Genetius

The study used chemically induced effector-triggered immunity combined with single-cell transcriptomics to map immune responses across all leaf cell types in Arabidopsis, revealing that while a core defense program is universally activated, individual cell types deploy distinct transcriptional modules. Functional assays showed that epidermis‑specific transcriptional regulators are essential for preventing pathogen penetration, indicating a spatial division of immune functions within the leaf.

The study combined cell biology, transcriptomics, and ionomics to reveal that zinc deficiency reduces root apical meristem size while preserving meristematic activity and local Zn levels, leading to enhanced cell elongation and differentiation in Arabidopsis thaliana. ZIP12 was identified as a highly induced gene in the zinc‑deficient root tip, and zip12 mutants displayed impaired root growth, altered RAM structure, disrupted Zn‑responsive gene expression, and abnormal metal partitioning, highlighting ZIP12’s role in maintaining Zn homeostasis and meristem function.

The study profiled root transcriptomes of Arabidopsis wild type and etr1 gain-of-function (etr1-3) and loss-of-function (etr1-7) mutants under ethylene or ACC treatment, identifying 4,522 ethylene‑responsive transcripts, including 553 that depend on ETR1 activity. ETR1‑dependent genes encompassed ethylene biosynthesis enzymes (ACO2, ACO3) and transcription factors, whose expression was further examined in an ein3eil1 background, revealing that both ETR1 and EIN3/EIL1 pathways regulate parts of the network controlling root hair proliferation and lateral root formation.

The authors engineered a novel ethylene‑responsive promoter (EBSn) containing ten divergent natural EIN3‑binding sites and demonstrated that it provides higher sensitivity and broader tissue expression than existing reporters in Arabidopsis thaliana. The EBSn promoter successfully monitored endogenous ethylene levels and also functioned in tomato, suggesting utility for studying ethylene‑regulated processes such as fruit ripening.

The study used Arabidopsis thaliana mutants with low (vtc2, vtc4) and high (vtc2/OE-VTC2) ascorbate levels to examine how ascorbate concentration affects gene expression and cellular homeostasis. Transcriptomic analysis revealed that altered ascorbate levels modulate defense and stress pathways, and that TAA1/TAR2‑mediated auxin biosynthesis is required for coping with elevated ascorbate in a light‑dependent manner.

The study uses time-course microscopy to show that VAR2 mutants have delayed and heterogeneous chloroplast biogenesis, with many cells lacking chloroplasts, especially in white leaf sectors. Genetic interactions reveal that loss of plastid division genes worsens the phenotype, while overexpressing PDV1/PDV2 or knocking out COP1 rescues it, indicating VAR2’s novel role in plastid division and chloroplast development. These findings clarify mechanisms behind leaf variegation.

The study identifies HISTONE DEACETYLASE COMPLEX 1 (HDC1) as a positive regulator of sepal size during maturation in Arabidopsis thaliana, showing that hdc1 mutants exhibit prolonged elongation due to delayed maturation. Integrated transcriptomic and proteomic analyses, together with genetic and chemical experiments, reveal that HDC1 promotes ethylene production, which in turn triggers ROS accumulation to terminate sepal growth. These findings elucidate a coordinated ethylene‑ROS signaling mechanism controlling organ size during plant development.

The study compares transcriptional, proteomic, and metabolomic responses of wild‑type Arabidopsis and a cyp71A27 mutant to a plant‑growth‑promoting Pseudomonas fluorescens strain and a pathogenic Burkholderia glumeae strain, revealing distinct reprogramming and an unexpected signaling role for the non‑canonical P450 CYP71A27. Mutant analysis showed that loss of CYP71A27 alters gene and protein regulation, especially during interaction with the PGP bacterium, while having limited impact on root metabolites and exudates.

The study shows that soil compaction induces ethylene production, which upregulates Auxin Response Factor1 in the root cortex and represses cellulose synthase genes, leading to altered cell wall thickness and mechanics that cause radial expansion of cortical cells. This ethylene‑mediated modulation of cell wall strength creates a stiff epidermis‑soft cortex architecture, linking hormonal signaling to root mechanical adaptation in compacted soils.

The study identifies the scaffolding protein RACK1A as a cytoplasmic interaction partner of the antioxidant enzyme FSD1, revealing that RACK1A recruits FSD1 to cycloheximide-sensitive condensates that colocalize with stress granules during salt stress. Functional analyses show that this RACK1A‑FSD1 module modulates ROS levels, influences root hair tip growth, and determines salt‑stress resilience in Arabidopsis.