Category Ranking
98%
Total Visits
921
Avg Visit Duration
2 minutes
Citations
20
Article Abstract
The search for genetic regulators of leaf venation patterning started over 30 years ago, primarily focused on mutant screens in the eudicotyledon Arabidopsis thaliana. Developmental perturbations in either cotyledons or true leaves led to the identification of transcription factors required to elaborate the characteristic reticulated vein network. An ortholog of one of these, the C2H2 zinc finger protein DEFECTIVELY ORGANIZED TRIBUTARIES 5 (AtDOT5), was recently identified through transcriptomics as a candidate regulator of parallel venation in maize (Zea mays) leaves. To elucidate how AtDOT5 regulates vein patterning, we generated three independent loss-of-function mutations by gene editing in Arabidopsis. Surprisingly, none of them exhibited any obvious phenotypic perturbations. To reconcile our findings with earlier reports, we re-evaluated the original Atdot5-1 and Atdot5-2 alleles. By genome sequencing, we show that reported mutations at the Atdot5-1 locus are actually polymorphisms between Landsberg erecta and Columbia ecotypes, and that other mutations present in the background most likely cause the pleiotropic mutant phenotype observed. We further show that a T-DNA insertion in the Atdot5-2 locus has no impact on leaf venation patterns when segregated from other T-DNA insertions present in the original line. We thus conclude that AtDOT5 plays no role in leaf venation patterning in Arabidopsis.
Download full-text PDF |
Source |
|---|---|
| http://www.ncbi.nlm.nih.gov/pmc/articles/PMC9826136 | PMC |
| http://dx.doi.org/10.1111/tpj.15958 | DOI Listing |
Publication Analysis
Top Keywords
Similar Publications
Adaptive Node Positioning in Biological Transport Networks.
Phys Rev Lett
August 2025
University of Copenhagen, University of Copenhagen, Niels Bohr Institute, Denmark and Department of Computer Science, Copenhagen, Denmark.
Biological transport networks are highly optimized structures that ensure power-efficient distribution of fluids across various domains, including animal vasculature and plant venation. Theoretically, these networks can be described as space-embedded graphs, and rich structures that align well with observations emerge from optimizing their hydrodynamic energy dissipation. Studies on these models typically use regular grids and focus solely on edge width optimization.
View Article and Find Full Text PDFComprehensive data of 10 fruit leaf classes captured for agricultural AI applications.
Data Brief
August 2025
Department of Computer Science and Engineering, Daffodil International University, Daffodil Smart City, Birulia, Dhaka 1216, Bangladesh.
This corpus contains 3173 high-quality images of leaves of ten commonly found fruit species in Bangladesh, namely Lotkon (306), Lychee (312), Mango (330), Black plum (304), Custard apple (304), Guava (325), Jackfruit (311), Aegle marmelos (336), Star Fruit (343), Plum (302). It is captured with Realme 7-Pro (64 MP primary camera) and Realme 8-Pro (108 MP primary camera) smartphones at nurseries near to Daffodil International University, Bangladesh. This dataset addresses the scarcity of high-quality, region-specific agricultural image datasets in South Asia, offering a unique combination of standardized smartphones-based imaging and controlled lighting to ensure consistant high-resolution visual data compared to existiong datasets.
View Article and Find Full Text PDFA spatio-temporal model of embolism propagation in leaf vein networks.
AoB Plants
August 2025
Department of Statistics, Columbia University, 1255 Amsterdam Ave, New York, NY 10027, United States.
Leaf veins hydrate and sustain leaf tissue for photosynthesis. During drought and freeze events, embolisms can form in xylem conduits, ceasing the transport of water. Understanding the formation and propagation of embolisms is crucial to predicting species' responses to a changing climate.
View Article and Find Full Text PDFModeling full-scale leaf venation networks.
PLoS Comput Biol
July 2025
Niels Bohr Institute, University of Copenhagen, Copenhagen, Denmark.
The vascular network of leaves, comprising xylem and phloem, is a highly optimized system for the delivery of water, nutrients, and sugars. The design rules for these naturally occurring networks have been studied since the time of Leonardo da Vinci, who constructed a local rule for comparing the widths of in- and outgoing veins at branch points. Recently, physical models have been developed that seek to explain the full morphogenesis of leaf venial networks in which veins grow in response to local hydrodynamic feedback.
View Article and Find Full Text PDFBioinspired Leaf-Vein Micromixer for a Rapid and Efficient Synthesis of Monodisperse Ciprofloxacin Lipid Nanoparticles.
Langmuir
July 2025
School of Transportation, Shandong Province Key Laboratory of High Performance Hard Alloys and Precision Tools, Ludong University, Yantai, Shandong 264025, China.
Inspired by plant vascular architectures and leveraging hierarchical vein-branching principles, this study pioneers a biomimetic leaf-venation groove micromixer (LVGM) to address critical limitations in passive microfluidic mixing and conventional liposome preparation. Through systematic numerical simulations, we elucidate the flow field characteristics and vortex-driven mixing mechanisms of the LVGM architecture, complemented by experimental validation of its mixing performance and nanocarrier synthesis capabilities. The bioinspired groove configuration induces hierarchical vortical flows that amplify chaotic advection, achieving exceptional mixing efficiencies (>99%) across broad Reynolds numbers ( = 0.
View Article and Find Full Text PDF