) trace their origins deep into the Mesozoic, but they showed their major diversifications in the Cretaceous and Paleogene, apparently fuelled by the Angiosperm Terrestrial Revolution (ATR).
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    New Phytologist
    @NewPhyt
    Feb 26, 2022
    Crafting the plant root metabolome for improved microbe-assisted stress resilience #TansleyInsight nph.onlinelibrary.wiley.com/doi/10.1111/npโ€ฆ
    Overview of the stressโ€“metabolomeโ€“microbiota (SMM) sequence in plant roots. Plants can sense various abiotic and biotic stress signals, which induce the increased production of corresponding secondary metabolites. These key signaling metabolites can modulate root microbiota, enriching or repelling certain bacteria or fungi, which aid in mitigating the environmental stresses that plants have been subject to.
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    New Phytologist
    @NewPhyt
    Apr 15, 2023
    How to build a #lichen #TansleyReview by Gregor Pichler et al. ๐Ÿ‘‡ ๐Ÿ“– ow.ly/KjXq50NHVbv
    Proposed concept of lichenization, re-lichenization and trans-lichenization.
    31K
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    New Phytologist
    @NewPhyt
    Jul 13, 2022
    Routes to roots: direct evidence of water transport by arbuscular mycorrhizal fungi to host plants @AKakouridis @Firestone_Lab @Jeffinerca @ecologicaljack ow.ly/wTsb50JTRwv
    Simplified representation of water transport from soil through an arbuscular mycorrhizal fungus hypha to a plant root. Extracytoplasmic water transport in a hypha, joins apoplastic transport in a plant root. Cytoplasmic transport in a hypha, joins symplastic transport in a plant root.
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    New Phytologist
    @NewPhyt
    Apr 6, 2019
    Having the right neighbors: how tree species diversity modulates drought impacts on forests @WSL_research #Tansleyinsight ow.ly/SzwA50oueZL
    Conceptual representation of the three classes of mechanisms: resource partitioning, facilitation, and selection effect.
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    New Phytologist
    @NewPhyt
    Jan 11, 2019
    Read the new accepted article from Wester et al. on mammal pollination in African pineapple lilies nph.onlinelibrary.wiley.com/doi/10.1111/npโ€ฆ
    00:00
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    New Phytologist
    @NewPhyt
    Oct 29, 2022
    Maize plants and the brace roots that support them #TansleyInsight @ErinSparksPhD ๐Ÿ“– ow.ly/FhIB50Lo9xS
    Diagram showing some of the many functions of maize brace roots. The roots that are aerialโ€“subterranean play a role in bracing the plant from perturbations. The roots that are aerial can associate with nitrogen (N)-fixing bacteria. The subterranean portion of brace roots probably also plays a key role in soil resource acquisition.