A common garden experiment with 320 wild barley (Hordeum vulgare) accessions across two seasons quantified over 30 photophysiological traits, revealing heritable variation and strong genotype-by-environment interactions. Genome-wide association studies and population genetics identified signals of local adaptation, particularly involving stomatal conductance under water limitation, highlighting its role in maintaining photosynthesis and biomass.

The study investigates the role of the Arabidopsis transcription factor AtMYB93 in sulfur (S) signaling and root development, revealing that AtMYB93 mutants exhibit altered expression of S transport and metabolism genes and increased shoot S levels, while tomato plants overexpressing SlMYB93 show reduced shoot S. Transcriptomic profiling, elemental analysis, and promoter activity assays indicate that AtMYB93 contributes to root responses to S deprivation, though functional redundancy masks clear phenotypic effects on lateral and adventitious root formation.

A forward genetic screen in the negative photoblastic plant Aethionema arabicum identified a phytochrome A null mutant (koy2) that fails to inhibit seed germination under various light qualities, demonstrating that phytochrome A mediates light‑inhibited germination. The study links natural variation in phytochrome A signaling to local adaptation across the Irano‑Turanian region.

The study performed transcriptome profiling of Cryptomeria japonica individuals from different geographic origins grown in three common gardens across Japan, assembling 77,212 transcripts guided by the species' genome. Using SNP-based genetic clustering and weighted gene co‑expression network analysis, they identified gene modules whose expression correlated with genetic differentiation, revealing that defense‑related genes are up‑regulated in Pacific‑side populations while terpenoid metabolism genes are higher in Sea‑of‑Japan populations, indicating local adaptation via regulatory changes.

The study examined interspecific and intraspecific drought responses of Populus fremontii, P. angustifolia, and their hybrids using leaf-level visible‑shortwave infrared spectroscopy and canopy-level UAV thermal imaging. Spectral shifts revealed that hybrids showed the strongest drought reaction, while local adaptation influenced the magnitude and direction of spectral changes, demonstrating convergence under stress. These findings highlight remote sensing as a powerful tool to detect ecological and evolutionary drought responses across scales.