2024, Szymańska, Grażyna

2022, Panasiewicz, Katarzyna, Szymańska, Grażyna

2022, Radzikowska-Kujawska, Dominika, Sulewska, Hanna, Bandurska, Hanna, Ratajczak, Karolina, Szymańska, Grażyna, Kowalczewski, Przemysław Łukasz, Głowicka-Wołoszyn, Romana

Climate change, including decreasing rainfall, makes cultivating cereals more difficult. Drought stress reduces plant growth and most all yields. On the other hand, consumers’ interest in ancient wheat varieties, including spelt, is growing. The aim of this work is to compare the response to drought stress between spelt (Triticum aestivum ssp. spelta) and common wheat (Triticum aestivum ssp. vulgare). Six cultivars of spelt from different European countries and common wheat ‘Bogatka’ as a reference were chosen for research. The photosynthesis process, chlorophyll fluorescence, relative water content, and the content of free proline and anthocyanins in well-watered and drought-stressed plants were measured. It was shown that the spelt cultivars ‘Franckenkorn’ and ‘Badengold’ were much more resistant to water deficit than other cultivars and even common wheat. A slight reduction of CO2 assimilation (by 27%) and no reduction of transpiration rate, with simultaneous intensive proline (eighteen times fold increase) and anthocyanins accumulation (increase by 222%) along with a slight increase in lipid peroxidation level (1.9%) revealed in ‘Franckenkorn’ prove that this cultivar can cope with drought and can be effectively cultivated in areas with limited water abundance.

2023, Sobiech, Aleksandra, Tomkowiak, Agnieszka, Bocianowski, Jan, Szymańska, Grażyna, Nowak, Bartosz, Lenort, Maciej

The pressure to reduce mineral fertilization and the amount of pesticides used has become a factor limiting production growth, as has the elimination of many crop protection chemicals from the market. A key condition for this to be an effective form of protection is the use of varieties with higher levels of resistance. The most effective and fastest way to assist in the selection and control of pathogens is the conducting of genome-wide association studies. These are useful tools for identifying candidate genes, especially when combined with QTL mapping to map and validate loci for quantitative traits. The aim of this study was to identify new markers coupled to genes that determine maize plant resistance to fusarium head blight through the use of next-generation sequencing, association and physical mapping, and to optimize diagnostic procedures to identify selected molecular markers coupled to plant resistance to this fungal disease. As a result of field experiments and molecular analyses, molecular markers coupled to potential genes for resistance to maize ear fusariosis were selected. The newly selected markers were tested against reference genotypes. As a result of the analyses, it was found that two markers (11801 and 20607) out of the ten that were tested differentiated between susceptible and resistant genotypes. Marker number 11801 proved to be the most effective, with a specious product of 237 bp appearing for genotypes 1, 3, 5, 9 and 10. These genotypes were characterized by a field resistance of 4–6 on the 9° scale (1 being susceptible, 9 being resistant) and for all genotypes except 16 and 20, which were characterized by a field resistance of 9. In the next step, this marker will be tested on a wider population of extreme genotypes in order to use it for the preliminary selection of fusarium-resistant genotypes, and the phosphoenolpyruvate carboxylase kinase 1 gene coupled to it will be subjected to expression analysis.

2023, Ratajczak, Karolina, Sulewska, Hanna, Panasiewicz, Katarzyna, Faligowska, Agnieszka, Szymańska, Grażyna

Phytostimulators are attracting considerable attention for replacing mineral fertilizers, which are of environmental concern, being especially forbidden in organic farming. The benefit of applying such products based on microorganisms (e.g., algae extract) or minerals of nano-meter-sized particle (e.g., nanofertilizers) is that plants can uptake them faster than soil fertilizers, targeting plant growth by regulating their phytohormones, as well as improving plant tolerance to unfavorable environmental conditions (e.g., cold stress). The aim of this study was to test and evaluate the effects of three commercial phytostimulators, called biostimulants (a seaweed-based extract—Kelpak®, mineral nanoparticles—Nano Active®, zinc nanoparticles—Dynamic Cresco®) on yield, chlorophyll content, level of CO2 assimilation and the effectiveness of PSII under cold stress. The values of all chlorophyll fluorescence and photosynthetic parameters significantly decreased under cold, which indicated a strong inhibition of light-phase photosynthesis in maize leaves. Predicted by the regression analysis minimum, 20 days was enough for maize plants to recover from the inhibition caused by stress damages in their photosynthetic apparatus. At the final measurement in maize growth stage BBCH 65, all the tested phytostimulators showed significant effects in increased values of effective quantum yield of photosystem II, maximum photosynthetic efficiency of PSII and electron transport rate. At this stage, Dynamic Cresco® and Nano Active® treatment significantly increased the value of maximum net photosynthetic rate (15.37% and 18.85%, respectively) and leaf chlorophyll content (7.8% and 8.7%, respectively). The application of Dynamic Cresco® significantly promoted total dry weight by 43.4% in comparison to control under stress growth conditions with cold. These phytostimulators can be used to enhance yield and physiological status of plants after abiotic stress (such as cold) to improve crop productivity, especially in organic farming.

2025, Ratajczak, Karolina, Szymańska, Grażyna, Kaźmierczak, J.

2022, Faligowska, Agnieszka, Kalembasa, Stanisław, Kalembasa, Dorota, Panasiewicz, Katarzyna, Szymańska, Grażyna, Ratajczak, Karolina, Skrzypczak, Grzegorz Antoni

The field experiment was carried out in 2013 and 2014 as part of a long-term experiment to test the influence of different soil tillage systems (conventional, reduced, direct sowing) on (a) the yield of summer pea (Pisum sativum L.) and (b) the amount of biologically reduced atmospheric nitrogen (N), which was determined using the 15N dilution method (ID15N). Spring barley was used as a reference plant. Climatic conditions did not have a significant influence on the yield of pea seeds (mean value 4.56 t ha−1), post-harvest residues (3.76 t ha−1) and total biomass (8.33 t ha−1). Soil tillage system was found to have a significant impact on all components of the pea yield in years of experiment, with the highest average seed yield values observed with the conventional system (5.19 t ha−1) and significantly lower values observed with reduced tillage (4.34 t ha−1) and direct sowing (4.17 t ha−1). The content of total N was greatest in the pea biomass that was harvested in the conventional system (202 kg ha−1) and lowest with direct sowing (155 kg ha−1). Nitrogen accumulated in the pea seeds from three sources: atmosphere (mean value 35.2%), fertilizers (6.8%) and soil (57.9%), equating to 48.6, 9.9, and 85.4 kg ha−1, respectively. Soil tillage system was found to have a significant impact on the amount of N that was fixed from the atmosphere by the peas: 17.7% in conventional tillage, 37.9 in reduced system and 50.2% in direct sowing, which equates to a harvested seed yield of 28.9, 52.0 and 64.4 kg ha−1, respectively. In the post-harvest residues, the amount of N fixed from the atmosphere by the pea crop was also modified by the soil tillage system in range: 20.2% in conventional tillage and 32.6% in direct sowing (which equates to 7.4 and 8.5 kg N ha−1, respectively), but the difference was not significant.

2025-04-29, Panasiewicz, Katarzyna, Sobieszczański, Rafał, Ratajczak, Karolina, Faligowska, Agnieszka, Szymańska, Grażyna, Bocianowski, Jan, Kolanoś, Anna, Pretkowski, Rafał

Maize is one of the most productive cereal crops, and is increasingly being grown over large areas. Using the right cultivar of high-quality selected seeds for sowing can be crucial for its productivity. The aim of this study was to investigate the effect of kernel fraction on the seed quality, seed vigor, morphological traits, and seed yield of the trilinear hybrid maize cv. ‘Lokata’. The research factor was the kernel fraction, categorized based on the thousand-kernel weight (TKW) into four groups: I—small; II—medium; III–large; and IV–very large. A three-year experiment showed that increases in the TKW resulted in increases in germination and vigor up to fraction III (large seeds) in maize. Sowing maize seeds with a higher TKW resulted in plants with higher fresh and dry weights in the early stages of maize development; however, this response decreased as growth progressed. The seed yield was significantly correlated with plant height and the number of kernels per cob for all fractions sown, but the fraction did not significantly modify the seed yield of ‘Lokata’ maize.

2025, Faligowska, Agnieszka, Panasiewicz, Katarzyna, Szymańska, Grażyna, Ratajczak, Karolina

2026, Kolanoś, Anna, Panasiewicz, Katarzyna, Faligowska, Agnieszka, Szymańska, Grażyna, Ratajczak, Karolina

Soybean cultivation in Europe remains limited compared to major global producing regions, resulting in dependence on imported sources of plant protein. Although soybean cultivation has expanded in several European countries in recent years, production is still constrained by climatic variability, soil conditions, restricted availability of locally adapted varieties, and yield instability. To improve the stimulation of plant defense mechanisms against biotic and abiotic stress, and above all, to achieve yield stability, there is an increasing search for environmentally friendly products, such as biofertilizers, that can be used to rebuild and maintain a sustainable ecosystem. However, environmental intervention requires extensive research on plant species and bacteria. Therefore, increasing attention is being focused on plant growth-promoting rhizobacteria (PGPR), among other factors. These microorganisms stimulate the growth of their host through various pathways, enabling biomass growth, and improving vitality. In the near future, this may explain the various detailed mechanisms of their interactions with plants. This article reviews the current state of soybean production in Europe and synthesizes recent advances in the understanding of PGPR–soybean interactions, with particular emphasis on both direct and indirect mechanisms of action. The roles of PGPR in nutrient acquisition, phytohormone modulation, biological nitrogen fixation efficiency, and stress tolerance are discussed alongside their capacity to suppress soil-borne pathogens and induce systemic resistance. Furthermore, recent European field and greenhouse studies evaluating seed and soil inoculation strategies are summarized to highlight region-specific responses under diverse agroecological conditions. Collectively, the available evidence indicates that PGPR application can contribute to improved soybean performance in Europe, although its effectiveness remains strongly dependent on environmental factors, strain selection, and crop management practices.

2023, Panasiewicz, Katarzyna, Faligowska, Agnieszka, Szymańska, Grażyna, Ratajczak, Karolina, Sulewska, Hanna

The cultivation of soybeans, especially where this species has not been grown in large areas, requires the determination of the optimal mineral nitrogen fertilization and seed inoculation with Bradyrhizobium japonicum. The purpose of the study was to determine the optimal dose of mineral N fertilization and seed inoculation treatments with B. japonicum under field conditions in the southeastern Baltic region. The objective of this study was to achieve nitrogen supply and/or inoculation with B. japonicum: check-0 kg N ha−1, 30 kg N ha−1, 60 kg N ha−1, HiStick® Soy + 0 kg N ha−1, Nitroflora + 0 kg N ha−1, HiStick® Soy + 30 kg N ha−1, HiStick® Soy + 60 kg N ha−1, Nitroflora + 30 kg N ha−1, Nitroflora + 60 kg N ha−1. Higher yields of seeds, protein and fat were found after application HiStick® Soy compared to Nitorflora. The inoculation with B. japonicum together with nitrogen fertilization improved crude protein content in seeds, biometrical features, yield components and especially the seed yield of ‘Aldana’ soybean. The highest seed yield was found after the application of HiStick® Soy and nitrogen fertilization in doses 30 kg N ha−1 or 60 kg N ha−1. Compared to the control, combined B. japonicum inoculation and nitrogen fertilization in soybean cultivation proved to be a significant factor in improving the productivity of this species in southeastern Baltic conditions.

2025, Panasiewicz, Katarzyna, Faligowska, Agnieszka, Szymańska, Grażyna, Ratajczak, Karolina, Wolna-Maruwka, Agnieszka, Niewiadomska, Alicja, Kolanoś, Anna

2024, Ratajczak, Karolina, Becher, Marcin, Kalembasa, Stanisław, Faligowska, Agnieszka, Kalembasa, Dorota, Symanowicz, Barbara, Panasiewicz, Katarzyna, Szymańska, Grażyna, Sulewska, Hanna

The future of agricultural production involves sustainable production systems with a balance between nutrients in soil–plant systems. These production systems are based on limiting the use of mineral fertilizers while introducing natural sources that increase soil fertility. The best example of such a system is plant rotation, including legumes as a forecrop for cereal plants. For this reason, the goal of the present study was to determine the possibility of obtaining nitrogen from the air using 15N isotopes and to determine the quantity of nitrogen biologically fixed and taken up by winter wheat cultivated as a succeeding plant. In field experiments, we investigated the cycle of nitrogen fixed by legume plants in rotation under sustainable conditions, as follows: soybean–winter wheat–winter wheat. After soybean seedling emergence, a mineral fertilizer (15NH4)2SO4 containing 20.1 at% 15N (a dose of 30 kg∙ha−1) was applied, with summer wheat as a reference plant. The yield of soybean reached 2.48 t∙ha−1 for seeds and 8.73 t∙ha−1 for crop residue (CR), providing a total yield of 11.21 t∙ha−1. The total biomass of soybean contained 149.1 kg∙ha−1 of total nitrogen, with 108.1 kg∙ha−1 in the seeds and 41.0 kg∙ha−1 in the residue, of which 34.0 kg∙ha−1 in the seeds and 11.4 kg∙ha−1 in the residue was biologically fixed. CR was ploughed into the soil. Plots with winter wheat cultivated after soybean (2017) were divided into two sub-plots for the application of 0 and 100 kg∙ha−1 of mineral N. The scheme was repeated in 2018. Overall, winter wheat cultivated for two subsequent years took up 8.12 kg∙ha−1 of the total nitrogen from the CR from the control sub-plot and 15.51 kg∙ha−1 from the fertilized sub-plot, of which 2.61 and 2.98 kg∙ha−1 was biologically fixed by soybean plants, respectively. The dose of fertilizer contained 5.920 kg∙ha−1 of 15N, of which 3.024 kg∙ha−1 was accumulated in soybean. In wheat cultivated as the first subsequent crop, the accumulation of 15N was as follows: 0 kg N (control)—0.088 kg∙ha−1; 100 kg N—0.158 kg∙ha−1. Meanwhile, in winter wheat cultivated as the second aftercrop, 0.052 and 0.163 kg∙ha−1 of 15N was accumulated, respectively. This study demonstrates that biological nitrogen fixation in soybeans is an underappreciated solution for enhancing crop productivity within sustainable agricultural systems. It holds significant implications for planning rational fertilizer management, reducing the application of chemical fertilizers, and improving nitrogen use efficiency within crop rotation systems.

2023, Faligowska, Agnieszka, Panasiewicz, Katarzyna, Szymańska, Grażyna, Ratajczak, Karolina, Starzyk, Justyna

A field experiment was conducted in the Wielkopolska region at the Gorzyń Research Station, Poland (52.34°N, 15.54°E) in Central Europe. The study was conducted over a 3-year period (2017, 2018, 2019) as a two-factorial desingn with four replications in the randomised plots. The aim of the research was to determine the effect of the cultivar (‘Bolero’, ‘Tytan’) and the inoculation (Nitragina–seeds inoculation, Nitroflora I–seeds inoculation, Nitroflora II–soil inoculation, HiStick® Lupin–seeds inoculation) on plant development, seeds chemical composition and yielding of narrow-leaved lupin. The weather conditions and experimental factors significantly influenced on productivity of narrow-leaved lupin ‘Tytan’. Drought during the growing season reduced seeds and protein yields. After inoculation of HiStck the seeds yield was significantly greater by 12.4% and the protein yield after application of Nitroflora I or HiStick by 13.9% and 19.2%, respectively. Correlation coefficients showed strong relations between number of pods and seeds per plant in both cultivars regardless of the inoculation variant, however the strongest relations in both cultivar were proved on HiStick treatment.

2024, Panasiewicz, Katarzyna, Faligowska, Agnieszka, Szymańska, Grażyna, Ratajczak, Karolina, Kłosowicz, Monika, Wolna-Maruwka, Agnieszka

Many countries in Europe are struggling with a shortage of feed protein; moreover, efforts are being made to limit the import of post-extraction soybean meal, most often from GMO crops. To achieve the above assumptions, varietal progress is necessary and, above all, breeding work should aim at greater adaptation to regional conditions. This study was designed to evaluate the potential for growing Ukrainian soybean ‘Annushka’ in the southeastern Baltic Sea area, in accordance with the application of mineral nitrogen fertilizer and the inoculation of seeds with Bradyrhizobium japonicum. Soybean ‘Annushka’ yielded 0.98–1.68 t ha−1 in the conditions of central Poland. Our experiments have shown significant variations in seed, protein, and fat yields over the years. The maximum amounts of these characteristics were recorded in 2017. Nitrogen fertilization combined with seed inoculation with B. japonicum has proven to be an important factor in improving soybean yields; however, it slightly modified the content of organic compounds in seeds. Improvement in seed and protein yields relative to the control amounted, respectively, to Nitragina + 30 kg N ha−1 (58.8%; 72.6%), HiStick® Soy + 30 kg N ha−1 (57.6%; 68.3%), and Nitroflora + 60 kg N ha−1 (57.6%; 71.9%).