Purpose. To develop a method of propagation, stimulation of rhizomes growth in vitro culture for the genus Miscanthus representatives and their adaptation in the open field without the use of greenhouse complexes for acclimatization and completion of growing.Methods. Biotechnological procedures, mathematical and statistical analyses. Results. Prescription of nutrient medium was developed for explants inoculation, sprouts propagation, rhizomes growth stimulation in vitro. Such sterile explants as seeds, buds to be removed from rhizomes, parts of  stems with bud were placed on modified media with mineral portion by Murashige and Skoog (MS) that contained 0,5–1 dose of macroelements and one dose of microelements,  vitamins (10 mg/l of thia­minum, 1,0 mg/l of pyridoxine, 1,0 mg/l of nicotinic acid and 1,0 mg/l of ascorbic acid) supplemented with amino acids (250 mg/l of glutamic acid, 3 mg/l of tyrosine, 3 mg/l of arginine, 2 mg/l of hydroxyproline), plant growth regulators [0,5–1,0 mg/l of GA (gibberelline acid), 0,2 mg/l of 6-BAP (6-Benzylaminopurine, 0,1 mg/l of NAA (α-naphtylacetic acid)] in different variations. After seed germination, buds emerging and sprouts formation 1–2 cm in height, for propagation purpose they were passivated on the medium of other composition that differed from previous one by the content and ratio of growth regulators, especially by a high concentration of cytokinins [6-BAP (0,4–0,5 mg/l), kinetin (0,5 mg/l), adenine (0,5 mg/k)] in different variations in presence of GA (0,2 mg/l). In order to stimulate rhizomes growth, microclones were transferred on media with other composition and ratio growth regulators (6-BAP (0,2–0,3 mg/l) + GA (0,5–1,0 mg/l) or 6-BAP (0,2–0,3 mg/l) + GA (0,5–1,0 mg/l) + NAA (0,1 mg/l),  in other words,  with a high content of gibberellins. After the formation of rhizomes 10–15 cm in length, miscanthus plants were planted out in the open ground. Stimulation of rhizomes initiation and elongation on appropriate nutrient media before Miscanthus giganteus, M. sacchariflorus and M. sinensis planting in vivo resulted in 100% adaptation and 100% survival of plants in the winter period without the use of greenhouse complexes.Conclusions. The method of miscanthus propagation in vit­ro and adaptation in the open ground was developed that included stimulation of rhizomes growth and favoured the increase of their length on media supplemented with gibbe­relline that guaranteed 100% preservation of microplants to be propagated from in vitro culture during adaptation in the open ground and acclimatization in winter.

Purpose. To analyze the variety diversity of the Itoh peony group in the collection of the M. M. Hryshko National Botanical Garden National Botanical Garden National Academy of Sciences of Ukraine and determine its biological features in the new conditions of introduction. Methods. Introduction studies, phenological observations, morphometry, statistical processing of results. Results. The cultivars diversity of the Itoh peony group of the M. M. Hrysh­ko National Botanical Garden National Botanical Garden National Academy of Sciences of Ukraine collection was analyzed. The ornamental properties of the cultivars were described. Features of their growth and development under conditions of introduction were studied. It was revealed that the duration of vegetation of plants of Ito group varieties is 218–225 days. It was determined that plant growth begins on March 23 – April 2, flowering on May 19–28. The budding of plants was observed in the first decade of May and lasts 16–20 days. It was revealed that in the conditions of introduction ‘Morning Lilac’ and ‘Sonoma Apricot’ bloom first (May 19–20), ‘Viking Full Moon’, ‘Yankee Doodle Dandy’, ‘Yellow Waterlily’ bloom later (May 28). The height of generative shoots of plants in flowe­ring phase ranged from 60 to90 cm. Plants go dormant in winter, having formed generative shoots that successfully winter. Reproduction of plants occurs both due to the buds that form on the lower part of the stem, and the buds that form on the rhizome. The shoot-forming ability and flowering productivity are 6.0±2.5 – 19.5±4.0 shoots and 4.5±1.5 – 16.0±3.0 generative shoots per plant, respectively. Cultivars ‘First Arrival’, ‘Sonoma Apricot’, ‘Hillary’, ‘Bartzella’, ‘Morning Lilac’, ‘Lollipop’, ‘Old Rose Dandy’ are highly productive. Conclusions. The collection of peonies of the M. M. Hryshko National Botanical Garden National Botanical Garden National Academy of Sciences of Ukraine has been expanded by Itoh Group cultivars. The R. Anderson’s breeds of 1980–1990 are more fully represented. An analysis of the ornamental features of the varieties showed that the hybrids with a semi-double flower shape of a yellow color dominate the collection. Cultivars retain all their ornamental and economic characteristics under conditions of introduction. The Itoh group varieties of the collection can be material for developing technologies for their cultivation and propagation, can be a source of replenishment and expansion of regional botanical gardens collections, planting material for gardening and landscaping, and also perform an educational and cognitive function.

Purpose. Estimate phenological and morphological characteristics of Miscanthus giganteus J. M. Greef & Deuter ex Hodkinson & Renvoize, M. sacchariflorus (Maxim) Benth. and M. sinensis Anderss., obtained in vitro, and M. giganteus, propagated by rhizomimes (ex vitro) to attract them to the breeding process and create new forms of miscanthus for use in bioenergy. Methods. Seeds of M. sinensis, as well as M. sacchariflorus (2n), M. sacchariflorus (4n), introduced into culture and propagated in vitro according to commonly used methods (M. D. Melnychuk, A. Plazek et al.) were used in the studies. Phenological observations were carried out according to the methods of V. V. Zinchenko, M. V. Roik, D. B. Rakh­metov, and others. Statistical processing of the obtained data was carried out according to M. A. Shelamov and ot­hers. Results. M. sacchariflorus (2n) in the conditions of the Forest-Steppe of Ukraine does not enter into the flowering phase, whereas in M. sacchariflorus (4n) the flowering phase begins a month earlier than M. sinensis, which is an obstacle for transpollination of these species in the natural environment. M. giganteus, reproduced by rhizomes, in overwhelming majority of indicators (stem height and diameter, number of interstices and leaves, leaf area, length and width of cluster) dominate all species of mescanthus obtained in vitro. But the number of stems in the bush of M. sinensis is the highest (63 pcs.) and is almost 2–4 times higher than those of M. giganteus, obtained from risomes and in vitro. It has been revealed that the most promising forms for bioenergy use are M. sinensis, whose productivity is about 7 kg/m2 of green mass and M. giganteus, propagated by rhizomimes (ex vitro), where the mass of the aerial part is almost 9 kg/m2. But M. sacchariflorus (2n) and M. sacchariflorus (4n) should not be considered as promising species for use in bioenergy purposes, because their performance is very low compared to other species and is only 0.25 and 2.05 kg above ground mass from 1 m2. Conclusions. On the basis of the obtained data, the most promising forms of Miscanthus were established to attract them into the breeding process and to obtain new varieties with high biomass productivity for the needs of bioenergy. | Цель. Оценить фенологические и морфологические характеристики растений мискантуса гигантского (Miscanthus giganteus J.M.Greef & Deuter ex Hodkinson & Renvoize), мискантуса сахароцветного (M. sacchariflorus (Maxim) Benth.) и мискантуса китайского (M. sinensis Anderss.), полученных в культуре in vitro, и мискантуса гигантского, размноженного ризомами (ex vitro) для привлечения их в селекционный процесс и создания новых форм мискантуса для использования в биоэнергетике. Методы. В исследованиях использовали семена M. sinensis, а также M. sacchariflorus (2n), растения M. sacchariflorus (4n), введены в культуру и размножены в условиях in vitro по общепринятым методикам (М. Д. Мельничук и др., A. Plazek et al.). Фенологические наб­людения проводили по методикам В. А. Зинченко, М. В. Роика, Д. Б. Рахметова и др.; статистическую обработку полученных данных – по М. А. Шеламовой и др. Результаты. M. sacchariflorus (2n) в условиях Лесостепи Украины в фазу цветения не вступает, зато у M. sacchariflorus (4n) цветение начинается на месяц раньше, чем у M. sinensis, что является препятствием для переопыления этих видов в естественной среде. M. giganteus, размноженный ризомами, по подавляющиму большинству показателей (высота и диаметр стебля, количество междоузлий и листьев, площадь листьев, длина и ширина метелки) доминирует над всеми видами мискантуса, полученными в культуре in vitro. Однако количество стеб­лей в кусте у растений M. sinensis является наибольшим (63 шт.) и почти в 2–4 раза превышает показатели растений M. giganteus, полученных из ризом и в in vitro. Наиболее перспективными формами для использования в биоэнергетике является M. sinensis и размноженный ризомами (ex vitro) M. giganteus, урожайность зеленой массы которых составляла примерно 7 и 9 кг/м2 соответственно, тогда как M. sacchariflorus (2n) и M. sacchariflorus (4n) для этого непригодны, ведь формируют лишь 0,25 и 2,05 кг наземной массы с 1 м2. Выводы. На основе полученных данных установлены перспективные формы Miscanthus для привлечения их в селекционный процесс и получения новых сортов с высокой продуктивностью биомассы для нужд биоэнергетики. | Мета. Оцінити фенологічні та морфологічні характеристики рослин міскантусу гігантського (Miscanthus giganteus J.M.Greef & Deuter ex Hodkinson & Renvoize), міскантусу цукроквіткового (M. sacchariflorus (Maxim) Benth.) та міскантусу китайського (M. sinensis Anderss.), отриманих у культурі in vitro, та міскантусу гігантського, розмноженого ризомами (ex vitro) для залучення їх у селекційний процес і створення нових форм міскантусу для використання в біоенергетиці. Методи. У дослідженнях використовували насіння M. sinensis, а також M. sacchariflorus (2n), рослини M. sacchariflorus (4n), уведені в культуру та розмножені в умовах in vitro за загальноприйнятими методиками (М. Д. Мельничук, A. Plazek та ін.). Фенологічні спостереження проводили за методиками В. О. Зінченко, М. В. Роїка, Д. Б. Рахметова та ін.; статистичну обробку отриманих даних – за М. А. Шеламовой та ін. Результати. M. sacchariflorus (2n) в умовах Лісостепу України у фазу цвітіння не вступає, натомість у M. sacchariflorus (4n) цвітіння починається на місяць раніше, ніж у M. sinensis, що є перешкодою для перезапилення цих видів у природньому середовищі. M. giganteus, розмножений ризомами, за переважною більшістю показників (висота та діаметр стебла, кількість міжвузлів та листків, площа листків, довжина та ширина волоті) домінує над усіма видами міскантусу, отриманими в культурі in vitro. Проте кількість стебел у кущі в рослин M. sinensis є найбільшою (63 шт.) і майже у 2–4 рази перевищує показники рослин M. giganteus, отриманих із ризом та в in vitro. Найперспективнішими формами для використання в біоенергетиці є M. sinensis та розмножений ризомами (ex vitro) M. giganteus, урожайність зеленої маси яких становила приблизно 7 і 9 кг/м2 відповідно, тоді як M. sacchariflorus (2n) та M. sacchariflorus (4n) для цього є непридатними, адже формують лише 0,25 та 2,05 кгназемної маси з 1 м2. Висновки. На основі отриманих даних установлено найперспективніші форми Miscanthus для залучення їх у селекційний процес та отримання нових сортів з високою продуктивністю біомаси для потреб біоенергетики.

Purpose. To establish biological features of plants growth and development and the formation of Miscanthus giganteus planting material depending on the cultivation technology elements. Methods. Field, laboratory, visual, weight measu­ring, mathematical and statistical ones. Results. The features of the growth and development of the miscanthus bioenergy crop were investigated including the formation of planting material depending on the combined technology elements application during the planting time, namely: planting time, rhizome mass, the granules and the MaxiMarin absorbent gel. It was established that the increase in plant height and leaf area as well as the miscanthus stems formation was depended on both the rhizome planting time, their size, and the use of the absorbent. During three-year period, increase in plant height was more intensive and leaf area was largest in case of the absorbent application, as compared to the control during all phases of the development for the first and the second planting time regardless of rhizome mass. On the average, the largest leaf area – 1905,9 cm3 – was in the final stage of vegetation in the context of the second planting time for large rhizomes and application of granules and absorbent gel jointly. Increasing the ground mass due to plant height, leaf area and the number of stems benefited the photosynthesis productivity intensity, that influenced the root system increase, and consequently the output of the miscanthus planting material. It was found that there are direct strong correlation between these indices and the rhizome mass. Ground mass growing is contributed to the increase in the rhizome mass, and accordingly the output of the planting material – rhizome. In case of application of granules and absorbent gel jointly, the ground mass of the miscanthus was growing most intensively and accordingly the rhizome mass was the largest, which in the first year of small rhizomes planting was twice as much as compared to the control and was equal to 1090.5 g, for large rhizomes planting this index was respectively 2.4 times more and equal to 1763.9 g. During the second planting time, the application of granules and absorbent gel jointly resulted in the rhizomes mass increase for small rhizomes planting 1.9, large rhizomes – 2.1 times more as compared to the control. Conclusions. Direct strong correlations were established bet­ween the intensity of the ground mass growth – the height of plants, the number of leaves, leaf area, the number of buds and the rhizome mass. The growth of the ground mass of plants was contributed to the increase of the root system, and consequenly the output of planting material. In all sta­ges of plant development, the increase of the rhizome mass was more intensive in case of the absorbent application regardless the time of rhizome planting, as compared to the control. The application of granules and absorbent jointly allowed to form the largest rhizome mass.

Purpose. To develop a method of propagation, stimulation of rhizomes growth in vitro culture for the genus Miscanthus representatives and their adaptation in the open field without the use of greenhouse complexes for acclimatization and completion of growing. Methods. Biotechnological procedures, mathematical and statistical analyses. Results. Prescription of nutrient medium was developed for explants inoculation, sprouts propagation, rhizomes growth stimulation in vitro. Such sterile explants as seeds, buds to be removed from rhizomes, parts of stems with bud were placed on modified media with mineral portion by Murashige and Skoog (MS) that contained 0,5–1 dose of macroelements and one dose of microelements, vitamins (10 mg/l of thia­minum, 1,0 mg/l of pyridoxine, 1,0 mg/l of nicotinic acid and 1,0 mg/l of ascorbic acid) supplemented with amino acids (250 mg/l of glutamic acid, 3 mg/l of tyrosine, 3 mg/l of arginine, 2 mg/l of hydroxyproline), plant growth regulators [0,5–1,0 mg/l of GA (gibberelline acid), 0,2 mg/l of 6-BAP (6-Benzylaminopurine, 0,1 mg/l of NAA (α-naphtylacetic acid)] in different variations. After seed germination, buds emerging and sprouts formation 1–2 cm in height, for propagation purpose they were passivated on the medium of other composition that differed from previous one by the content and ratio of growth regulators, especially by a high concentration of cytokinins [6-BAP (0,4–0,5 mg/l), kinetin (0,5 mg/l), adenine (0,5 mg/k)] in different variations in presence of GA (0,2 mg/l). In order to stimulate rhizomes growth, microclones were transferred on media with other composition and ratio growth regulators (6-BAP (0,2–0,3 mg/l) + GA (0,5–1,0 mg/l) or 6-BAP (0,2–0,3 mg/l) + GA (0,5–1,0 mg/l) + NAA (0,1 mg/l), in other words, with a high content of gibberellins. After the formation of rhizomes 10–15 cm in length, miscanthus plants were planted out in the open ground. Stimulation of rhizomes initiation and elongation on appropriate nutrient media before Miscanthus giganteus, M. sacchariflorus and M. sinensis planting in vivo resulted in 100% adaptation and 100% survival of plants in the winter period without the use of greenhouse complexes. Conclusions. The method of miscanthus propagation in vit­ro and adaptation in the open ground was developed that included stimulation of rhizomes growth and favoured the increase of their length on media supplemented with gibbe­relline that guaranteed 100% preservation of microplants to be propagated from in vitro culture during adaptation in the open ground and acclimatization in winter.

Purpose. Estimate phenological and morphological characteristics of Miscanthus giganteus J. M. Greef & Deuter ex Hodkinson & Renvoize, M. sacchariflorus (Maxim) Benth. and M. sinensis Anderss., obtained in vitro, and M. giganteus, propagated by rhizomimes (ex vitro) to attract them to the breeding process and create new forms of miscanthus for use in bioenergy. Methods. Seeds of M. sinensis, as well as M. sacchariflorus (2n), M. sacchariflorus (4n), introduced into culture and propagated in vitro according to commonly used methods (M. D. Melnychuk, A. Plazek et al.) were used in the studies. Phenological observations were carried out according to the methods of V. V. Zinchenko, M. V. Roik, D. B. Rakh­metov, and others. Statistical processing of the obtained data was carried out according to M. A. Shelamov and ot­hers. Results. M. sacchariflorus (2n) in the conditions of the Forest-Steppe of Ukraine does not enter into the flowering phase, whereas in M. sacchariflorus (4n) the flowering phase begins a month earlier than M. sinensis, which is an obstacle for transpollination of these species in the natural environment. M. giganteus, reproduced by rhizomes, in overwhelming majority of indicators (stem height and diameter, number of interstices and leaves, leaf area, length and width of cluster) dominate all species of mescanthus obtained in vitro. But the number of stems in the bush of M. sinensis is the highest (63 pcs.) and is almost 2–4 times higher than those of M. giganteus, obtained from risomes and in vitro. It has been revealed that the most promising forms for bioenergy use are M. sinensis, whose productivity is about 7 kg/m2 of green mass and M. giganteus, propagated by rhizomimes (ex vitro), where the mass of the aerial part is almost 9 kg/m2. But M. sacchariflorus (2n) and M. sacchariflorus (4n) should not be considered as promising species for use in bioenergy purposes, because their performance is very low compared to other species and is only 0.25 and 2.05 kg above ground mass from 1 m2. Conclusions. On the basis of the obtained data, the most promising forms of Miscanthus were established to attract them into the breeding process and to obtain new varieties with high biomass productivity for the needs of bioenergy.