Zhibo Wang ^1* Dominik K. Großkinsky ² Dongmei Li ³ Weiwei Zheng ⁴

• ¹ Donald Danforth Plant Science Center, St Louis, United States
• ² Austrian Institute of Technology (AIT), Vienna, Vienna, Austria
• ³ Shandong Agricultural University, Taian, Shandong Province, China
• ⁴ Zhejiang Agriculture and Forestry University, Hangzhou, Zhejiang Province, China

investigate the e:ects of elevated CO2 levels on the physiology of strawberries and tomatoes. With atmospheric CO2 levels having increased by more than 20% in the past four decades, this research is highly significant. They found that a three-month exposure to 800 ppm CO2 increased yields in both strawberry and tomato. Additionally, while both species prioritized fruit development over other sink organs, they were limited by carbon export at elevated CO2 levels, as new photoassimilates were evenly distributed across various sinks, regardless of CO2 conditions. With food security becoming an increasingly pressing concern, breeding stress-resistant crops has emerged as a critical focus in modern agriculture. This e:ort is bolstered by advancements in our understanding of the molecular mechanisms and genetic components involved in signaling cascades, transcriptional networks, structural modifications, and biochemical pathways. This Research Topic presents groundbreaking studies that advance molecular biology, genetics, and genomics associated with abiotic stress tolerance, enhancing our ability to dissect plant stress responses. CabHLH18 gene, a specific bHLH transcription factor, from a waterlogging-tolerant pepper cultivar, 'ZHC2'. Compared with wild-type (WT) plants, pepper plants overexpressing CabHLH18 showed greater water content, amino acid, proline, soluble sugar levels, root viability, and superoxide dismutase activity, while exhibiting lower malondialdehyde content under waterlogging conditions. After 24 hours of waterlogging stress, the fresh weight, amino acid, proline, and soluble sugar levels of the overexpression lines were higher than those of the WT plants. Hence, CabHLH18 is a promising candidate for breeding waterlogging-tolerant hot pepper varieties.Liu et al. investigated respiratory burst oxidase homologs (RBOHs), a key enzyme family regulating superoxide production and playing a central role in plant stress responses. Seven PsRBOH genes were identified in the pea genome, with tissue-specific expression patterns and functional diversity during growth and stress responses. PsRBOH4 emerged as a key responsive gene, as its expression was significantly induced under heat, cold, cadmium, drought, and low boron stresses, while PsRBOH1 primarily responded to salt stress. This study provides valuable insights into the functional roles of pea RBOH genes in plant adaptation to climate-related challenges.Aluminum (Al) toxicity in acidic soils is a major limiting factor a:ecting crop yield, inhibiting root growth, reducing nutrient and water absorption, and ultimately impairing photosynthesis. Zhang et al. studied potato aluminum-activated malate transporters (ALMTs), which play important roles in responding to Al toxicity, maintaining ion homeostasis, and supporting mineral nutrient distribution. Fourteen StALMT genes were identified in the potato genome, unevenly distributed across seven chromosomes. Specific StALMT genes were significantly up-regulated in response to Al3+ and overexpression of these genes conferred enhanced growth resistance to Al toxicity, highlighting the pivotal role of these genes in combating Al3+ toxicity in plants.Khassanova et al. identified two chickpea zinc finger knuckle genes, Ca04468 and Ca07571, as key candidates in plant responses to drought and dehydration. Various methods, including Sanger sequencing, DArT (Diversity Array Technology) for plant genotyping, molecular marker and gene expression analyses, and field trials, were used to characterize these genes. Associations with 100-seed weight and seed weight per plant were examined, and two SNP molecular markers for both genes were developed and verified. These markers hold potential for marker-assisted selection to improve drought and dehydration tolerance in chickpea, paving the way for the development of novel chickpea cultivars in the future.These studies collectively highlight the critical advancements in understanding the molecular, genetic, and genomic bases of abiotic stress resistance, providing invaluable tools and knowledge for breeding climate-resilient crop varieties. Under changing climatic conditions, crop plants are increasingly a:ected by combinations of multiple abiotic stresses rather than individual stress factors. Studies in this Research Topic explore the concept of cross-talk between di:erent abiotic stress responses. Samarina et al. investigate the role of specific transcription factors in regulating stressresponsive genes in tea plants under drought and cold conditions, as well as gene models related to cell wall remodeling. The highlighted key signaling pathways suggest that plants employ shared mechanisms to cope with multiple stressors, providing a molecular basis for breeding tea plants with enhanced tolerance to interactive abiotic stresses.The frequent co-occurrence of various abiotic stresses highlights the need to identify potential donors resistant to multiple stressors for developing climate-resilient crop varieties. In this context, Kumar et al. screened 41 rice germplasm accessions, including landraces and elite cultivars, for tolerance to drought, salinity, and submergence at the 21day-old seedling stage over a 10-day period. Specific genotypes were identified as promising donors for multiple abiotic stress tolerance. Additionally, a set of 30 SSR markers linked to drought, salinity, and submergence QTLs were used to characterize these accessions, providing valuable genomic tools for future breeding e:orts. Continuous agricultural production can also introduce atypical abiotic stress to plants. Zhou et al. reported that continuous cropping of tobacco results in the accumulation of allelopathic compounds in the rhizosphere. Redundancy analysis (RDA) identified eight compounds with autotoxic e:ects on tobacco growth. These compounds contributed to yield reductions, outbreaks of tobacco black shank, and a decline in beneficial soil flora.Expanding industrialization and other human activities lead to an increase in the occurrence of sudden environmental pollution accidents (SEPAs), an atypical form of abiotic stress. Developing methods to promptly eliminate pollutants at their source and address the resulting environmental issues is crucial for global ecological health and sustainable human development. Phytoremediation, a biological approach, o:ers advantages such as simplicity, cost-e:ectiveness, and the reduction of secondary pollution compared to traditional methods. Li et al. developed a 3D-QSAR pharmacophore model to predict plant resistance and the phytodegradation of polychlorinated biphenyls (PCBs), a class of organic pollutants regulated under the Stockholm Convention due to their persistence, high toxicity, bioaccumulation, and long-range environmental transport. This study provides theoretical support for the application of transgenic plant-based emergency phytoremediation technology. As the global climate continues to change, the frequency and intensity of abiotic stresses will likely increase, further challenging global food production systems. This Research Topic provides a foundation for developing stress-tolerant crops that can thrive in adverse conditions. Future work should focus on validating the newly identified molecular mechanisms underlying the physiological responses, integrating these insights into breeding programs and agricultural practices, ensuring that crop yield and quality can be maintained in the face of environmental uncertainties. This Research Topic represents a significant step toward understanding the intricate mechanisms that govern plant stress responses and o:ers promising avenues for improving crop resilience through innovative biotechnological approaches.