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1. Two transporters mobilize magnesium from vacuolar stores to enable plant acclimation to magnesium deficiency

   https://doi.org/10.1093/plphys/kiac330  

   Tang, Ren-Jie; Yang, Yang; Yan, Yu-Wei; Mao, Dan-Dan; Yuan, Hong-Mei; Wang, Chao; Zhao, Fu-Geng; Luan, Sheng (July 2022, Plant Physiology)

   Abstract Magnesium (Mg) is an essential metal for chlorophyll biosynthesis and other metabolic processes in plant cells. Mg is largely stored in the vacuole of various cell types and remobilized to meet cytoplasmic demand. However, the transport proteins responsible for mobilizing vacuolar Mg2+ remain unknown. Here, we identified two Arabidopsis (Arabidopsis thaliana) Mg2+ transporters (MAGNESIUM TRANSPORTER 1 and 2; MGT1 and MGT2) that facilitate Mg2+ mobilization from the vacuole, especially when external Mg supply is limited. In addition to a high degree of sequence similarity, MGT1 and MGT2 exhibited overlapping expression patterns in Arabidopsis tissues, implying functional redundancy. Indeed, the mgt1 mgt2 double mutant, but not mgt1 and mgt2 single mutants, showed exaggerated growth defects as compared to the wild type under low-Mg conditions, in accord with higher expression levels of Mg-starvation gene markers in the double mutant. However, overall Mg level was also higher in mgt1 mgt2, suggesting a defect in Mg2+ remobilization in response to Mg deficiency. Consistently, MGT1 and MGT2 localized to the tonoplast and rescued the yeast (Saccharomyces cerevisiae) mnr2Δ (manganese resistance 2) mutant strain lacking the vacuolar Mg2+ efflux transporter. In addition, disruption of MGT1 and MGT2 suppressed high-Mg sensitivity of calcineurin B-like 2 and 3 (cbl2 cbl3), a mutant defective in vacuolar Mg2+ sequestration, suggesting that vacuolar Mg2+ influx and efflux processes are antagonistic in a physiological context. We further crossed mgt1 mgt2 with mgt6, which lacks a plasma membrane MGT member involved in Mg2+ uptake, and found that the triple mutant was more sensitive to low-Mg conditions than either mgt1 mgt2 or mgt6. Hence, Mg2+ uptake (via MGT6) and vacuolar remobilization (through MGT1 and MGT2) work synergistically to achieve Mg2+ homeostasis in plants, especially under low-Mg supply in the environment. 

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2. Regulation of Vacuole Fusion in Stomata by Dephosphorylation of the HOPS subunit VPS39

   https://doi.org/10.1101/2025.10.02.680005  

   Pullen, Anne-Marie; Billings, Grant; Hodgens, Charles; White, Gisele; Akpa, Belinda S; Rojas-Pierce, Marcela (October 2025, bioRxiv)

   ABSTRACT Understanding how plants regulate water loss is important for improving crop productivity. Tight control of stomatal opening and closing is essential for the uptake of CO₂while mitigating water vapor loss. The opening of stomata is regulated in part by homotypic vacuole fusion, which is mediated by conservedhomotypic vacuoleproteinsorting (HOPS) and vacuolar SNARE (soluble N-ethylmaleimide sensitive factor attachment protein receptors) complexes. HOPS tethers apposing vacuole membranes and promotes the formation oftrans-SNARE complexes to mediate fusion. In yeast, HOPS dissociates from the assembled SNARE complex to complete vacuole fusion, but little is known about this process in plants. HOPS-specific subunits VACUOLE PROTEIN SORTING39 (VPS39) and VPS41 are required for homotypic plant vacuole fusion, and a computational model predicted that post-translational modifications of HOPS may be needed for plant stomatal vacuole fusion. Here, we characterized a viable T-DNA insertion allele ofVPS39which demonstrated a critical role of VPS39 in stomatal vacuole fusion. We found that VPS39 has increased levels of phosphorylation when stomata are closed versus open, and that VPS39 function in stomata and embryonic development requires dynamic changes in phosphorylation. Our data are consistent with VPS39 phosphorylation altering vacuole dynamics in response to environmental cues, similar to well-established phosphorylation cascades that regulate ion transport during stomatal opening. SIGNIFICANCE STATEMENTVacuole fusion is important for stomata opening but how it is regulated in response of stomata opening signals is not characterized. This research demonstrated the role of the HOPS complex in vacuole fusion in stomata, and it identified phosphorylation sites in the HOPS subunit VPS39 that are critical for vacuole fusion. One Ser residue was enriched in closed stomata and represents a putative site for control of vacuole fusion downstream of stomata opening signals. 

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3. PEK14 : A Kinesin‐4 Necessary for Male‐Derived Fertility in Arabidopsis thaliana

   https://doi.org/10.1002/cm.22042  

   Mendes, Isabella_N; Groves, Norman_R; Li, Jessica_Z; Thompson, Lily_N; Smith, Brian_J; Husbands, Aman_Y; Meier, Iris (May 2025, Cytoskeleton)

   ABSTRACT Of the 61 kinesins annotated inArabidopsis thaliana, many are still without assigned function. Here, we have screened an insertional mutant library of Arabidopsis pollen‐expressed kinesins for fertility defects. Insertional mutants for three kinesins showed a significant reduction in seed set. Among them, we focused on the sole kinesin‐4 expressed in pollen (kinesin‐4C, here Pollen‐Expressed Kinesin 14, PEK14). We show a seed‐set defect in the three independent allelespek14‐1, pek14‐2, and pek14‐3. This defect is male‐derived and is equally distributed throughout the silique. Maturepek14‐1anthers contain about 10% inviable pollen grains.pek14‐1pollen tubes grow 20% more slowly and show reduced pollen tube bending. Analysis of the male germ unit (MGU), as it travels through the pollen tube, demonstrates an aberrant organization of thepek14‐1MGU in 30% of pollen tubes and an increase in the distance of the MGU to the tip by 24%. Expression of GFP‐tagged PEK14 successfully complemented the observed seed set defect, as well as the growth rate, bending, and MGU organization defects observed inpek14‐1. In pollen, PEK14‐GFP is located diffusely at the pollen tube tip. PEK14‐GFP is also expressed in the root meristematic zone and is located at the mid‐zone of the phragmoplast, but no apparent root growth phenotype was observed, likely due to redundancy in this organ. 

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4. Interactions between root hairs and the soil microbial community affect the growth of maize seedlings

   https://doi.org/10.1111/pce.14755  

   Quattrone, Amanda; Lopez‐Guerrero, Martha; Yadav, Pooja; Meier, Michael A; Russo, Sabrina E; Weber, Karrie A (February 2024, Plant, Cell & Environment)

   Abstract Root hairs are considered important for rhizosphere formation, which affects root system functioning. Through interactions with soil microorganisms mediated by root exudation, root hairs may affect the phenotypes and growth of young plants. We tested this hypothesis by integrating results from two experiments: (1) a factorial greenhouse seedling experiment withZea mays B73‐wtand its root‐hairless mutant,B73‐rth3, grown in live and autoclaved soil, quantifying 15 phenotypic traits, seven growth rates, and soil microbiomes and (2) a semi‐hydroponic system quantifying root exudation of maize genotypes. Possibly as compensation for lacking root hairs,B73‐rth3seedlings allocated more biomass to roots and grew slower thanB73‐wtseedlings in live soil, whereasB73‐wtseedlings grew slowest in autoclaved soil, suggesting root hairs can be costly and their benefits were realized with more complete soil microbial assemblages. There were substantial differences in root exudation between genotypes and in rhizosphere versus non‐rhizosphere microbiomes. The microbial taxa enriched in the presence of root hairs generally enhanced growth compared to taxa enriched in their absence. Our findings suggest the root hairs' adaptive value extends to plant‐microbe interactions mediated by root exudates, affecting plant phenotypes, and ultimately, growth. 

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5. A temperature-sensitive FERONIA mutant allele that alters root hair growth

   https://doi.org/10.1093/plphys/kiaa051  

   Kim, Daewon; Yang, Jiyuan; Gu, Fangwei; Park, Sungjin; Combs, Jonathon; Adams, Alexander; Mayes, Heather B; Jeon, Su Jeong; Bahk, Jeong Dong; Nielsen, Erik (December 2020, Plant Physiology)

   null (Ed.)

   Abstract In plants, root hairs undergo a highly polarized form of cell expansion called tip-growth, in which cell wall deposition is restricted to the root hair apex. In order to identify essential cellular components that might have been missed in earlier genetic screens, we identified conditional temperature-sensitive (ts) root hair mutants by ethyl methanesulfonate mutagenesis in Arabidopsis thaliana. Here, we describe one of these mutants, feronia-temperature sensitive (fer-ts). Mutant fer-ts seedlings were unaffected at normal temperatures (20°C), but failed to form root hairs at elevated temperatures (30°C). Map based-cloning and whole-genome sequencing revealed that fer-ts resulted from a G41S substitution in the extracellular domain of FERONIA (FER). A functional fluorescent fusion of FER containing the fer-ts mutation localized to plasma membranes, but was subject to enhanced protein turnover at elevated temperatures. While tip-growth was rapidly inhibited by addition of rapid alkalinization factor 1 (RALF1) peptides in both wild-type and fer-ts mutants at normal temperatures, root elongation of fer-ts seedlings was resistant to added RALF1 peptide at elevated temperatures. Additionally, at elevated temperatures fer-ts seedlings displayed altered reactive oxygen species (ROS) accumulation upon auxin treatment and phenocopied constitutive fer mutant responses to a variety of plant hormone treatments. Molecular modeling and sequence comparison with other Catharanthus roseus receptor-like kinase 1L (CrRLK1L) receptor family members revealed that the mutated glycine in fer-ts is highly conserved, but is not located within the recently characterized RALF23 and LORELI-LIKE-GLYCOPROTEIN 2 binding domains, perhaps suggesting that fer-ts phenotypes may not be directly due to loss of binding to RALF1 peptides. 

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