Understanding these processes is key for designing crops that can withstand increasing drought and climate stress.
π Read the paper: www.science.org/doi/10.1126/...
#PlantScience #PlantResilience #WaterStress
How do plants actually sense water?π€
This "simple" question is central to plant survival & crop resilience
In a new Science Advances paper, our NTNU team uncovers new insights into the mechanisms plants use to detect changes in water availability & translate them into stress signals
@science.org
Happy International Women's Day! π§ͺ
The EMBO #WomenInScience Lectures address issues related to gender and #diversity in #science.
Find out more and apply here:
https://www.embo.org/funding/lecture-travel-and-childcare-grants/women-in-science-lectures/
#LifeSciences #funding
How do we strengthen trust in science?
Public trust keeps science strong. Strong public engagement helps build that trust.
A European community of practice on trust in science is now being initiated. Discover more: link.europa.eu/d6kNXT
#EUResearchArea π§ͺ
Our work now on its final version. We mapped the mechanical properties of roots at tissue and single cell levels using Brillouin microscopy and molecular rotors. Additional mutants and stress measurements from what we previously showed in the preprint are included.
www.science.org/doi/10.1126/...
A limestone cave in Western Australia where the Karri tree roots extend the whole height of the massive cavern in search of nutrients and water.
π²
A limestone cave in Western Australia where the Karri tree π³roots extend the whole height of the massive cavern in search of nutrients and water.
Xero branching in action! π·πͺ
1/7 Happy to share that the first publication from my PhD, in which we review the literature about THESEUS1, is now out in @theplantjournal.bsky.social βοΈ: doi.org/10.1111/tpj....
Curiosity, adventure and discovery.
On this International Day of Women and Girls in Science, Giulia Giordano, Eleonora Macchia and GΓ©raldine Laloux share what inspired them to choose a career in science, from early curiosity to inspiring teachers.
#WomenInScience #GirlsInScience #IDWGS #STEM
Full professor for plant ecology in Regensburg. #plantscience #plantscijobs
jobs.zeit.de/jobs/w3-prof...
β’ Cortex cell walls weaken β cells expand radially
β’ Result: a thick epidermisβthin cortex architecture that helps roots penetrate dense soil
π Ethylene modulates cell wall mechanics for root responses to compaction. Nature www.nature.com/articles/s41...
#Plantscience #RootBiology #Science
Image: Semi-thin sections (2βΒ΅m thickness, 1βcm from root tip) of WT, arf1-1, OE-ARF1, cesa6 and arf1cesa6 lines. Scale bar=50βΒ΅m. Credit: Nature https://doi.org/10.1038/s41586-025-09765-7
π± How do roots push through compacted soil?
A new study in @nature.com shows that soil compaction increases ethylene, reshaping cell wall mechanics in roots hydrosensing.eu/2026/02/ethy...
Some key findingsπ
β’ Ethylene activates ARF1 in the root cortex
β’ ARF1 represses cellulose synthase genes
π
Why are stress-resistant crops still rare? Bridging the gap between discovery and the field buff.ly/gnIupta via @universityofessex.bsky.social #Plantscience
Teaching Tools in Plant Biology Graphics highlighting several scientific images/figures.
π£ Check out the latest unit in the Teaching Tools in Plant Biology series, βGenomic Analysis of Botanical Collections: Opportunities and Challenges,β blog.aspb.org/new-teaching.... π±
#PlantScience
With advances in genome sequencing, these insights are now being translated to crop species, opening exciting opportunities for crop innovation. A look back at foundational discoveries, and forward to whatβs next in plant developmental biology.
π To the full paper: doi.org/10.1093/plce...
From a tiny model plant to global food systems ππ±
Review in The Plant Cell explores how decades of research on Arabidopsis thaliana have transformed our understanding of plant development.
#PlantScience #Arabidopsis #PlantGenomics
π
![Image: Description and validation of pMDS plasmid system for dual analysis of transcription and translation in plants. (A) Organization of pMDS1 vector showing reporters for transcription [mTurquoise (mTurQ)], translation (C-terminal mVenus), and a 2A self-cleaving peptide. (B) Organization of pMDS2 vector showing reporters for transcription (mTurQ), translation (N-terminal mVenus), and a 2A self-cleaving peptide. (C) Confocal image of pMDS1_SHRpro:SHR:mVenus:mTurQΒ showing gene expression (mTurQ) in the stele region and protein (mVenus) translocating to endodermis in the root meristem. (D) Confocal image of pMDS2_VAM3pro:mVenus:VAM3:mTurQΒ showing subcellular expression (mTurQ) in the nucleus and protein (mVenus) moving to the vacuole in the root epidermis. Red channel shows mCherry expression. nu, nucleus; vac, vacuole; *, endodermis of root meristem. Scale bar, 10 ΞΌM.Β Credit: Science Advances](https://cdn.bsky.app/img/feed_thumbnail/plain/did:plc:5l42c4gpfv34lqzigeftvql4/bafkreia57owau5zyahyrvj5c4vzu3edakjcabo664cbauhnkhvskrw66ai)
Image: Description and validation of pMDS plasmid system for dual analysis of transcription and translation in plants. (A) Organization of pMDS1 vector showing reporters for transcription [mTurquoise (mTurQ)], translation (C-terminal mVenus), and a 2A self-cleaving peptide. (B) Organization of pMDS2 vector showing reporters for transcription (mTurQ), translation (N-terminal mVenus), and a 2A self-cleaving peptide. (C) Confocal image of pMDS1_SHRpro:SHR:mVenus:mTurQΒ showing gene expression (mTurQ) in the stele region and protein (mVenus) translocating to endodermis in the root meristem. (D) Confocal image of pMDS2_VAM3pro:mVenus:VAM3:mTurQΒ showing subcellular expression (mTurQ) in the nucleus and protein (mVenus) moving to the vacuole in the root epidermis. Red channel shows mCherry expression. nu, nucleus; vac, vacuole; *, endodermis of root meristem. Scale bar, 10 ΞΌM.Β Credit: Science Advances
π§¬π± How do cells tune SUMOylation under stress?
New study builds a SUMO Cell Atlas of the Arabidopsis root, revealing striking tissue- and compartment-specific regulation of the entire SUMO pathway, and how different stresses rewire it.
π To the full paper: www.science.org/doi/10.1126/...
With 5,565 amiRNAs targeting ~82% of the transportome, mTACT enables spatially resolved genetic screens to uncover hidden regulators of signaling molecule transport.
Published in @plantphys.bsky.social
#PlantPhysiology #Arabidopsis #FunctionalGenomics #Transporters #GeneRegulation #PlantScience
π§¬π± Just added a new paper to the website:
A report about a Multi Targeted AmiRNA Cell type-specific Transportome-scale (mTACT) toolbox, a cell type-specific, transportome-scale amiRNA toolbox that overcomes functional redundancy in Arabidopsis.
π Here: hydrosensing.eu/2026/01/mtac...
π
Schematic illustration of NRT1.1B-SPX4-NLP4 or NLP3 response patterns in six different states. States IβIV correspond to plants exposed to constant low-nitrate (LN) or high-nitrate (HN) conditions, as discussed in Ma et al. (2025). States I and II depict a stress-free condition, while states III and IV depict a stress condition, in which abscisic acid (ABA) molecules (red circles) bind to NRT1.1B exclusively under constant LN (Figure 1 State III). Under constant HN conditions, instead of ABA molecules, nitrate ions bind to NRT1.1B, and nitrate is transported from the outside to the inside of the cell (Figure 1 State IV). Abscisic acid molecules are substituted by nitrate. As a reference, the transient application of nitrate ions (green circles) is also included for states V and VI, as discussed in Hu et al. (2019) (note that NLP3 is used here instead of NLP4).
πΏTo #grow or not to grow...πΏ
This #OpenAccess #JIPB commentary discusses the mechanism by which #plants decide whether stop or continue growing under fluctuating #environmental conditions.
doi.org/10.1111/jipb...
@wileylifesci.bsky.social
#PlantScience #botany #evolution #ClimateChange
Hi! You can contact Malcolm Bennett or check the version available in biorxiv: www.biorxiv.org/content/10.1...
2026 UK plant biomechanics workshop on 17th April 2026 in Nottingham.
Abstract submissions deadline is 13 Feb, and registration is open.
π±π§ͺπΏπ¬#PlantSci
4. These signaling pathways translate environmental water patterns into root architecture with clear field relevance.
π€ These insights into moisture-responsive root growth could help improve drought resilience in crops. #Maize #PlantScience
π Full paper: www.science.org/doi/abs/10.1...
4/4
Image: Hydropatterning responses revealed in public sector breeding lines of Zea mays (maize). (A and B) Schematic of the (A) hydropatterning response in (B) our custom-built hydropatterning assay. Primary roots of maize seedlings are grown in a vertical position along moist paper while being prevented from growing off the paper by a mesh cover. Lateral root (LR) primordia are preferentially induced towards the water-saturated paper (contact-side) and suppressed on the air-exposed side (air-side). Longitudinal cross-section of maize root (B73 inbred) stained with Calcofluor White (cell walls; gray) and SYBR Green (LRs; green). (C and D) Distribution of (C) contact-(blue) and air-side (white) LR densities from 250 maize inbred lines characterized using the hydropatterning assay and calculated (D) percent air-side LRs (purple). Each inbred line is represented by its median value (n = 1-3 seedlings/inbred) (data S2). Gray lines connect corresponding inbred lines. Population median (white circles). (E) X-ray Computed Tomography showing LR patterning on primary roots of strong (CI64) and weak (OH7B) hydropatterning inbred lines grown through an air-filled macropore in soil.
2. This divergence likely reflects different historical selection pressures during modern breeding.
3. Auxin promotes root branching toward moisture, while ethylene suppresses branching on air-exposed root surfaces.
3/4
Maize #roots actively pattern new branches toward water (hydropatterning), but this response differs across varieties.
Some key findings:
1. Maize shows genetic diversity in hydropatterning, with tropical/subtropical lines exhibiting stronger responsive root branching.
π
2/3
π± How do maize roots know where water is in dry soils... and why donβt all crops do this equally well??
Recap of the #HS Science paper "Moisture-responsive root-branching pathways identified in diverse maize breeding germplasm"π§πΏ
π Full paper: www.science.org/doi/abs/10.1...
π
1/3
π
Together, these insights highlight roots as dynamic, hormone-regulated organs that fine-tune growth to maximise water acquisition in challenging environments.
π Full paper: academic.oup.com/jxb/article/76/7/1987/8011474
#PlantScience #RootBiology #Science #Plants #Roots #PlantHormones
β’ Hormones act as central integrators of water signals, translating environmental cues into growth responses that reshape root systems.
β’ Hormone-driven root plasticity is crucial for drought adaptation, with targets for improving water-use efficiency & resilience.
Review brings together evidence on how plant hormones coordinate root development in response to water availability.
3 key takeaways:
β’ Roots actively sense water availability, both at the root tip & along mature tissues, enabling directional & adjustment of branching patterns.
π± How do plant roots sense and respond to water in the soil?
Recap of hashtag#HS Journal of Experimental Botany review that synthesises current knowledge on hormonal control of root growthβwater interactionsπ§πΏ
π Full paper: academic.oup.com/jxb/article/76/7/1987/8011474
π
