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1. WAVE-DAMPENED2-LIKE4 modulates the hyper-elongation of light-grown hypocotyl cells

   https://doi.org/10.1093/plphys/kiad248  

   Schaefer, Kristina; Cairo Baza, Ariadna; Huang, Tina; Cioffi, Timothy; Elliott, Andrew; Shaw, Sidney L (April 2023, Plant Physiology)

   Abstract Light, temperature, water, and nutrient availability influence how plants grow to maximize access to resources. Axial growth, the linear extension of tissues by coordinated axial cell expansion, plays a central role in these adaptive morphological responses. Using Arabidopsis (Arabidopsis thaliana) hypocotyl cells to explore axial growth control mechanisms, we investigated WAVE-DAMPENED2-LIKE4 (WDL4), an auxin-induced, microtubule-associated protein and member of the larger WDL gene family shown to modulate hypocotyl growth under changing environmental conditions. Loss-of-function wdl4 seedlings exhibited a hyper-elongation phenotype under light conditions, continuing to elongate when wild-type Col-0 hypocotyls arrested and reaching 150% to 200% of wild-type length before shoot emergence. wdl4 seedling hypocotyls showed dramatic hyper-elongation (500%) in response to temperature elevation, indicating an important role in morphological adaptation to environmental cues. WDL4 was associated with microtubules under both light and dark growth conditions, and no evidence was found for altered microtubule array patterning in loss-of-function wdl4 mutants under various conditions. Examination of hormone responses showed altered sensitivity to ethylene and evidence for changes in the spatial distribution of an auxin-dependent transcriptional reporter. Our data provide evidence that WDL4 regulates hypocotyl cell elongation without substantial changes to microtubule array patterning, suggesting an unconventional role in axial growth control. 

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2. Data for: Helical Growth of Twining Common Bean is Associated with Longitudinal, Not Skewed, Microtubule Patterning

   https://doi.org/10.5281/zenodo.17082352  

   Acevedo, Angelique (January 2025, Zenodo)

   These are the data used to generate the figures associated with the paper: Helical Growth of Twining Common Bean is Associated with Longitudinal, Not Skewed, Microtubule Patterning.   All associated scripts can be found here: https://github.com/angelique-acevedo/Microtubule-Twining-Analysis 

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3. Single-cell analysis of cell identity in the Arabidopsis root apical meristem: insights and opportunities

   https://doi.org/10.1093/jxb/erab228  

   Shahan, Rachel; Nolan, Trevor M; Benfey, Philip N (May 2021, Journal of Experimental Botany)

   Dubrovsky, Joseph (Ed.)

   Abstract A fundamental question in developmental biology is how the progeny of stem cells become differentiated tissues. The Arabidopsis root is a tractable model to address this question due to its simple organization and defined cell lineages. In particular, the zone of dividing cells at the root tip—the root apical meristem—presents an opportunity to map the gene regulatory networks underlying stem cell niche maintenance, tissue patterning, and cell identity acquisition. To identify molecular regulators of these processes, studies over the last 20 years employed global profiling of gene expression patterns. However, these technologies are prone to information loss due to averaging gene expression signatures over multiple cell types and/or developmental stages. Recently developed high-throughput methods to profile gene expression at single-cell resolution have been successfully applied to plants. Here, we review insights from the first published single-cell mRNA sequencing and chromatin accessibility datasets generated from Arabidopsis roots. These studies successfully reconstruct developmental trajectories, phenotype cell identity mutants at unprecedented resolution, and reveal cell type-specific responses to environmental stimuli. The experimental insight gained from Arabidopsis paves the way to profile roots from additional species. 

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4. Arabidopsis AUGMIN8 Contains Two Independent Microtubule Association Domains

   https://doi.org/10.1002/cm.70068  

   Chana, Naveen K; Cioffi, Timothy; Shaw, Sidney L (November 2025, Cytoskeleton)

   ABSTRACT Plant cells create a plasma membrane‐associated network of microtubules that are nucleated by γ‐tubulin ring complexes primarily through microtubule‐dependent microtubule nucleation (MDMN). This dynamic array organizes into specific patterns in response to developmental and environmental cues to influence primary cell wall construction. The molecular mechanisms directing the creation of cortical microtubule array patterns are largely unknown. The hetero‐octameric AUGMIN complex facilitates mitotic spindle formation by associating γ‐tubulin ring complexes with existing spindle microtubules and creating parallel branched microtubules through MDMN. AUGMIN8, the key linker protein connecting the AUGMIN complex to the parent microtubule, is encoded by a paralogous family of QWRF genes in flowering plants. Members of the QWRF family are distinguished by an unstructured N‐terminal half encoded in a single 5′ exon. We hypothesize that the QWRF paralogs form interchangeable AUGMIN microtubule binding subunits that confer specific roles to the AUGMIN complex in mitotic and non‐mitotic microtubule arrays. We identify four QWRF family members expressed inArabidopsishypocotyl cells and investigate the sites of QWRF interaction with cortical microtubules using transient transformation of fluorescently tagged constructs in the heterologousNicotiana benthamianasystem. We show that full‐length QWRF8 and QWRF4 associate with non‐mitotic, cortical microtubules as distributed puncta where QWRF8 shows evidence for two independent sites of microtubule association. Sequence comparisons and in vivo assay with homologous fragments from QWRF1, 2, 4, and 5 define a shared N‐terminal conserved microtubule association domain. We additionally identify protein regions leading to the formation of microtubule‐associated “QWRF bodies” potentially linked to discontinuous localization on microtubules. We identify the “QWRF” protein motif as a conserved domain associating the AUGMIN8 paralogs with AUGMIN6, part of the larger AUGMIN complex. 

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5. The unconventional TPX2 family protein TPXL3 regulates α Aurora kinase function in spindle morphogenesis in Arabidopsis

   https://doi.org/10.1093/plcell/koaf065  

   Deng, Xingguang; Higaki, Takumi; Lin, Hong-Hui; Lee, Yuh-Ru Julie; Liu, Bo (April 2025, The Plant Cell)

   Abstract Spindle assembly in vertebrates requires the Aurora kinase, which is targeted to microtubules and activated by TPX2 (Targeting Protein of XKLP2). In Arabidopsis (Arabidopsis thaliana), TPX2-LIKE 3 (TPXL3), but not the highly conserved TPX2, is essential. To test the hypothesis that TPXL3 regulates the function of α Aurora kinase in spindle assembly, we generated transgenic Arabidopsis lines expressing an artificial microRNA targeting TPXL3 mRNA (amiR-TPXL3). The resulting mutants exhibited growth retardation, which was linked to compromised TPXL3 expression. In the mutant cells, α Aurora was delocalized from spindle microtubules to the cytoplasm, and spindles were assembled without recognizable poles. A functional TPXL3-GFP fusion protein first prominently appeared on the prophase nuclear envelope. Then, TPXL3-GFP localized to spindle microtubules (primarily toward the spindle poles, like γ-tubulin), and finally to the re-forming nuclear envelope during telophase and cytokinesis. However, TPXL3 was absent from phragmoplast microtubules. In addition, we found that the TPXL3 N-terminal Aurora-binding motif, microtubule-binding domain, and importin-binding motif, but not the C-terminal segment, were required for its mitotic function. Expression of truncated TPXL3 variants enhanced the defects in spindle assembly and seedling growth of amiR-TPXL3 plants. Taken together, our findings uncovered the essential function of TPXL3, but not TPX2, in targeting and activating α Aurora kinase for spindle apparatus assembly in Arabidopsis. 

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