Cold stress severely limits grapevine survival and fruit production. In this study, scientists discovered that the transcription factor VaWRKY65 plays a pivotal role in helping Vitis amurensis withstand freezing temperatures. The gene enhances cold tolerance through a dual mechanism: promoting the breakdown of starch into soluble sugars and stimulating the detoxification of reactive oxygen species (ROS). These combined effects improve cellular stability and energy balance under stress. The research also identified VaBAM3 and VaPOD36 as key downstream genes activated by VaWRKY65. This work uncovers how sugar metabolism and ROS scavenging are transcriptionally coordinated to strengthen cold resilience in grapevine.

The coupled effect of dynamics and nucleation during supercooled droplet’s collision on superhydrophobic surface plays an important role in the anti-icing capability of different superhydrophobic surface, however, without any method to evaluate it. In this work, the impact-freezing behaviors of supercooled droplets on surfaces with different wettability, including two typical hydrophobic surfaces, were investigated experimentally. The morphology, size, velocity, and nucleation rate of freezing on each surface at different temperatures were extracted, based on which emphasis was put on discussing the discrepancy of freezing processes and the formation mechanism of freezing morphologies on different superhydrophobic surfaces. The main findings are: (1) The freezing morphology on superhydrophobic surface was independent of contact angle and supercooling degree, but depended on the surface roughness; (2) the interaction between the fast motion of unfrozen water and the generation of ice nucleus dominates in the formation of freezing morphology, while the ice growth process has less influence. On smooth surface, multiple ice nucleus generating before bounce impeded the fast retraction of droplet, forming irregular-hill freezing shape whose size enlarged with decreasing temperature. On rough surface, because of the later nucleation after retraction process finished, the freezing morphology showed convergent sphere shape with supercooling-independent freezing size; (3) considering more complicated impact dynamics, including breaking and bouncing, on different superhydrophobic surfaces, an impact-freezing model was established and could be used to estimate the average frozen spreading ratio.

Pollen viability is essential for plant fertility, yet the genetic mechanisms ensuring pollen wall integrity remain poorly understood. This study reveals that two NAC transcription factors, SlNOR and SlNOR-like1, act redundantly to regulate pollen development in tomato. Loss of both genes leads to collapsed, nonviable pollen and complete male sterility. The findings show that these transcription factors activate critical genes involved in lipid metabolism and pollen wall formation, such as SlABCG8/9/23, SlCER1, and SlGRP92. By controlling sporopollenin and wax biosynthesis, SlNOR and SlNOR-like1 maintain pollen wall stability, offering new insight into the transcriptional regulation of male fertility in flowering plants.

A perspective article by international scientists underscores a critical new dimension to the global plastic crisis: Plastic pollution is not just harming wildlife and human health, but also disrupting the Earth’s carbon cycle in profound and lasting ways.

Wearable microfluidic sensors are promising for efficient sweat analysis, with applications in sports, healthcare, worker safety, and more fields. Recently, researchers from Chung-Ang University have successfully demonstrated next-generation soft, skin-interfaced 3D microfluidic systems for accurate and comprehensive sweat rate, cumulative loss, and biochemical content assessment. This cutting-edge technology is expected to revolutionize real-time and non-invasive tracking of health status and disease progression.

Garlic, a vital vegetable and medicinal crop, suffers severe yield losses from persistent viral infections accumulated through clonal propagation. This study presents the first single-cell transcriptomic atlas of garlic cloves during swelling growth, revealing how viruses invade and interact with individual cell types. By analyzing over 19,000 high-quality cells, researchers identified 11 distinct clusters and reconstructed their differentiation trajectory from meristem to mature parenchyma cells. Intriguingly, meristem cells exhibited strong viral resistance, while parenchyma cells became major viral hotspots. Co-expression and metabolomic analyses further uncovered glutathione-related genes and RNA-silencing pathways as key antiviral responses, providing unprecedented insights into garlic’s cellular immunity.

Onions with glossy leaves possess an unexpected advantage: natural resistance to thrips, one of the crop’s most damaging pests. Researchers identified a premature stop codon mutation in the AcCER2 gene, disrupting the formation of epicuticular wax—a layer that normally gives onion leaves their frosty-white look. Multi-omics analyses revealed that the loss of wax alters fatty acid elongation, gene expression, and metabolite accumulation, resulting in higher flavonoid levels and reduced soluble sugars. These changes appear to make the glossy onions less attractive to thrips. The discovery of AcCER2’s regulatory role provides a new genetic target for breeding pest-resistant onion varieties.

Shanghai Jiao Tong University researchers have developed a data-driven method to recognize the coordinated intentions of unmanned aerial vehicle (UAV) swarms.

By combining a simplified flight motion model with an artificial neural network, the approach can predict swarm behavior early and accurately—advancing aerial surveillance and autonomous defense systems.

The innovation features of this research are: Treating a UAV swarm as a single intelligent entity and combining the Dubins motion model with an artificial neural network to achieve early and highly accurate intention recognition of coordinated swarm behaviors.