Relevance and methodology. The task of controlling the growth and development of sugar beet plants with the help of lighting devices is of interest from the point of view of identifying biological features of the culture and in breeding practice. The purpose of the research is to determine the response of plants to the effects of low–energy monochrome radiation at the initial stage of ontogenesis (germination of seeds (coplodia) sugar beet). In this regard, the seeds of the hybrid Smena were germinated in the dark (control) and under different variants of continuous illumination with wavelengths of 380 nm, 440 nm, 525 nm, 660 nm and 730 nm.Results. The reaction of sugar beet seeds and sprouts to illumination with monochromatic light depends on the wavelength Germination of seeds when irradiated with monochromatic far-red light leads to a decrease in germination energy by 23%, seed germination by 39%, the height of sprouts and aboveground biomass by 21.8% compared with the control (dark germination). Similar indicators were observed for the negative effect of red light. Exposure to UV-A light (380 nm) led to an increase in germination energy by 4%, but germination, on the contrary, decreased by 12%. The terrestrial biomass of sprouts also decreased (by 9.9%). Irradiation with green and blue light had a positive effect on growth: the terrestrial biomass of sprouts increased by 19.8% with a green spectrum and 7.3% blue. At the same time, there was no decrease in germination energy and germination compared to the control. The germination energy under the influence of blue light even increased by 12%. With dark germination, elongated etiolated plants were formed on the 10th day, whereas in the variants of green, blue and UV-A irradiation, harmoniously developed dark green shoots were formed.

The article reflects the issues of the current state of scientific research in the FSBSI FSVC, directions and prospects for the development of selection and seed production of vegetable crops are shown. Varieties have been created that realize the bioclimatic potential of the cultivation zone, meet market requirements, and are capable of producing high yields under the influence of biotic and abiotic stressors. Selection is carried out in a combination of classical methods with innovative technologies.Biotechnologists have improved the basic protocol for in vitro microspore culture for the Brassicaceae, stages of technology for obtaining doubled haploids in microspore culture in vitro for the Apiaceae are being developed. For the first time, an effective protocol for obtaining double haploids of European radish has been developed. Doubled haploids of vegetable crops of the Cucurbitaceae, Amarantháceae, Amaryllidáceae were obtained in vitro in the culture of unpollinated ovules. The Center conducts research on the increased content of biologically active substances and antioxidants. An important place is occupied by immunological studies on the resistance of vegetable crops to harmful diseases. The institution develops systems of protective measures against pests, diseases and weeds for vegetable crops based on the use of new environmentally friendly preparations. On the basis of fundamental and priority applied research of previous years, the creation of 21 varieties and hybrids of cabbage, table beet, tomato, sweet pepper, onion, chives, leek, cucumber, melon, lettuce, chervil, potato, aster, lychnis has been completed. Along with the creation of new breeding achievements, technologies for their cultivation are being improved through the use of new agricultural practices, microfertilizers, biological products and humates on vegetable crops in various soil and climatic zones of Russia. New agricultural methods are being developed in the cultivation of mushrooms. In the field of seed production, methods are being developed to increase the germination of seeds, seed production, elements of the technology for the production of mother liquors and seeds of various vegetable and melon crops; zonal seed production technologies that increase their yield. In 2021, a team of scientists received an award from the Government of the Russian Federation for scientific work "Development and implementation of innovative technologies for growing vegetables and potatoes to provide the population with environmentally friendly food".

Architectonics of dill seed-plant and ripeness level of seeds determine the linear sizes of embryo, exerting an influence on dormant stage, speed of embryo development, and main quality characteristics of seeds, which are responsible for their germination ability.

The influence of high temperature treatment of the seeds of vegetable Umbelliferae crops was studied. Features of seed germination and embryo development depending on incubation time were revealed. High-temperature treatment of seeds during 5 and 20 days inhibits the embryo development and seed germination.

Relevance. In the context of climate change, onion cultivation has become a challenge and innovative solutions are needed to support breeders and seed producers as well as farmers, starting with critical issues of seed quality. Seed priming successfully improves seed viability, which leads to rapid and uniform germination and emergence of onion seedlings.Results. Priming onion seeds can improve viability, especially under unfavorable conditions such as low/high temperatures, reduced water availability and salinity. It is a simple, low-cost and low-risk intervention that can be a useful technology for farmers and have a positive impact on their livelihoods by increasing the rate of seed germination, increasing the rate of plant development, reducing harvest time and increasing yields. Although this method is common for radish, tomato, carrot and cabbage seeds, this method is less popular for onions. This review provides an up-to-date picture of the scientific and technological advances that have contributed to increasing seed germination and vigor in onion plants to date. For large-scale commercial use, optimal priming methods and conditions tailored to different varieties or seed lots will require further extensive experimental work. It cannot be denied that seed priming technology is characterized by ease of operation, low cost and high practical value in industrial and market contexts. It can be foreseen that this technology will have wider prospects in agricultural production and green building. In addition, seed priming can effectively restore or enhance seed viability and ensure successful retention of germplasm resources and subsequent development, especially for onion seeds that rapidly lose viability.

Relevance. Growing plants in artificial conditions (closed agroecosystems) requires precise regulation of plant growth factors, starting from the first stages of ontogenesis. One of the parameters is the presence or absence of light in the period of seed germination. For most types of cabbage the standard method is germination in the dark, but for freshly harvested seeds (at rest) light exposure is necessary. According to the literature, the mechanisms of the effect of light on seed germination are complex and ambiguous, so the issue needs detailed research.Methods. Therefore, the purpose of this work was to study the germination of seeds of broccoli (Brassica oleracea var. italica Plenck) and Chinese cabbage (Brassica rapa var. chinensis), taking into account the light factor and the simultaneous analysis of antioxidant activity as a marker of changes in metabolic processes.Results. The experiment has revealed a significant increase in the antioxidant activity of the microgreens during germination in the dark compared to germination in the light (in broccoli by 5.5 times, in Chinese cabbage by 4.8 times). Later on, after the seedlings are moved to the light, the differences between the light and dark versions practically disappear. After germination in the light, the antioxidant activity of microgreens in comparison with the original (dry seeds) decreased by 3-3.5 times, while in the dark – on the contrary, increased by 1.5-1.6 times. The final results of germination (germination energy and seed germination) practically do not differ in the versions. In the case of dark germination, the height of microgreens is greater (due to etiolation and stretching in the absence of light), however, later on, the differences in the versions are smoothed out. The biomass of microgreens in the version of light germination on the 4th day after sowing seeds in broccoli is by 9.1% higher, in Chinese cabbage – by 10.5%. In case of Chinese cabbage, differences remained until the end of the experiment (on the 18th day from sowing seeds), in case of broccoli they were smoothed out. Comparison of two kinds of cabbage has showen that broccoli in the closed system of the synergotron forms a much higher aboveground biomass than Chinese cabbage (on the 4th day after sowing – by 37%, on the 18th day – by 75.4% in the dark version).

The effect of temperature during seeds germination of some species of Umbelliferae vegetable crops has been studied. There is a different reaction of vegetable crops on the temperature factor: depending on crops and temperature, the number of days until the maximum rate of growth can varied from 7,6 to 22,8 days, and percentage of germinated seeds can varied from 7% to 88%. The effect of temperature on growth of seeds embryo has been studied in different crops. The «degree of underdevelopment of embryo» (DUE) characterized the morphological and anatomical features of embryo varied from 13 to 52%. The temperature coefficient (Q10) for the rate of germination of seeds of vegetable crops of Umbelliferae was 1,23 - 1,82.