Search Results (871)

Phytopathogenic diseases are a major limiting factor in agricultural production. Therefore, scientific research continues to focus on developing effective techniques to mitigate their impact on crop productivity. Seaweed extracts, used as nutritional supplements, organic fertilizers, or bio-pesticides, have demonstrated their ability to enhance plant growth, increase yield, and alleviate the effects of abiotic stress. This study aimed to evaluate the effect of the aqueous extract of Bifurcaria bifurcata, collected from the Atlantic coast of Sidi Bouzid (El Jadida, Morocco), on the growth of Solanum tuberosum L., as well as its bactericidal activity against soft rot caused by Dickeya dadantii. The chemical Characterization revealed that Bifurcaria bifurcata aqueous extract is rich in polar and hydrophilic functional groups. In addition, this extract is particularly rich in phenolic metabolites, particularly phenolic acids, such as p-coumaric acid, ferulic acid, vanillic acid, and caffeic acid, which are known for their potential antimicrobial mechanisms. However, the treatment with 4 g/L extract resulted in a significant reduction in disease symptoms (>60%) and enhanced plant growth parameters, including 21% increase in plant height and 33% increase in leaf number. POX activity increased 6-fold (from 0.12 to 0.7 µmol/min/mg protein), indicating successful elicitation of plant defense mechanisms. The Bifurcaria bifurcata extract could act as novel activators of plant defense mechanisms and serve as potential alternatives to chemical pesticides. Full article

Genetically modified (GM) plants have been commercially grown for 30 years, and their acceptance depends on a thorough risk assessment. Environmental Risk Assessment (ERA) evaluates potential impacts of releasing GM plants into the environment, whether through cultivation or import for food, feed, and processing. A key component is assessing potential gene flow to crop wild relatives or non-GM crops. For gene flow to significantly affect the environment, transferred genes must provide a selective advantage. Since most GM plants are engineered for herbicide tolerance, insect resistance, or stacked traits, evaluating such advantages is relatively straightforward. New genomic techniques (NGTs) can generate plants with a wider range of traits, including tolerance to biotic and abiotic stress. Although still considered GM in the EU, their genomic changes can complicate detection, identification, and ERA, especially when such traits may offer advantages under stress conditions. This scoping review focuses on gene flow in two crops: oilseed rape (canola) (Brassica napus L.) and potato (Solanum tuberosum L.). In canola, transgene movement can increase weediness, fitness, herbicide resistance, or genetic diversity in feral or related populations. Gene flow in potato is less studied, with concerns centered on contamination risks in the Andean diversity center. Limited data exist for NGT plants, though many are expected to resemble conventionally bred varieties, suggesting comparable environmental impacts. Full article

Potato (Solanum tuberosum L.), as a shallow-rooted crop, is relatively sensitive to soil water deficits; therefore, irrigation plays a crucial role in achieving economically viable production and quality. However, due to the scarcity of water, which has become more precious and less available due to climate change, it is essential to optimize irrigation management and enhance water productivity. The present systematic review, drawing on the most relevant scientific literature, discusses the current state of knowledge on irrigation management and water productivity in potato crop production in semi-arid regions, particularly within Mediterranean countries. Overall, the main findings indicate different possible solutions for saving irrigation water and increasing water productivity by adopting a combination of water-saving strategies, such as static or dynamic deficit irrigation, or partial root-zone drying, and by using a suitable irrigation method like drip irrigation. In addition, the importance of other agronomic factors, namely planting dates, soil texture, and fertilization management, has also emerged, prompting scientists to pay greater attention to them in the future, along with the selection or breeding of appropriate cultivars, which may represent the long-term solution to the problem of water scarcity. Full article

Yeast models are widely used to study molecular chaperones from diverse organisms, including plants, because of their well-characterized genetics and the conservation of the protein-folding machinery among eukaryotes. Cross-species complementation studies in yeast have yielded valuable insights into conserved biochemical activity and molecular functions that manage protein folding, assembly, and repair during stress. This study evaluated the functional capacity of three potato StBiP isoforms (StBiP1, StBiP2, and StBiP3) to complement the kar2 deletion (kar2Δ) strain under a range of environmental and ER stress conditions. All three StBiPs partially restored colony growth under normal conditions, demonstrating that they are functional orthologs of yeast KAR2 and can support core ER housekeeping functions. Under severe stress, however, the isoforms diverged: StBiP3 most effectively complemented the kar2Δ strain during heat- and chemically induced ER stress, whereas StBiP1 and StBiP2 provided weaker protection. Unfolded protein response (UPR) activation, monitored via HAC1 mRNA splicing, further highlighted isoform-specific differences in how the StBiPs support IRE1-HAC1 signaling under ER stress and oxidative stress. A conserved cysteine in the nucleotide-binding domain, previously implicated in Kar2 redox control, was also critical for StBiP3-mediated protection in yeast, although the same mutation led to different consequences in plant tissues. Together, these findings provide evidence of subfunctionalization among potato BiP isoforms, with StBiP3 emerging as a stress-specialized chaperone that is a promising target for improving ER stress resilience in solanaceous crops. Full article

Steroidal glycoalkaloids (GAs) are key plant defense compounds, yet their effects on insect gut physiology are not fully understood. We investigated how purified α-chaconine and Solanum tuberosum leaf extract influence the gut function and growth of the mealworm Tenebrio molitor. Larvae were exposed to sublethal doses of GAs, and gut contractility, midgut digestive enzyme activity and body weight were analysed over time. Both α-chaconine and potato extract caused a rapid decrease in digestive enzyme activity 2 h after exposure, followed by a clear increase above control levels after 24 h, indicating a time-dependent compensatory response of the digestive system. Gut contractility was significantly enhanced in treated larvae, and larvae exposed to both treatments exhibited a body weight loss over 72 h. These results show that potato glycoalkaloids strongly modulate the gut physiology of T. molitor while allowing continued growth, highlighting both the plasticity of insect digestive responses and the need to consider sublethal, gut-centered effects when evaluating glycoalkaloids as candidates for bioinsecticidal agents. Full article

Weed identification and quantification are processes that are usually manual, subjective, and error-prone. Weeds compete with crops for nutrients, minerals, physical space, sunlight, and water. Thus, weed identification is a crucial component of precision agriculture for autonomous removal and site-specific treatments, efficient weed control, and sustainability. Convolutional Neural Networks (CNNs) are very common in weed identification. This work implemented CNN models for semantic segmentation based on the U-Net architecture for automatically segmenting and quantifying weeds in potato crops using RGB images acquired by a drone at 9–10 m height, flying at 1 m/s. Remote sensing images are affected by factors that degrade image quality and the model’s accuracy. Five U-Net variants were evaluated: the original U-Net, Residual U-Net, Double U-Net, Modified U-Net, and AU-Net. The models were trained using the TensorFlow/Keras frameworks on Google Colab Pro+, following the Knowledge Discovery in Databases (KDD) methodology for image analysis. Each model was trained using a diverse custom dataset in uncontrolled environments, considering six classes: background, Broadleaf dock (Rumex obtusifolius), Dandelion (Taraxacum officinale), Kikuyu grass (Cenchrus clandestinum), other weed species, and the crop potato (Solanum tuberosum L.). The models’ segmentation was widely assessed using Mean Dice Coefficient, Mean IoU, and Dice Loss metrics. The results showed that the Residual U-Net model performed the best in multi-class segmentation, achieving a Mean IoU of 0.8021, a performance comparable to or superior to that reported by other authors. Additionally, a Student’s t-test was applied to complement the data analysis, suggesting that the model is reliable for weed quantification. Full article

Potato (Solanum tuberosum L.), the fourth most important food crop worldwide, serves as a multi-purpose resource for food, feed and industrial raw materials, and plays a pivotal role in safeguarding food security, diversifying dietary structure and boosting the development of agricultural economy. With increasing consumer demand for nutritional quality, elucidating the regulatory mechanisms of potato quality traits has become a research priority. In this study, three potato cultivars with distinct coloration were employed as materials. Metabolomic profiling identified a total of 1128 metabolites, and revealed that pigmented potato cultivars accumulated higher levels of flavonoids and linoleic acid derivatives compared with the white-fleshed cultivar. Transcriptomic analysis uncovered numerous differentially expressed genes (DEGs) among the three cultivars; notably, DEGs in pigmented cultivars were significantly enriched in pathways related to terpenoid backbone biosynthesis, flavonoid biosynthesis, linoleic acid metabolism, and starch and sucrose metabolism. Integrated multi-omics analysis revealed that the high expression of structural genes in the flavonoid biosynthesis pathway is strongly associated with flavonoid accumulation in pigmented potatoes, suggesting that transcriptional upregulation of these genes may be a key driver of flavonoid biosynthesis. Furthermore, several MYB and WD40 family transcription factors were identified as potential regulators of flavonoid and anthocyanin biosynthesis in potato. Collectively, our study provides insight into the regulatory mechanisms underlying the biosynthesis of secondary metabolites in potato by combining transcriptomic and metabolomic approaches, and the findings provide a valuable theoretical basis for the genetic improvement of potato nutritional quality in future breeding programs. Full article

Drought and elevated temperature are major abiotic stresses that limit potato growth and productivity; however, their combined effects on biomass and oxidative damage to proteins remain poorly understood. We investigated individual and interactive effects of drought and elevated temperature on growth traits, yield, protein carbonylation, 20S proteasome activity, and the leaf proteome. Results show that while an elevated temperature alone did not significantly impair vegetative biomass or yield, it markedly intensified the negative impacts of drought during simultaneous exposure. Drought and combined stress substantially reduced stem and leaf mass, as well as assimilation area. Biochemically, drought induced protein carbonylation and stimulated 20S proteasome activity. Interestingly, elevated temperature reduced carbonylation and proteasome activity, yet its presence in combined stress exacerbated oxidative damage compared to drought. Proteomic analysis revealed stress-specific carbonylation of molecular chaperones, antioxidant enzymes, and proteins involved in photosynthesis, glycolysis, and energy metabolism. These results suggest that while potato plants exhibit resilience to moderately elevated temperature, the synergistic effect of heat and drought triggers a more severe oxidative challenge. This requires enhanced proteolytic and antioxidant mechanisms to maintain growth and productivity under complex stress conditions. Full article

The growing pollution caused by plastics with slow degradation kinetics is demanding the search for biodegradable alternatives. Starch-based films are a promising option, but their practical application may be limited by their potential susceptibility to rapid ultraviolet (UV) exposure degradation. This study evaluates the effect of prolonged UV-C irradiation (254 nm, 168 h) on plasticizer-free films derived from the starch of an Ecuadorian potato Solanum tuberosum (Chola variety). Films formulated at 3% and 5% (w/v) starch were characterized before and after UV exposure. The analysis includes the evaluation of optical, mechanical, and physicochemical properties, along with Fourier Transform Infrared spectroscopy (FTIR) and atomic force microscopy (AFM) for nanoscale surface inspection. UV irradiation increased the opacity of the films but reduced slightly their tensile strength, elongation at break, moisture content, and total soluble matter. In contrast, the elastic modulus remained relatively high. FTIR analysis revealed no significant formation of new functional groups. AFM measurements indicated that irradiation caused only minor nanoscale alterations in the same film regions. These alterations were more pronounced in films with higher starch concentrations. The results demonstrate that UV-C exposure induces minor structural adjustments in plasticizer-free starch films derived from the Chola variety, without compromising their fundamental integrity. Consequently, this work advances the understanding of the environmental stability of these films and supports their potential application as sustainable materials, even in conditions involving UV exposure. Full article

Aux/IAA proteins function as central transcriptional repressors in auxin signaling and have been implicated in coordinating developmental responses to environmental stress, particularly through modulation of root system architecture. However, the contribution of auxin signaling components to drought-associated root plasticity in improving drought resilience in potato (Solanum tuberosum L.) remains unclear. In this study, we profiled Aux/IAA responses to water deficit across underground tissues by RNA sequencing of root tips, stolon tips, and tubers from two cultivars (Qingshu 9 and Atlantic) with contrasting drought tolerance. Drought treatment induced broad transcriptional changes in the Aux/IAA family, with the majority of members showing increased expression in at least one tissue. qRT-PCR across tissues and developmental stages validated distinct spatiotemporal patterns for selected candidates. Among these, the StIAA3, StIAA6, StIAA22, and StIAA25 genes displayed drought-inducible expression, whereas StIAA24 showed an opposite trend. To probe functional relevance, we generated overexpression and knockdown lines for StIAA3, StIAA6, StIAA22, and StIAA24. Altered expression of these genes was consistently associated with measurable changes in root architecture traits, including root length, diameter, and volume, under water-deficit conditions. These findings reveal insights into the contribution of auxin signaling components to drought-associated root plasticity in potato. The identified drought-responsive Aux/IAA candidates that link root architectural remodeling provide a foundation for mechanistic dissection and underground tissue remodeling of architecture enhancement in root crops. Full article

Potato cultivars are inherently sensitive to high temperatures, and dissecting the mechanisms underlying heat response and tolerance has long been a central focus in potato research. However, the molecular mechanisms governing the short-term heat stress response in potato, as well as the regulatory role of DNA methylation in heat adaptation, remain largely unclear. In this study, we identified breeding line D187 as heat-tolerant and cultivar Q9 as heat-sensitive through microtuber induction under heat stress. We further confirmed that heat-sensitive cultivar Q9 exhibited distinct physiological responses in leaves following 6 h of heat treatment. Comparative transcriptome analysis of leaves exposed to 6 h of heat stress revealed distinct molecular response patterns between D187 and Q9. D187 specifically upregulated genes enriched in heat and other stress response pathways to enhance heat adaptation, whereas Q9 relied on pathways related to RNA modification and splicing, presumably adapting to high temperatures via post-transcriptional regulation. Notably, genes involved in the RdDM pathway were differentially upregulated in both genotypes, and heat stress correspondingly enhanced CHH methylation levels in the vicinity of functional genes in the heat-sensitive cultivar Q9. Treatment with 5-Azacytidine, a DNA methylation inhibitor, exacerbated the inhibition of in vitro tuber formation under high temperatures, indicating that maintaining and enhancing DNA methylation is essential for heat adaptation in potato. Furthermore, overexpression of StAGO4a/b in Nicotiana benthamiana modestly improved heat tolerance, suggesting that StAGO4s act as positive regulators of heat tolerance in potato. Collectively, our results suggest that heat-induced CHH methylation near functional genes via the RdDM pathway contributes positively to heat stress response and tolerance in Q9, providing new insights for identifying heat tolerance regulators from a DNA methylation perspective. Full article

Potato (Solanum tuberosum L.), the world’s fourth most significant food crop, faces a critical sustainability challenge: meeting escalating global demand while mitigating the substantial environmental footprint of its production. Potato exhibits high nitrogen requirements, which makes conventional fertilization significantly inefficient, with nitrogen use efficiency (NUE) being below 40%, contributing to severe environmental losses, including nitrate leaching and nitrous oxide emissions. In this comprehensive review, global research is examined regarding enhanced-efficiency nitrogen fertilizers, such as nitrification inhibitors (NIs), urease inhibitors (UIs), and slow-released fertilizers, which promote a pivotal strategy for sustainable potato cultivation. An extensive analysis is provided exploring the biochemical mechanisms of these inhibitors, their complex interactions with potato physiology, and also their impact on tuber yield, quality, and environmental footprint. These insights are combined with sustainable strategies to optimize nitrogen fertilization in potato cropping systems. Lastly, essential knowledge gaps, such as ongoing soil-health impacts and climate-change interactions, are underlined, and future directions of research are proposed to advance inhibitor utilization on potato production. Full article

In Alberta, extreme weather events, such as hailstorms, have negative impacts on agriculture. Previous studies have found that potato crop yield and quality losses from hail are dependent on both the severity and the timing of the event. It has also been demonstrated that biostimulant products can positively impact crop yields by increasing plant growth and stress resistance. In the current study, we examined whether the application of biostimulants lessens the negative impacts of simulated hailstorms on potato growth. Potato plants were defoliated at three timepoints during the growing season. Tuber yield was reduced by ~25–40%, depending on at which timepoint the plants were defoliated, and specific gravity declined for plants defoliated later in the growing season. The overall fry color increased for plants defoliated earlier in the growing season, as did the incidence of sugar ends. The application of biostimulant products prior to defoliation lessened the impact of defoliation in terms of both overall yield and tuber processing quality. Tuber yields for defoliated plants treated with biostimulants were ~12–60% higher, depending on the defoliated/treatment timepoint, compared to defoliated control plants. Specific gravity was increased for defoliated plants treated with biostimulants at later timepoints. The overall fry color and incidence of dark ends decreased for defoliated plants treated with biostimulants at early timepoints. Defoliation early in the growing season, around tuber initiation, had the most negative impact on both tuber quality and yield, and treatment with biostimulants had the greatest impact on reducing yield and quality losses when applied at this timepoint. Full article

This study conducted a multi-criteria assessment of farming systems (organic vs. integrated) and hydrothermal conditions on the productivity and quality of seven potato cultivars in Southern Poland (2022–2024). The objective was to identify genotypes with the highest plasticity for adaptation to Sustainable Land Management (SLM) strategies. Using a split-plot design, analyses covered total and marketable yield, tuber architecture, and starch and dry matter concentration. Statistical evaluation utilized ANOVA and variance component analysis to determine the contribution of genetic and environmental factors to phenotypic variability. Results showed that productivity was strongly determined by the cultivation system, with organic yields being 20–57% lower due to Phytophthora infestans and virus pressure. Notably, the lack of a significant three-way interaction (S × V × Y) for quality traits suggests high predictability of starch and dry matter based on genotype selection, regardless of management-induced stressors. The ‘Lawenda’ cultivar demonstrated superior adaptation to organic frameworks. We conclude that organic potato production is viable in warming climates if supported by rigorous cultivar selection and biological innovations. Future research should focus on the long-term monitoring of soil organic matter dynamics and the economic viability of these systems throughout a full crop rotation cycle. Such an approach is essential to provide a more comprehensive and robust foundation for sustainable land-use policies. Full article