Purpose. Selecting spring wheat lines with increased adaptive capacity. Methods. Field experiments, statistical evaluation. Results. Lines of spring soft wheat with better adaptive capacity were identified (‘Erythrospermum 13-39’, ‘Lutescens 11-16’, ‘Lutescens 05-24’, ‘Lutescens 10-36’) and spring durum wheat (‘Melanopus 10-02’ (biotype II), ‘Melanopus 10-02’, ‘Melanopus 10-03’, ‘Hordeiforme 12-12’). Spring soft wheat varieties ‘Zlata’, ‘Dubravka’, ‘Oksamyt Myronivskyi’, ‘Bozhena’ and spring durum wheat varieties ‘MIP Raiduzhna’, ‘Magdalena’ with increased adaptive capacity were passed for State variety testing. Conclusions. With regard to the analysis of parameters of yield capacity and its variability under the influence of changing environmental factors, soft and durum spring wheat lines with increased adaptive capacity were identified. The best spring wheat lines for general adaptive capacity were passed for State variety testing. Soft spring wheat variety ‘Zlata’ and durum spring wheat variety ‘MIP Raiduzhna’, in 2014, and such soft spring wheat varieties as ‘Dubravka’, ‘Oksamyt Myronivskyi’, ‘Bozhena’ and spring durum wheat variety ‘Magdalena’, in 2015, were passed for State variety testing.

Рurpose. To investigate inheritance of “plant height” trait in populations of the first (F1) and second (F2) generations of the soybean (Glucine max (L.) Merrill) and evaluate hybrid combinations in order to identify phenotypes with the highest level of heterosis for plant height. Methods. Laboratory test, mathematical and statistical analysis. Results. The inheritance of plant height in soybean was investigated. Hybrid combinations were assessed for the ability to select phenotypes with an optimal height. Different types of inheritance of this trait were found in populations of the second generation. The highest degree of heterosis for plant height was expressed by such soybean hybrids of the second generation as ‘АЕЕМ ’/‘Cherniatka’ (102.6%), next were ‘№ 427/‘Коrado’ (36,1%) and ‘Yelena’/‘Vizhion’ (32,0%). For the above trait, the ‘Legend’ variety in combinations with such varieties as ‘Staroukrainka’, ‘Korado’ and ‘Medeia’ expressed a heterosis amounting to 28.1%, 8.3%, 6.1% accordingly. Plant height was inherited mainly in terms of negative overdominance (34.2% combinations). There were 21.1% of combinations that had a negative semidominance. Conclusions. Among large majority of crossing combinations, forms were revealed that differed greatly for the plant height. The highest variability was observed in combinations such as ‘Legenda’/‘Korado’, ‘Ustia’/‘Vizjion’, ‘№894’/‘Vizjion’, ‘Ug-30’/‘Vizjion’, ‘Legenda’/‘Annushka’, ‘№441’/‘Gentleman’, ‘№441’/‘Vizjion’, ‘Yug-30’/‘Gentleman’, ‘Angelica’/‘Annushka’ and ‘Angelica’/‘Gentleman.

Purpose. Comparative studies of the photosynthetic apparatus of winter wheat varieties of modern and earlier breeding in the relation to their productivity. Methods. Field, pot experiment, biometrical, gas analysis, analytical and statistical ones. Results. It is found that the modern high-yielding winter wheat varieties have a higher rate of flag leaf photosynthesis during generative period of development, particularly at grain filling period, improved ability to store assimilates in stem and effectively use them later for grain growth. The modern varieties form crop canopy with greater leaf area and chlorophyll indexes and larger photosynthetic capacity and maintain functional activity of photosynthetic apparatus longer at the end of the growing season. Conclusions. The superiority for grain productivity of modern high-yielding wheat varieties, originated from the Institute of Plant Physio­logy and Genetics, NAS of Ukraine, over varieties released before the “green revolution”, results from increased capacity and durability of functioning the crop photosynthetic apparatus, higher CO2 assimilation rate and optimization of source-sink relations in whole plant.

Цель. Установить наиболее эффективные индексные показатели для определения селекционной ценности генотипов пшеницы яровой.Методы. Полевой, статистический. Определяли индекс перспективности – IР, финно-скандинавский индекс – FSI, мексиканский – MI, белоцерковский – БI, полтавский – РI, линейной плотнос­ти колоса – ЛЩК, плотности колоса – ЩК.Результаты. В период проведения исследований погодные условия отличались от средних многолетних показателей по температурному режиму, количеству атмосферных осадков и их распределению по месяцам. Оптимальные условия вегетационного периода сложились в 2016 г. (ГТК = 1,1), недостаточным уровнем влажности характеризовался 2017 г. (ГТК = 0,2). Это дало возможность установить селекционные индексы для различных условий выращивания пшеницы мягкой и твердой яровой. Анализ полученных данных показал, что IР варьировал как у разных сортов, так и по годам, что свидетельствует о различной реакции генотипов на условия вегетации, сложившиеся в годы выращивания. Высоким показателем FSI характеризовались сорта пшеницы твердой – ‘Славута’ и мягкой яровой – ‘Струна мироновская’. К сортам пшеницы твердой с высоким уровнем МІ отнесены: ‘МИП Магдалена’, ‘МИП Радужная’, ‘Кучумовка’, ‘Харьковская 41’ и мягкой яровой – ‘МИП Злата’, ‘Оксамыт мироновский’, ‘Струна мироновская’, ‘Элегия мироновская’. Самые высокие показатели ЛПК и БІ сорта пшеницы яровой сформировали в 2016 г. РІ был в пределах от 2,3 до 4,5 у сортов пшеницы твердой и от 2,2 до 6,4 – мягкой яровой. Важным в селекции является использование селекционных индексов, которые необходимо включать на основании признаков, имеющих достоверную корреляционную связь с показателями урожайности. Наиболее эффективными для сортов пшеницы твердой яровой в оптимальный год увлажнения (2016) оказались индексы ЩК (r = 0,53±0,08), БІ (r = 0,42±0,08), МІ (r = 0,41±0,08), для мягкой в 2016 и 2017 гг. – РІ (r = 0,39±0,07; r = 0,34±0,07 соответственно). По комплексу селекционных индексов выделены такие сор­та пшеницы мягкой яровой: ‘Струна мироновская’, ‘Симкода мироновская’, ‘МИП Злата’ и твердой: ‘МИП Магдалена’, ‘МИП Райдужная’, ‘Славута’, ‘Кучумовка’.Выводы. Наиболее эффективными для сортов пшеницы твердой яровой были индексы ЩК, БІ, МІ, для мягкой – РІ. Выделенные сорта пшеницы яровой характеризовались оптимальным соотношением исследуемых признаков. | Purpose. To establish the most effective index figures for determination of breeding value of spring wheat genotypes.Methods. Field and statistical ones. Index of prospectivity – IP, Finno-Scandinavian index – FSI, Mexican index – MI, Bila Tserkva index – BI, Poltava index – PI, index of spike linear density – ISLD, index of spike density – ISD were defined.Results. During the investigation period, weather conditions differed from the long-term average annual indices for temperature regime, amount of precipitation and its distribution by month. Conditions of the growing season was the most favorable in 2016 (HTC = 1.1), insufficient level of humidity was specific for 2017 (HTC = 0.2). This allowed to define breeding indices for the soft wheat and spring durum wheat growing under different conditions. The analysis of the obtained data showed that the IP varied both in varieties and over the years, that indicated a various response of genotypes to vegetation conditions that existed during the growing years. Varieties of durum wheat ‘Slavuta’ and soft spring wheat ‘Struna myronivska’ were characterized by the high FSI. Such durum wheat varieties as ‘MIP Magdalena’, ‘MIP Raiduzhna’, ‘Kuchumivka’, ‘Kharkivska 41’, as well as the following soft spring varieties as ‘MIP Zlata’, ‘Oksamyt myronivskyi’, ‘Struna myronivska’, ‘Elehiya myronivska’ had a high level of MI. The spring wheat varieties have the highest indices of LSD and BI in 2016. IP during the investigation period was ranging from 2.3 to 4.5 in durum wheat varieties and from 2.2 to 6.4 in soft spring wheat. In breeding, it is important to use breeding indices, which should be included on the basis of traits that have a reliable correlation with yield index. SD indices (r = 0.53±0.08), BI (r = 0.42±0.08), MI (r = 0.41±0.08) were the most effective for durum spring wheat varieties in the year to be the best for humidification (2016), while PI (r = 0.39±0.07; r = 0.34±0.07 respectively) was the most effective for the soft wheat in 2016 and 2017. For the complex of breeding indices, the varieties of soft spring wheat (‘Struna myronivska’, ‘Simkoda myronivska’, ‘MIP Zlata’) and durum (MIP Mahdalena’, ‘MIP Raiduzhna’, ‘Slavuta’, ‘Kuchumivka’) were defined.Conclusions. The indices SD, BI, MI were the most effective for durum spring wheat varieties and PI – for soft wheat. Selected spring wheat varieties showed the optimum ratio between investigated traits. | Мета. Встановити найефективніші індексні показники для визначення селекційної цінності генотипів пшениці ярої.Методи. Польовий, статистичний. Визначали індекс перспективності – ІР, фіно-скандинавський індекс – FSI, мексиканський – MI, білоцерківський – БІ, полтавський – РІ, лінійної щільності колоса – ЛЩК, щільності колоса – ЩК.Результати. Протягом періоду досліджень погодні умови відрізнялись від середніх багаторічних показників за температурним режимом, кількістю атмосферних опадів та їх розподілом по місяцях. Оптимальні умови вегетаційного періоду склалися у 2016 р. (ГТК = 1,1), недостатнім рівнем вологості характеризувався 2017 р. (ГТК = 0,2). Це дало змогу встановити селекційні індекси для різних умов вирощування пшениці м’якої та твердої ярої. Аналіз отриманих даних показав, що ІР варіював як у різних сортів, так і за роками, що свідчить про різну реакцію генотипів на умови вегетації, які склались у роки вирощування. Високим показником FSI характеризувалися сорти пшениці твердої – ‘Славута’ та м’якої ярої – ‘Струна миронівська’. До сортів пшениці твердої із високим рівнем МІ віднесено: ‘МІП Магдалена’, ‘МІП Райдужна’, ‘Кучумівка’, ‘Харківська 41’, а до м’якої ярої – ‘МІП Злата’, ‘Оксамит миронівський’, ‘Струна миронівська’, ‘Елегія миронівська’. Найвищі показники ЛЩК та БІ сорти пшениці ярої сформували у 2016 р. РІ за період проведених досліджень був у межах від 2,3 до 4,5 у сортів пшениці твердої та від 2,2 до 6,4 – м’якої ярої. Важливим у селекції є використання селекційних індексів, які необхідно включати на підставі ознак, що мають достовірний кореляційний зв’язок з показниками врожайності. Найефективнішими для сортів пшениці твердої ярої в оптимальний рік зволоження (2016) виявились індекси ЩК (r = 0,53±0,08), БІ (r = 0,42±0,08), МІ (r = 0,41±0,08), для м’якої у 2016 і 2017 рр. – РІ (r = 0,39±0,07; r = 0,34±0,07 відповідно). За комплексом селекційних індексів виділено такі сорти пшениці м’якої ярої: ‘Струна миронівська’, ‘Сімкода миронівська’, ‘МІП Злата’ та твердої: ‘МІП Магдалена’, ‘МІП Райдужна’, ‘Славута’, ‘Кучумівка’.Висновки. Найбільш ефективними для сортів пшениці твердої ярої були індекси ЩК, БІ, МІ, для м’якої – РІ. Виділені сорти пшениці ярої характеризувались оптимальним співвідношенням досліджуваних ознак.

Purpose. Assessment and selection of self-pollinated S5 maize (Zea mays L.) families with high combining ability and wide adaptive capacity obtained on the basis of specially produced hybrids by crossing elite lines of various genetic plasms with the best main agronomic characters. Methods. Field studies, mathematico-statistical evaluation. Results. An amplitude of grain yield ranging from 5.96–10.96 t/ha (x = 8.44 t/ha) in 2013 to 2.67–7.59 t/ha (x = 5.08 t/ha) in 2014 was determined in the course of study of the testcrosses of self-pollinated S5 families. It was found that different response of genotypes of the studied testcrosses to the year conditions significantly affected the average yield level, which decreased in the stressful 2014 by 3.4 t/ha as compared to 2013. The results of the assessment based on the general and specific combining ability of new parent material of mixed germplasm were shown. A significant variability of the estimates of GCA (general combining ability) effects depending on the year conditions was observed in the course of study. A marked difference in the estimates of GCA effects based on the grain yield was revealed. They were persistently high in 19% of the best self-pollinated families in both years, 14% of the families had persistently low estimates of GCA effects, 67% changed their value depending on the genotype and year conditions. Conclusions. 17 best self-pollinated families with persistently high estimates of GCA, 6 families featuring high tolerance to drought and 4 families with persistently high variances of SCA were selected. The selected families will be used as a parent material in selection programs aimed to create new high performance hybrids.

Мета. Дослідити формування продуктивності сорту сої культурної ‘Говерла’ за використання різних елементів технології вирощування. Методи. Польові, лабораторні, статистичні (розрахунково­порівняльний, математично­статистичний). Результати. Встановлено ефективність весняного чизелювання за вирощування сої культурної сорту ‘Говерла’ в ґрунтово­кліматичних умовах Прикарпаття. Відзначено позитивний вплив досліджуваних способів обробітку ґрунту на фітосанітарний стан посівів. Зокрема, поєднання зяблевої оранки з весняним чизелюванням за внесення мінеральних добрив N30P30K30 та дворазового позакореневого обприскування посівів регулятором росту зумовило підвищення конкурентоздатності рослин проти бур’янів та знизило чисельність останніх на 46,2%, як порівняти з контролем. Виконання вищевказаних дій також сприяло збільшенню врожайності до 2,48 т/га, або на 57,0%, у середньому за три роки. Водночас зріс вихід кормових одиниць та перетравного протеїну – на 1,35 і 0,3 т/га відповідно. Висновки. Весняне чизелювання разом із зяблевою оранкою та раціональним поєднанням у системі удобрення побічної продукції попередника, запропонованих доз мінеральних добрив і регулятора росту в умовах Прикарпаття сприяли зниженню забур’яненості посівів на 46,2% та підвищенню врожайності сорту сої культурної ‘Говерла’ на 57,0%. | Purpose. To study the formation of the productivity of the ‘Hoverla’ soybean variety using different elements of cultivation technology.  Methods. Field, laboratory, statistical (calculation­comparative, mathematical­statistical). Results. The effectiveness of spring chisel ploughing for the cultivation of the soyabean variety ‘Hoverla’ in the soil and climatic conditions of the  Prykarpattia region was established. The positive effect of the studied tillage methods on the phytosanitary condition of the crop was noted. In particular, the combination of autumn ploughing and spring chisel ploughing with the application of N30P30K30 mineral fertiliser and double foliar spraying of crops with a growth regulator led to an increase in the competitiveness of plants against weeds and reduced the number of weeds by 46.2% compared to the control. The implementation of the above measures also contributed to an increase in yield to 2.48 t/ha, or 57.0% on average over three years. At the same time, the yield of forage units and digestible protein increased by 1.35 and 0.3 t/ha respectively. Conclusions. Spring chisel ploughing, together with autumn ploughing and a rational combination of the predecessor’s by­products, the proposed doses of mineral fertiliser and growth regulator in the conditions of the Prykarpattia region, helped to reduce the weediness of crops by 46.2% and increase the yield of the ‘Ho­verla’ soybean variety by 57.0%.

Purpose. Studying variety samples of winter triticale of various ecological and geographical origin for revealing polymorphism of the culture for its susceptibility to pathogenic complex of Fusarium head blight and defining high-yielding and resistant to diseases varieties that later can be put into the production and breeding process. Methods. Field experiments, statistical evaluation. Results. It was defined that the development of Fusarium head blight in different variety samples of winter triticale depends on the hydrothermal conditions and genotype of the host-plant. Resistance of varieties and hybrids to the disease was partial, and no immune samples were found among the analyzed ones. The following varieties proved to be tolerant to Fusarium head blight: ‘Granat’, ‘Zorro’, ‘Obrii Myronivskyi’. The positive correlation between the development of Fusarium head blight and root rot of winter triticale was found. It was determined that in the pathogenic complex of Fusarium head blight the amount of the following pathogens is increasing: Fusarium sporotrichioides, F. аvenaceum and F. poae. Conclusions. The leading varieties that combine high yields and resistance to Fusarium head blight are as follows: ‘Obrii Myronivskyi’, ‘ADM 8’, ‘Yuvileine Volynske’, ‘Yukon’, ‘Zorro’, ‘Tsekad 90’, ‘Zerniatko’, ‘Legion’ and ‘Rarytet’. These varieties should be involved in the selection process to breed the hybrids with the augmented resistance to the disease and high yields.

Purpose. Studying variety samples of winter triticale of various ecological and geographical origin for revealing polymorphism of the culture for its susceptibility to pathogenic complex of Fusarium head blight and defining high-yielding and resistant to diseases varieties that later can be put into the production and breeding process. Methods. Field experiments, statistical evaluation. Results. It was defined that the development of Fusarium head blight in different variety samples of winter triticale depends on the hydrothermal conditions and genotype of the host-plant. Resistance of varieties and hybrids to the disease was partial, and no immune samples were found among the analyzed ones. The following varieties proved to be tolerant to Fusarium head blight: ‘Granat’, ‘Zorro’, ‘Obrii Myronivskyi’. The positive correlation between the development of Fusarium head blight and root rot of winter triticale was found. It was determined that in the pathogenic complex of Fusarium head blight the amount of the following pathogens is increasing: Fusarium sporotrichioides, F. аvenaceum and F. poae. Conclusions. The leading varieties that combine high yields and resistance to Fusarium head blight are as follows: ‘Obrii Myronivskyi’, ‘ADM 8’, ‘Yuvileine Volynske’, ‘Yukon’, ‘Zorro’, ‘Tsekad 90’, ‘Zerniatko’, ‘Legion’ and ‘Rarytet’. These varieties should be involved in the selection process to breed the hybrids with the augmented resistance to the disease and high yields.

Purpose. To create a multiplex system for identification glyphosate-tolerant sugar beet by using PCR. Methods. Molecular genetic analysis. Results. The article presents the results of studies to determine the parameters of the polymerase chain reaction (PCR) in order to develop a multiplex system for identification of the structural elements of the design of transgenic gene cp 4 epsps, which provides tole­rance to glyphosate. For amplicon target DNA sequences, the following values of temperature conditions of PCR were determined: step 1 (initial denaturation) 95 °C – 3 min; step 2 (specific reaction products accumulation): denaturation 95 °C – 45 s; hybridization of primers 55 °C – 50 s; elongation 72 °C – 1 min; number of cycles – 40; step 3 (final elongation) 72 °C – 6 min. A series of PCR were carried out for the purpose of selecting the optimal amount of DNA matrix for efficient estimate of transgenic sugar beet plants for the presence of specific sequences. Conclusions. To identify transgenic glyphosate-tolerant sugar beet, it is advisable to determine 35S promoter and gene cp 4 epsps in individual genotypes. It was found that during the selection of temperature parameters of multiplex reaction a 5 °C rise in primer hybridization temperature did not affect the identification of gene als that allowed to include specific primers for determination of this sequence as an internal control. Based on the results of test multiplex reactions, concentrations of dNTPs and Mg2+ ions were determined that allowed to exclude the possibility of non-specific fragments and false-negative results. The optimum amount of matrix DNA (100–150 ng) for an efficient estimate of transgenic sugar beet plants for the presence of specific sequences was determined. Obtained results allowed to develop a multiplex test system for identification of transgenic glyphosate-to­lerant sugar beet which can be used for simultaneous determination of the 35S promoter, cp 4 epsps gene and als gene as an internal reaction control.

Purpose. To create a multiplex system for identification glyphosate-tolerant sugar beet by using PCR. Methods. Molecular genetic analysis. Results. The article presents the results of studies to determine the parameters of the polymerase chain reaction (PCR) in order to develop a multiplex system for identification of the structural elements of the design of transgenic gene cp 4 epsps, which provides tole­rance to glyphosate. For amplicon target DNA sequences, the following values of temperature conditions of PCR were determined: step 1 (initial denaturation) 95 °C – 3 min; step 2 (specific reaction products accumulation): denaturation 95 °C – 45 s; hybridization of primers 55 °C – 50 s; elongation 72 °C – 1 min; number of cycles – 40; step 3 (final elongation) 72 °C – 6 min. A series of PCR were carried out for the purpose of selecting the optimal amount of DNA matrix for efficient estimate of transgenic sugar beet plants for the presence of specific sequences. Conclusions. To identify transgenic glyphosate-tolerant sugar beet, it is advisable to determine 35S promoter and gene cp 4 epsps in individual genotypes. It was found that during the selection of temperature parameters of multiplex reaction a 5 °C rise in primer hybridization temperature did not affect the identification of gene als that allowed to include specific primers for determination of this sequence as an internal control. Based on the results of test multiplex reactions, concentrations of dNTPs and Mg2+ ions were determined that allowed to exclude the possibility of non-specific fragments and false-negative results. The optimum amount of matrix DNA (100–150 ng) for an efficient estimate of transgenic sugar beet plants for the presence of specific sequences was determined. Obtained results allowed to develop a multiplex test system for identification of transgenic glyphosate-to­lerant sugar beet which can be used for simultaneous determination of the 35S promoter, cp 4 epsps gene and als gene as an internal reaction control.

Purpose. Review of the main achievements of the Wheat Breeding and Seed ProductionDepartment in the Plant Breeding and Genetic Institute – National Centre of Seed and Cultivar Investigation in the developing theoretical principles of breeding and creation of winter wheat varieties of different types during 100-year (1916–2016) period of breeding programs realization. Results. The main theoretical, methodical developments and breeding achievements of Wheat Breeding and Seed Production Department during 100-year (1916–2016) history have been considered. In the course of the Department activity, the research and metho­dology grounds of bread winter wheat breeding and seed production have been laid, 9 stages of breeding programs development have been accomplished. As a result, more than 130 varieties of different types have been created, 87 of them have been released in some periods or registered in the State registers of plants varieties of Ukraine and other countries and grown in the total sowing area about 220 million hectares.

Мета. Визначення генетичних ефектів ПЖТ 1AL.1RS і 1ВL.1RS на врожайність, елементи продуктивності рослин та показники якості рекомбінантних ліній, установлення ефективності використання кожної з ПЖТ для створення досконаліших за цими ознаками сортів пшениці м’якої озимої в умовах ґрунтово-повітряних посух у степовій зоні України та розроблення селекційних заходівів зменшення негативних ефектів транслокацій для отримання генотипів з високими показниками якості зерна цінної і сильної пшениці. Методи. Польові експерименти, внутрішньовидова гібридизація, оцінювання селекційного матеріалу в польових умовах, методи лабораторного визначення показників хлібопекарських якостей зерна, електрофорез запасних білків, статистичні. Результати. У посушливих умовах Півдня України на великому експериментальному матеріалі селекційного процесу виявлено позитивний вплив ПЖТ 1AL.1RS на врожайність рекомбінантних ліній та основні елементи продуктивності рослин, що проявляється на фоні одночасного позитивного ефекту цієї транслокації на посухо- й жаростійкість. Використання в селекції пшениці ПЖТ 1ВL.1RS у цьому регіоні є менш перспективним заходом. Установлено, що введення шляхом гібридизації в місцевий генофонд пшениці м’якої озимої пшенично-житніх транслокацій 1АL.1RS та 1ВL.1RS змінює показники якості зерна. Зокрема, вміст білка, зазвичай, має тенденцію до підвищення, при цьому він суттєвіше зростає завдяки транслокації 1ВL.1RS. Показано, що частота отримання рекомбінантних ліній, які поєднують високу врожайність та мають добрі хлібопекарські властивості не нижче цінних і сильних пшениць, досить низька (1,7–6,1%). Однак, переваги за цим показником мають інтрогресивні лінії з ПЖТ 1АL.1RS. Використовуючи комбінування в процесі гібридизації ПЖТ з алелями з високим позитивним впливом на хлібопекарські властивості, а також створюючи гетерогенність у складі генотипів з ПЖТ і без них, можна спрямовано зменшувати негативний вплив ПЖТ на якість зерна пшениці м’якої озимої і створювати сорти з параметрами якості цінних і сильних пшениць. Висновки. Отримані результати дають підстави стверджувати, що використання ПЖТ 1AL.1RS є перспективним напрямом подальшого селекційного нарощування генетичного потенціалу врожайності сортів пшениці м’якої озимої в посушливих умовах Півдня України. У результаті повного циклу селекційного процесу на матеріалі з ПЖТ 1АL.1RS, створена серія сортів пшениці м’якої озимої – ‘Житниця одеська’, ‘Октава одеська’, ‘Ліга одеська’, ‘Дума одеська’, ‘Версія одеська’, які забезпечують підвищення врожайності на 10–15% порівняно зі стандартами та занесені до Державних реєстрів сортів рослин України та Молдови.

Мета. Визначення генетичних ефектів ПЖТ 1AL.1RS і 1ВL.1RS на врожайність, елементи продуктивності рослин та показники якості рекомбінантних ліній, установлення ефективності використання кожної з ПЖТ для створення досконаліших за цими ознаками сортів пшениці м’якої озимої в умовах ґрунтово-повітряних посух у степовій зоні України та розроблення селекційних заходівів зменшення негативних ефектів транслокацій для отримання генотипів з високими показниками якості зерна цінної і сильної пшениці. Методи. Польові експерименти, внутрішньовидова гібридизація, оцінювання селекційного матеріалу в польових умовах, методи лабораторного визначення показників хлібопекарських якостей зерна, електрофорез запасних білків, статистичні. Результати. У посушливих умовах Півдня України на великому експериментальному матеріалі селекційного процесу виявлено позитивний вплив ПЖТ 1AL.1RS на врожайність рекомбінантних ліній та основні елементи продуктивності рослин, що проявляється на фоні одночасного позитивного ефекту цієї транслокації на посухо- й жаростійкість. Використання в селекції пшениці ПЖТ 1ВL.1RS у цьому регіоні є менш перспективним заходом. Установлено, що введення шляхом гібридизації в місцевий генофонд пшениці м’якої озимої пшенично-житніх транслокацій 1АL.1RS та 1ВL.1RS змінює показники якості зерна. Зокрема, вміст білка, зазвичай, має тенденцію до підвищення, при цьому він суттєвіше зростає завдяки транслокації 1ВL.1RS. Показано, що частота отримання рекомбінантних ліній, які поєднують високу врожайність та мають добрі хлібопекарські властивості не нижче цінних і сильних пшениць, досить низька (1,7–6,1%). Однак, переваги за цим показником мають інтрогресивні лінії з ПЖТ 1АL.1RS. Використовуючи комбінування в процесі гібридизації ПЖТ з алелями з високим позитивним впливом на хлібопекарські властивості, а також створюючи гетерогенність у складі генотипів з ПЖТ і без них, можна спрямовано зменшувати негативний вплив ПЖТ на якість зерна пшениці м’якої озимої і створювати сорти з параметрами якості цінних і сильних пшениць. Висновки. Отримані результати дають підстави стверджувати, що використання ПЖТ 1AL.1RS є перспективним напрямом подальшого селекційного нарощування генетичного потенціалу врожайності сортів пшениці м’якої озимої в посушливих умовах Півдня України. У результаті повного циклу селекційного процесу на матеріалі з ПЖТ 1АL.1RS, створена серія сортів пшениці м’якої озимої – ‘Житниця одеська’, ‘Октава одеська’, ‘Ліга одеська’, ‘Дума одеська’, ‘Версія одеська’, які забезпечують підвищення врожайності на 10–15% порівняно зі стандартами та занесені до Державних реєстрів сортів рослин України та Молдови. | Purpose. To determine the genetic effects of WRT 1AL.1RS and 1BL.1RS on the yield, plant productivity elements and quality indices of recombinant lines, to determine the effectiveness of using each of the WRT for creating more perfect varieties of soft winter wheat in these traits under soil-air drought in the steppe zone of Ukraine and development of breeding techniques to reduce the negative effects of translocation to produce genotypes with high quality indices of valuable and strong wheat grain. Methods. Field experiments, intraspecific hybridization, evaluation of breeding material in the field, methods of laboratory determination of baking quality indices of grain, electrophoresis of spare proteins, statistical. Results. Under arid conditions of the South of Ukraine on the large experimental material of breeding process, a positive effect of 1AL.1RS on the yield of recombinant lines and the main elements of plant productivity were determined, which was manifested against the background of simultaneous positive effect of this transposition on the drought and heat tolerance. The use of 1BL.1RS in wheat breeding in this region is less promising technique. It has been determined that introduction of 1AL.1RS, 1BL.1RS translocations into local gene pool of soft winter wheat by hybridization changes the grain quality indices. In particular, the protein content tends to increase more significantly under the influence of 1BL.1RS translocation. It has been shown that the frequency of obtaining recombinant lines which combine high yield and sufficient level of baking properties (not lower than valuable and strong wheat) is quite low (1,7–6,1%), but introgressive lines with 1AL.1RS have the advantages in this parameter. Using such genetic factors as hybridization combining WRT with alleles with high positive effect on baking properties, and also creating heterogeneity in the composition of genotypes with and without WRT, one can purposefully reduce the negative impact of WRT on the quality of soft winter wheat grain and create varieties with quality parameters of valuable and strong wheat. Conclusions. In general, the results achieved give reason to assert that the use of WRT 1AL.1RS is a promising direction for further breeding increase of genetic capacity of soft winter wheat varieties in the arid conditions of the South of Ukraine. As a result of full cycle of breeding process on the material with 1AL.1RS WRT a series of varieties of soft winter wheat ‘Zhytnytsia odeska’, ‘Oktava odeska’, ‘Liha odeska’, ‘Duma odeska’, ‘Versiia odeska’, providing 10 – 15% increase in yield to standards was created and included in the State Register of Ukraine and Moldova.

The morphological and agrobiological characteristics and qualities, the potential of the new registered winter wheat varieties, which are suitable for intensive technologies have been learned.

The new rules formulated in Article 59 of the International Code of Nomenclature for algae, fungi, and plants (ICN) will cause numerous, often undesirable, name changes, when only phylogenetically defined clades are named. Our task is to name fungal taxa and not just clades. Two suggestions are made here that may help to alleviate some disadvantages of the new system. (1) Officially an epithet coined in a list-demoted genus that is older than the oldest one available in the list-accepted genus would have to be recombined in the accepted genus. We recommend that individual authors and committees establishing lists of protected names should generally not recombine older epithets from a demoted genus into the accepted genus, when another one from pre-2013 is available in that genus. (2) Because the concepts of correlated teleomorph and anamorph genera are often incongruent, enforced congruence leads to a loss of information. Retaining the most suitable generic name is imperative, even when this is subordinated to another, list-accepted, generic name. Some kind of cryptic dual generic nomenclature is bound to persist. We therefore strongly recommend the retention of binomials in genera where they are most informative. With these recommendations, the upheaval of fungal nomenclature ensuing from the loss of the former Art. 59 can be reduced to an unavoidable minimum.

Purpose. Review of the main achievements of the Wheat Breeding and Seed ProductionDepartment in the Plant Breeding and Genetic Institute – National Centre of Seed and Cultivar Investigation in the developing theoretical principles of breeding and creation of winter wheat varieties of different types during 100-year (1916–2016) period of breeding programs realization. Results. The main theoretical, methodical developments and breeding achievements of Wheat Breeding and Seed Production Department during 100-year (1916–2016) history have been considered. In the course of the Department activity, the research and metho­dology grounds of bread winter wheat breeding and seed production have been laid, 9 stages of breeding programs development have been accomplished. As a result, more than 130 varieties of different types have been created, 87 of them have been released in some periods or registered in the State registers of plants varieties of Ukraine and other countries and grown in the total sowing area about 220 million hectares.

Purpose. Studying and identifying winter wheat varieties that are resistant to causal agents of major diseases and pests. Methods. Laboratory analysis, field study. Results. On artificial infection backgrounds of causal agents such varieties as ‘Smuhlianka’, ‘Svitanok Myronivskyi’, ‘Berehynia Myronіvska’, ‘Horlytsia Myronіvska’ have shown high level of resistance to brown rust; ‘Svitanok Myronivskyi’, ‘Berehynia Myronіvska’ – to powdery mildew; ‘Smuhlianka’ – to covered smut. Varieties ‘Voloshkova’, ‘Yuviliar Myronivskyi’, ‘Myrliena’, ‘Oberih Myronivskyi’, ‘Kolos Myronivschyny’, ‘Lehenda Myronivska’ had medium resistance to Septoria leaf blotch; ‘Smuhlianka’, ‘Myrliena’, ‘Oberih Myronivskyi’, ‘Berehynia Myronіvska’, ‘Horlytsia Myronіvska’, ‘Myronivska storichna’ – to Fusarium head blight; ‘Myronіvska 65’, ‘Smuhlianka’, ‘Lehenda Myronivska’, ‘Berehynia Myronіvska’ – to root rots. Among the varieties studied, there were those with group resistance to diseases: ‘Voloshkova’, ‘Myrliena’, ‘Yuviliar Myronivskyi’, ‘Oberih Myronivskyi’, ‘Bohdana’, ‘Myronivska storichna’, ‘Ekonomka’, ‘Svitanok Myronivskyi’, ‘Berehynia Myronіvska’, ‘Horlytsia Myronіvska’, ‘Smuhlianka’. Varieties bred at the V. M. Remeslo Myronivka Institute of Wheat are distinguished by pest resistance. During autumn tillering phase of winter wheat the smallest number of large cereal aphids was observed in varieties ‘Smuhlianka’ and ‘Myronivska storichna’, leafhoppers – in varieties ‘Smuhlianka’, ‘Myrliena’, ‘Yuviliar Myronivskyi’. The slight population of thrips in the phase of earing was marked in the variety ‘Kolos Myronivschyny’, in the milk-ripe stage the smallest number of larvae per ear was detected in varieties ‘Smuhlianka’, ‘Voloshkova’, ‘Kolos Myronivschyny’. Varieties ‘Lehenda Myronivska’ and ‘Smuhlianka’ were proved to be resistant to damages of stems by sawflies. It should be noted that ‘Smuhlianka’ variety shows resistance to aphids, leafhoppers and grain sawflies. Conclusions. It was established that winter wheat varieties bred at the V. M. Remeslo Myronivka Instutite of Wheat are characterized by resistance to certain causal agents, some of them – to their group. Varieties that are resistant to the most common and harmful phytophages were identified.

Purpose. Studying and identifying winter wheat varieties that are resistant to causal agents of major diseases and pests. Methods. Laboratory analysis, field study. Results. On artificial infection backgrounds of causal agents such varieties as ‘Smuhlianka’, ‘Svitanok Myronivskyi’, ‘Berehynia Myronіvska’, ‘Horlytsia Myronіvska’ have shown high level of resistance to brown rust; ‘Svitanok Myronivskyi’, ‘Berehynia Myronіvska’ – to powdery mildew; ‘Smuhlianka’ – to covered smut. Varieties ‘Voloshkova’, ‘Yuviliar Myronivskyi’, ‘Myrliena’, ‘Oberih Myronivskyi’, ‘Kolos Myronivschyny’, ‘Lehenda Myronivska’ had medium resistance to Septoria leaf blotch; ‘Smuhlianka’, ‘Myrliena’, ‘Oberih Myronivskyi’, ‘Berehynia Myronіvska’, ‘Horlytsia Myronіvska’, ‘Myronivska storichna’ – to Fusarium head blight; ‘Myronіvska 65’, ‘Smuhlianka’, ‘Lehenda Myronivska’, ‘Berehynia Myronіvska’ – to root rots. Among the varieties studied, there were those with group resistance to diseases: ‘Voloshkova’, ‘Myrliena’, ‘Yuviliar Myronivskyi’, ‘Oberih Myronivskyi’, ‘Bohdana’, ‘Myronivska storichna’, ‘Ekonomka’, ‘Svitanok Myronivskyi’, ‘Berehynia Myronіvska’, ‘Horlytsia Myronіvska’, ‘Smuhlianka’. Varieties bred at the V. M. Remeslo Myronivka Institute of Wheat are distinguished by pest resistance. During autumn tillering phase of winter wheat the smallest number of large cereal aphids was observed in varieties ‘Smuhlianka’ and ‘Myronivska storichna’, leafhoppers – in varieties ‘Smuhlianka’, ‘Myrliena’, ‘Yuviliar Myronivskyi’. The slight population of thrips in the phase of earing was marked in the variety ‘Kolos Myronivschyny’, in the milk-ripe stage the smallest number of larvae per ear was detected in varieties ‘Smuhlianka’, ‘Voloshkova’, ‘Kolos Myronivschyny’. Varieties ‘Lehenda Myronivska’ and ‘Smuhlianka’ were proved to be resistant to damages of stems by sawflies. It should be noted that ‘Smuhlianka’ variety shows resistance to aphids, leafhoppers and grain sawflies. Conclusions. It was established that winter wheat varieties bred at the V. M. Remeslo Myronivka Instutite of Wheat are characterized by resistance to certain causal agents, some of them – to their group. Varieties that are resistant to the most common and harmful phytophages were identified.

Purpose. To analyse the Ukrainian nomenclature of subtribe Malinae representatives and improve terminological system of the Ukrainian names of a species and a generic levels and names of fruit crops. Results. There is a confusion in the Ukrainian names of plants of Cydonia-Chaenomeles–Pseudocydonia, Mespilus–Eriobotrya, Amelanchier–Cotoneaster. Considering the division of Sorbus s.l. on separate genera Sorbus s.str., Aria, Cormus, Chamaemespilus, Torminalis and availability of numerous hybrids with their involvement, the Ukrainian names for both taxa and nothotaxa of species and generic levels are offered, principles of their choice are also considered. Formation of the Ukrainian generic names on the basis of specific epithets leads to undesirable tautonomy. Aspects of derussification of the Ukrainian professional terminology are discussed. Conclusions. Ukrainian scientific generic and nothogeneric plant names for subtribe Malinae are transliterated/transcripted, borrowed as a calque of latin names or have their own origin, consisting of one or two words. The choice of the best variants of generic and species names from a number of possible ones has a temporal component and largely depends on experts who apply them and basic principles of choice. It is necessary to improve the modern Ukrainian plant nomenclature on a national basis involving the transformed Latin scientific names for introduced species and hybrids.

Purpose. To analyse the Ukrainian nomenclature of subtribe Malinae representatives and improve terminological system of the Ukrainian names of a species and a generic levels and names of fruit crops. Results. There is a confusion in the Ukrainian names of plants of Cydonia-Chaenomeles–Pseudocydonia, Mespilus–Eriobotrya, Amelanchier–Cotoneaster. Considering the division of Sorbus s.l. on separate genera Sorbus s.str., Aria, Cormus, Chamaemespilus, Torminalis and availability of numerous hybrids with their involvement, the Ukrainian names for both taxa and nothotaxa of species and generic levels are offered, principles of their choice are also considered. Formation of the Ukrainian generic names on the basis of specific epithets leads to undesirable tautonomy. Aspects of derussification of the Ukrainian professional terminology are discussed. Conclusions. Ukrainian scientific generic and nothogeneric plant names for subtribe Malinae are transliterated/transcripted, borrowed as a calque of latin names or have their own origin, consisting of one or two words. The choice of the best variants of generic and species names from a number of possible ones has a temporal component and largely depends on experts who apply them and basic principles of choice. It is necessary to improve the modern Ukrainian plant nomenclature on a national basis involving the transformed Latin scientific names for introduced species and hybrids.

Purpose. To develop and improve adaptive technologies of winter wheat cultivation which provide high productivity and quality of grain. Methods. Field and laboratory stu­dies, mathematical and statistical analysis. Results. During 2011–2015, the impact of cultivation technologies on the formation of grain quality and yield of winter wheat varie­ty ‘Stolychna’ (with pea as predecessor) was studied. When using alternative technologies with only predecessor by-products application, the yield of winter wheat with integ­rated crop protection system was 4,56 t/ha, with minimal protection – 4.25 t/ha with grain quality of the 5th class of B group. Resource saving cultivation technologies with limi­ted application of fertilizers (Р45К45N30(II)+30(IV)) provided productivity at the level of 4,87–5,50 t/ha with grain qua­lity of the 2nd–3rd class of A group. Grain yield of 6.01 t/ha with indicators of the 2nd–3rd class of quality was obtained with the use of intensive cultivation technology with application of mineral fertilizers (Р90К90N30(II)+60(IV)+30(VIII)) on the background of applying predecessor’s by-products and integra­ted crop protection. The highest yield of grain (6.22 t/ha) with indicators of the 2nd class of A group quality on average for the research period was provided by energy-intensive technology, that requires the application of mineral fertilize­rs (P135K135N60(II)+75(IV)+45(VIII)) and incorporation of predecessor’s by-products in the soil, and integrated plant protection. Conclusion. It was found that in the northern part of the Right-Bank Forest-Steppe zone of Ukraine, the highest productivity of winter wheat was obtained in dark grey podzolic soils when using the energy-intensive technology with application of P135K135N60(II)+75(IV)+45(VIII) on the background of predecessor’s by-products and integrated crop protection. This technology ensured the grain yield of 6.22 t/ha of the 2nd class of A group quality.

Purpose. To develop and improve adaptive technologies of winter wheat cultivation which provide high productivity and quality of grain. Methods. Field and laboratory stu­dies, mathematical and statistical analysis. Results. During 2011–2015, the impact of cultivation technologies on the formation of grain quality and yield of winter wheat varie­ty ‘Stolychna’ (with pea as predecessor) was studied. When using alternative technologies with only predecessor by-products application, the yield of winter wheat with integ­rated crop protection system was 4,56 t/ha, with minimal protection – 4.25 t/ha with grain quality of the 5th class of B group. Resource saving cultivation technologies with limi­ted application of fertilizers (Р45К45N30(II)+30(IV)) provided productivity at the level of 4,87–5,50 t/ha with grain qua­lity of the 2nd–3rd class of A group. Grain yield of 6.01 t/ha with indicators of the 2nd–3rd class of quality was obtained with the use of intensive cultivation technology with application of mineral fertilizers (Р90К90N30(II)+60(IV)+30(VIII)) on the background of applying predecessor’s by-products and integra­ted crop protection. The highest yield of grain (6.22 t/ha) with indicators of the 2nd class of A group quality on average for the research period was provided by energy-intensive technology, that requires the application of mineral fertilize­rs (P135K135N60(II)+75(IV)+45(VIII)) and incorporation of predecessor’s by-products in the soil, and integrated plant protection. Conclusion. It was found that in the northern part of the Right-Bank Forest-Steppe zone of Ukraine, the highest productivity of winter wheat was obtained in dark grey podzolic soils when using the energy-intensive technology with application of P135K135N60(II)+75(IV)+45(VIII) on the background of predecessor’s by-products and integrated crop protection. This technology ensured the grain yield of 6.22 t/ha of the 2nd class of A group quality.

Purpose. To select promising high productive maize hyb­rids of middle-early maturity group in terms of stability and plasticity of main economic characters. Methods. Field study, laboratory test, analytical procedure and statistical evaluation. Results. 14 maize hybrids recorded in the State Register of Plant Varieties Suitable for Dissemination in Ukraine in 2015 were studied for plasticity and stability of such traits as productivity, protein and starch content. Intensive highly-plastic hybrid ‘SI Tiptop’ was selected among the studied ones for productivity trait that can respond properly to changes of growing conditions. It was defined that for the starch content such hybrids as ‘SI Tiptop’, ‘SI Enigma’, ‘SI Arioso’, ‘Svich 38’, ‘Svich 35’, ‘HU 8653’, ‘Zdobutok’ and ‘SI Contrakt’ belonged to the intensive type and combined rather high values and the stability of the studied trait under variable conditions. The following hybrids as ‘NS 2642’, ‘DK S3016’, ‘Svich 38’, ‘NS 2632’ were qualified as intensive for protein content and appeared to be highly-plastic but stability values of this trait were low. ‘Svich 38’ hybrid was intensive simultaneously for two traits such as protein and starch content and showed rather high values of plasticity. ‘SI Tiptop’, ‘SI Enigma’ and ‘Svich 35’ were defined as hybrids of extensive type that provided stable protein content in adverse cultivation conditions. Conclusions. On the condition that intensive crop growing technologies should be used, for obtaining stable yields it is advisable to sow only highly-plastic hybrids that can adapt to unfavorable environmental factors, including ‘SI Tiptop’ – for productivity trait, ‘Zdobutok’ and ‘SI Kontrakt’ – for starch content, ‘MAC 24N‘, ‘NA 2642‘ and ‘Danubio’ – for protein content.

Purpose. To select promising high productive maize hyb­rids of middle-early maturity group in terms of stability and plasticity of main economic characters. Methods. Field study, laboratory test, analytical procedure and statistical evaluation. Results. 14 maize hybrids recorded in the State Register of Plant Varieties Suitable for Dissemination in Ukraine in 2015 were studied for plasticity and stability of such traits as productivity, protein and starch content. Intensive highly-plastic hybrid ‘SI Tiptop’ was selected among the studied ones for productivity trait that can respond properly to changes of growing conditions. It was defined that for the starch content such hybrids as ‘SI Tiptop’, ‘SI Enigma’, ‘SI Arioso’, ‘Svich 38’, ‘Svich 35’, ‘HU 8653’, ‘Zdobutok’ and ‘SI Contrakt’ belonged to the intensive type and combined rather high values and the stability of the studied trait under variable conditions. The following hybrids as ‘NS 2642’, ‘DK S3016’, ‘Svich 38’, ‘NS 2632’ were qualified as intensive for protein content and appeared to be highly-plastic but stability values of this trait were low. ‘Svich 38’ hybrid was intensive simultaneously for two traits such as protein and starch content and showed rather high values of plasticity. ‘SI Tiptop’, ‘SI Enigma’ and ‘Svich 35’ were defined as hybrids of extensive type that provided stable protein content in adverse cultivation conditions. Conclusions. On the condition that intensive crop growing technologies should be used, for obtaining stable yields it is advisable to sow only highly-plastic hybrids that can adapt to unfavorable environmental factors, including ‘SI Tiptop’ – for productivity trait, ‘Zdobutok’ and ‘SI Kontrakt’ – for starch content, ‘MAC 24N‘, ‘NA 2642‘ and ‘Danubio’ – for protein content.