Metagenomic pool sequencing of infected maize leaves was used to monitor the population dynamics of the fungal pathogen Exserohilum turcicum, revealing a recent shift from local clonal lineages to tropical Kenyan lineages in a Swiss agricultural region. The novel leaf‑pooling approach enabled cost‑effective, large‑scale sampling, while phyllobiome analyses showed consistent microbial communities across maize varieties.

The study co‑expressed BABY BOOM and WUSCHEL2 in maize embryos and used single‑cell transcriptomics to infer cell‑type‑specific gene regulatory networks underlying induced somatic embryogenesis. By prioritizing and functionally validating four novel transcription factors, the authors enhanced maize transformation efficiency and produced fertile transgenic plants.

The study tracked molecular changes in plastoglobules and thylakoids of Zea mays B73 during heat stress and recovery, revealing increased plastoglobule size, number, and adjacent lipid droplets over time. Proteomic and lipidomic analyses uncovered up‑regulation of specific plastoglobule proteins and alterations in triacylglycerol, plastoquinone derivatives, and phytol esters, suggesting roles in membrane remodeling and oxidative defense. These insights highlight plastoglobule‑associated pathways as potential targets for enhancing heat resilience in maize.

The study quantifies de novo insertions of the maize Mutator (Mu) transposon across four tissue types, achieving detection of mutations at a frequency of 1 in 16,000. While allele frequency distributions are reproducible within a tissue, they differ markedly between tissues, with roots showing few high-frequency insertions and endosperm displaying many low-frequency ones. Reanalysis of pollen data suggests that observed late Mu activity is better explained by cell division dynamics rather than ongoing transposition.

The study introduced full-length SOC1 genes from maize and soybean, and a partial SOC1 gene from blueberry, into tomato plants under constitutive promoters. While VcSOC1K and ZmSOC1 accelerated flowering, all three transgenes increased fruit number per plant mainly by promoting branching, and transcriptomic profiling revealed alterations in flowering, growth, and stress‑response pathways.

The study validates and quantifies biological nitrogen fixation in Mexican maize varieties and assesses a double‑haploid population derived from an elite inbred (PHZ51) crossed with these landraces. Aerial root traits show moderate to high heritability, and QTL mapping reveals multiple loci influencing root number, node occurrence, and diameter, with most favorable alleles originating from the landraces. The authors suggest that pyramiding the identified QTL into elite germplasm could enhance maize’s BNF capacity, pending field validation.

The study characterizes the protein and lipid composition of chloroplast plastoglobules in the B73 maize line during a water-deficit and recovery time course, identifying key polar and neutral lipids and abundant fibrillin proteins. Quantitative proteomics revealed a strong association between Fibrillin 4 and plastoquinone‑9, suggesting a role in redox and prenyl‑lipid metabolism, thereby establishing a foundation for leveraging plastoglobules to enhance crop drought resilience.

The study evaluated how modest temperature increases affect corn smut disease (Ustilago maydis) severity across multiple maize cultivars, generating extensive phenotypic and transcriptomic data. RNA‑seq and gene‑expression association analyses revealed temperature‑dependent expression changes, pinpointing GIBBERELLIC ACID STIMULATED TRANSCRIPT‑LIKE4 (GSL4) and γ‑aminobutyric acid as key infection factors, which were subsequently validated in vivo.

The study demonstrates that mutating maize A-type cyclin genes homologous to Arabidopsis TAM induces the formation of diploid gametes with high efficiency, leading to tetraploid progeny. This provides a viable apomeiosis component for synthetic apomixis in maize, complementing existing parthenogenesis approaches.

The study examines how the SnRK1 catalytic subunit KIN10 integrates carbon availability with root growth regulation in Arabidopsis thaliana. Loss of KIN10 reduces glucose‑induced inhibition of root elongation and triggers widespread transcriptional reprogramming of metabolic and hormonal pathways, notably affecting auxin and jasmonate signaling under sucrose supplementation. These findings highlight KIN10 as a central hub linking energy status to developmental and environmental cues in roots.