Purpose. To determine morphological and morphometric features of vegetative and generative organs of Persica species and varieties under the conditions of the Forest-Steppe zone of Ukraine for further use in breeding. Methods. Biological (morphological analysis) and statistical (processing of morphometric parameters) ones. Results. It was found that except ternate multiple buds, in peach hybrid ‘Suputnyk’collateral buds were prevalent which was not common to other tested varieties and species. Buds of each species and variety have a certain number of scales. The most scales were observed in ‘Suputnyk’. Pubescence of abaxial side of the leaf in P. davіdiana and ‘Suputnyk’ plants was not revealed. Species of P. vulgaris (‘Pecherskyi’, ‘Antotsianovyi’, ‘Poleskyi’) was characterized by increase in size of leaf blades, flowers and fruits. The distinctive features of P. davidiana and ‘Suputnyk’ are that stamens were accumulated in their flowers while in P. vulgaris they are branched. Raphe of a P. vulgaris stone protrudes above the edges of the bordering creases and consists of a number of narrow plates. Conclusions. For the breeding purposes, plants have an advantage for some basic criteria: the most flower buds that is common to interspecies hybrid ‘Suputnyk’; increase in photosynthetic productivity of the leaf apparatus to be typical for the variety ‘Pecherskyi’; large fruits that ‘Pecherskyi’ variety is noted for; intense red color of fruits that is inherent feature of ‘Antocianovyi’ variety.

The symposium “One fungus = Which name” held in Amsterdam 12–13 April 2012, addressed the drastic changes in the naming of pleomorphic fungi adopted by the 18th International Botanical Congress in Melbourne in 2011. Possible solutions and ways to face resulting problems were suggested. The fundamental change is that under the new rules fungi in future will be treated nomenclaturally like plants and all other groups of organisms ruled by the ICN, i.e. with one correct name for each species. Numerous discussions and statements during the Symposium reflected widespread anxieties that these rules could negatively influence taxonomic work on pleomorphic fungi. However, they are groundless, being based on misunderstandings and confusion of nomenclature and taxonomy. With pleomorphic fungi, taxonomists will in future have to answer the question whether different morphs can represent one fungus (taxon), but this remains a taxonomic decision and has nothing to do with nomenclature. Furthermore, the ICN does not and cannot rule on how this decision is made. Thus it cannot provide rules based solely on methods involving morphology in vivo or in vitro, molecular analyses, physiological and biochemical data, inoculation experiments in pathogenic groups or any other methods or combinations of them. It is up to the taxonomist to select appropriate methods and to decide which data are sufficient to introduce new taxa. Some future problems and strategies around the application of anamorph- and teleomoph-typified taxon names (genera and species), arediscussed here, using the recently monographed powdery mildews (Erysiphales) as an example.

Purpose. To review publications relating to the key point of the genotyping technology that is competitive allele-specific polymerase chain reaction (which is called now Kompetitive Allele Specific PCR, KASPTM) and its use in various genetic-breeding researching (a study of maize). Results. The essence of KASP-genotyping, its advantages are highlighted. The requirements for matrix DNA are presented, since the success of the KASP-analysis depends on its qua­lity and quantity. Examples of global projects of plant breeding for increasing crop yields using the KASP genoty­ping technology are given. The results of KASP genotyping and their introduction into breeding and seed production, in particular, for determining genetic identity, genetic purity, origin check, marker-assisted selection, etc. are presented using maize as an example. It is demonstrated how geno­mic selection according to KASP genotyping technology can lead to rapid genetic enhancement of drought resistance in maize. Comparison of the effectiveness of creating lines with certain traits (for example, combination of high grain yield and drought resistance) using traditional breeding approaches (phenotype selection) and molecular genetic methods (selection by markers) was proved that it takes four seasons (two years in case of greenhouses) in order to unlock the potential of the plant genotype using traditional self-pollination, test-crossing and definitions), while using markers, the population was enriched with target alleles during one season. At the same time, there was no need for a stress factor. Conclusions. KASP genotyping technology is a high-precision and effective tool for modern genetics and breeding, which is successfully used to study genetic diversity, genetic relationship, population structure, gene­tic identity, genetic purity, origin check, quantitative locus mapping, allele mapping, marker-assisted selection, marker-assisted breeding. It is expedient and timely to introduce KASP genotyping technology in our country to solve a wide range of modern genetics, breeding, seed production tasks.

Purpose. To review publications relating to the key point of the genotyping technology that is competitive allele-specific polymerase chain reaction (which is called now Kompetitive Allele Specific PCR, KASPTM) and its use in various genetic-breeding researching (a study of maize). Results. The essence of KASP-genotyping, its advantages are highlighted. The requirements for matrix DNA are presented, since the success of the KASP-analysis depends on its qua­lity and quantity. Examples of global projects of plant breeding for increasing crop yields using the KASP genoty­ping technology are given. The results of KASP genotyping and their introduction into breeding and seed production, in particular, for determining genetic identity, genetic purity, origin check, marker-assisted selection, etc. are presented using maize as an example. It is demonstrated how geno­mic selection according to KASP genotyping technology can lead to rapid genetic enhancement of drought resistance in maize. Comparison of the effectiveness of creating lines with certain traits (for example, combination of high grain yield and drought resistance) using traditional breeding approaches (phenotype selection) and molecular genetic methods (selection by markers) was proved that it takes four seasons (two years in case of greenhouses) in order to unlock the potential of the plant genotype using traditional self-pollination, test-crossing and definitions), while using markers, the population was enriched with target alleles during one season. At the same time, there was no need for a stress factor. Conclusions. KASP genotyping technology is a high-precision and effective tool for modern genetics and breeding, which is successfully used to study genetic diversity, genetic relationship, population structure, gene­tic identity, genetic purity, origin check, quantitative locus mapping, allele mapping, marker-assisted selection, marker-assisted breeding. It is expedient and timely to introduce KASP genotyping technology in our country to solve a wide range of modern genetics, breeding, seed production tasks.

Purpose. To define morphological peculiarities of the different types of shoots of switch grass (Panicum virgatum L.) in the context of introduction in the Right-Bank Forest-Steppe and Polissia zones of Ukraine. Methods. Morpho-physiological and ontogenetic analysis, morphometric technique, statistical evaluation. Results. It was found that P. virgatum plants were producing the following types of shoots: vegetative-generative short or long rhizomatous ones (they appeared as in the underground part of a maternal shoot in «the area of shortened internodes» and in the base of its aboveground part); vegetative underground and aboveground ones (they are forming both in the axils of scales of the underground part of a maternal shoot and in the axils of cauline leaves); generative aboveground shoots (borne in the axil of cauline leaves). Morphological parameters and features of morphogenesis of reproduction, resting and secondary buds have been described. Conclusions. During flowering phase of maternal shoot, P. virgatum reproduction buds were on the organogenesis phase I–II, their bursting occured after maternal shoot has flowered. The correlation of internodes length, leave blades and sheaths has been established. The maximum values of the above parameters were observed in the middle part of the prefloral zone of the stem. In the context of introduction, panicle earing came in the third decade of July, flowering began in the first decade of August. It was revealed that complete flowers are bloomed faster than the staminate ones.

Purpose. To define morphological peculiarities of the different types of shoots of switch grass (Panicum virgatum L.) in the context of introduction in the Right-Bank Forest-Steppe and Polissia zones of Ukraine. Methods. Morpho-physiological and ontogenetic analysis, morphometric technique, statistical evaluation. Results. It was found that P. virgatum plants were producing the following types of shoots: vegetative-generative short or long rhizomatous ones (they appeared as in the underground part of a maternal shoot in «the area of shortened internodes» and in the base of its aboveground part); vegetative underground and aboveground ones (they are forming both in the axils of scales of the underground part of a maternal shoot and in the axils of cauline leaves); generative aboveground shoots (borne in the axil of cauline leaves). Morphological parameters and features of morphogenesis of reproduction, resting and secondary buds have been described. Conclusions. During flowering phase of maternal shoot, P. virgatum reproduction buds were on the organogenesis phase I–II, their bursting occured after maternal shoot has flowered. The correlation of internodes length, leave blades and sheaths has been established. The maximum values of the above parameters were observed in the middle part of the prefloral zone of the stem. In the context of introduction, panicle earing came in the third decade of July, flowering began in the first decade of August. It was revealed that complete flowers are bloomed faster than the staminate ones.

Мета. Виявити закономірності рівня прояву врожайності сортів ячменю ярого у взаємодії «генотип–середовище» за випробування в різних екологічних зонах України та виділити генотипи з підвищеним адаптивним потенціалом. Методи. Об’єкт досліджень – 36 сортів ячменю ярого вітчизняної та зарубіжної селекції. Сортовипробування проведено в Миронівському інституті пшениці імені В. М. Ремесла НААН України (МІП) (Центральний Лісостеп) у 2015–2017 рр., на Носівській селекційно-дослідній станції МІП (НСДС) (Полісся) та на Кіровоградській державній сільськогосподарській дослідній станції НААН (КДСГДС) (Північний Степ) у 2016–2017 рр. За три роки досліджень (2015–2017) отримано результати випробування сортів у семи середовищах. Ділянки обліковою площею 10 м2 закладали у триразовій повторності методом повних рендомізованих блоків, відповідно до загальноприйнятих методик. Статистичний аналіз експериментальних даних проведено з використанням комп’ютерних програм Excel 2010 і Statistica 8.0. Для наочної інтерпретації взаємодії «генотип–середовище» використано GGE biplot модель. Результати. Дисперсійний аналіз даних урожайності засвідчив достовірні внески у загальну варіацію середовища – 64,64%, гено­типу – 14,90% та їх взаємодії – 20,46%. Найвищою диференціювальною здатністю (інформативністю) характеризувались умови МІП у 2016 р., найнижчою – умови КДСГДС у 2017 р. Найбільш репрезентативними були умови МІП у 2017 р. і НСДС у 2016 р., найменш репрезентативними – у КДСГДС (2016 р.). Найвіддаленішими між собою були умови МІП та KДСГДС у 2016 р. Візуалізація GGE biplot «хто-де-переміг» дала змогу розподілити середовища на два сектори: перший – умови МІП 2015–2017 рр. і НСДС 2016–2017 рр., другий – умови КДСГДС 2016–2017 рр. У першому секторі суттєву перевагу мав сорт ‘МІП Мирний’, у другому – сорт ‘Скарб’. Диференційовано й виділено сорти ячменю ярого з оптимальним рівнем прояву врожайності в середовищах, найближчих до гіпотетичного «ідеального» генотипу GGE biplot моделі – ‘МІП Мирний’, ‘МІП Богун’, ‘Талісман Миронівський’, ‘МІП Азарт’, ‘Доказ’, ‘Пан’. Висновки. Моделювання багатосередовищних сортовипробувань шляхом комбінування контрастних за гідротермічним режимом років і різних екологічних умов з інтерпретацією результатів досліджень за сучасними статистично-графічними методами сприяє детальнішій характеристиці взаємодії «генотип–середовище», ранжируванню і виділенню перспективних генотипів.

Цель. Выявить закономерности уровня проявления урожайности сортов ячменя ярового во взаимодействии «генотип–среда» при испытании в разных экологичес­ких зонах Украины и выделить генотипы с повышенным адаптивным потенциалом.Методы. Объект исследований – 36 сортов ячменя ярового отечественной и зарубежной селекции. Сортоиспытания проведены в Мироновском институте пшеницы имени В. Н. Ремесло НААН Украины (МИП) (Центральная Лесостепь) в 2015–2017 гг., на Носовской селекционно-опытной станции МИП (НСОС) (Полесье) и Кировоградской государственной сельскохозяйственной опытной станции НААН (КГСХОС) (Северная Степь) в 2016–2017 гг. За три года исследований (2015–2017) получены результаты испытания сортов в семи средах. Делянки учетной площадью 10 м2 были заложены в трёхкратной повторности методом полных рендомизированных блоков, в соответствии с общепринятыми методиками. Статистический анализ экспериментальных данных проведен с использованием компьютерных программ Excel 2010 и Statistica 8.0. Для наглядной интерпретации взаимодействия «генотип–среда» использована GGE biplot модель.Результаты. Дисперсионный анализ данных урожайности засвидетельствовал достоверные вклады в общую вариацию среды – 64,64%, генотипа – 14,90% и их взаимодействия – 20,46%. Самой большой дифференцирующей способностью (информативностью) характеризировались условия МИП в 2016 г., наименьшей – условия КГСХОС в 2017 г. Наиболее репрезентативными были условия МИП в 2017 г. и НСХОС в 2016 г., наименее – в КГСХОС (2016 г.). Наиболее отдаленными между собой были условия МИП и КГСХОС в 2016 г. Визуализация GGE biplot «кто-где-победил» позволила разделить среды на два секторы: первый – условия МИП 2015–2017 гг. и НСОС 2016–2017 гг., второй – условия КГСХОС 2016–2017 гг. В первом секторе существенно превалировал сорт ‘МИП Мирный’, во втором – ‘Скарб’. Дифференцированы и выделены сорта ячменя ярового с наиболее оптимальным уровнем проявления урожайности в средах, наиболее близких к гипотетическому «идеальному» генотипу GGE biplot модели – ‘МИП Мирный’, ‘МИП Богун’, ‘Талисман Мироновский’, ‘МИП Азарт’, ‘Доказ’, ‘Пан’. Выводы. Моделирование многосредовых сортоиспытаний путем комбинирования контрастных по гидротермическим режимам годов и различных экологических условий с интерпретацией результатов исследований в соответствии с современными статистическо-графическими методами способствует более детальной характеристике взаимодействия «генотип–среда», ранжированию и выделению перспективных генотипов. | Purpose. To define the regularities of yield level for spring barley varieties in “genotype–environment” interaction when testing in different ecological zones environments of Ukraine and identify genotypes with increased adaptive potential. Methods. As object of the research there were 36 spring barley varieties of domestic and foreign breeding. Varieties were tested at the V. M. Remeslo Myronivka Institute of Wheat of NAAS (MIW) (the Central Forest-Steppe) in 2015–2017, at Nosivka Plant Breeding Experimental Station of the V. M. Remeslo Myronivka Institute of Wheat of NAAS (NPBES) (Polissia) in 2016–2017 and at Kirovohrad State Agricultural Experimental Station of NAAS (KSAES) (the Northern Steppe) in 2016–2017. During three years of the investigation (2015–2017), the results of varieties testing in seven environments have been obtained. Plots with discount area of 10 m2 were laid out with three replications by the method of full randomized blocks, in accordance with conventional methods. Statistical analysis of experimental data was performed using Excel 2010 and Statistica 8.0 software. To interpret visually “genotype-environment” interaction the GGE biplot model was used. Results. The ANOVA of yield data showed reliable contributions into the total variation of environment (64.64%), genotype (14.90%), and their interaction (20.46%). Environmental conditions of MIW in 2016 were characterized with the highest discriminative fineness (informativeness), while KSAES in 2017 were characterized with the lowest one. Environmental conditions of both MIW in 2017 and NPBES in 2016 were the most representative; conditions of KSAES in 2016 were the least representative. The conditions of MIW and KSSGDS in 2016 were the most distant against each other. The GGE biplot “who-won-where” vizualization allowed to divide the environments in two sectors: the first – conditions of MIW 2015–2017 and NPBES 2016–2017, the second – conditions of KSAES 2016–2017. The variety ‘MIP Myrnyi’ had a significant advantage in the first sector, while the variety ‘Skarb’ had it in the second one. The varieties of spring barley ‘MIP Myrnyi’, ‘MIP Bohun’, ‘Talisman Myronivskyi’, ‘MIP Azart’, ‘Dokaz’, ‘Pan’ have been differen­tiated and defined as those with the optimal level of yield in environments being the closest to hypothetical “ideal” genotype of the GGE biplot model. Conclusions. Modelling of integrated variety testing by combining years being contrast in hydrothermal regime and different ecological conditions with interpretation of the investigation results using modern statistical and graphical method contributes to more detailed characterization of the “genotype–environment” interaction, ranking and identifying of prospecting genotypes. | Мета. Виявити закономірності рівня прояву врожайності сортів ячменю ярого у взаємодії «генотип–середовище» за випробування в різних екологічних зонах України та виділити генотипи з підвищеним адаптивним потенціалом.Методи. Об’єкт досліджень – 36 сортів ячменю ярого вітчизняної та зарубіжної селекції. Сортовипробування проведено в Миронівському інституті пшениці імені В. М. Ремесла НААН України (МІП) (Центральний Лісостеп) у 2015–2017 рр., на Носівській селекційно-дослідній станції МІП (НСДС) (Полісся) та на Кіровоградській державній сільськогосподарській дослідній станції НААН (КДСГДС) (Північний Степ) у 2016–2017 рр. За три роки досліджень (2015–2017) отримано результати випробування сортів у семи середовищах. Ділянки обліковою площею 10 м2 закладали у триразовій повторності методом повних рендомізованих блоків, відповідно до загальноприйнятих методик. Статистичний аналіз експериментальних даних проведено з використанням комп’ютерних програм Excel 2010 і Statistica 8.0. Для наочної інтерпретації взаємодії «генотип–середовище» використано GGE biplot модель.Результати. Дисперсійний аналіз даних урожайності засвідчив достовірні внески у загальну варіацію середовища – 64,64%, гено­типу – 14,90% та їх взаємодії – 20,46%. Найвищою диференціювальною здатністю (інформативністю) характеризувались умови МІП у 2016 р., найнижчою – умови КДСГДС у 2017 р. Найбільш репрезентативними були умови МІП у 2017 р. і НСДС у 2016 р., найменш репрезентативними – у КДСГДС (2016 р.). Найвіддаленішими між собою були умови МІП та KДСГДС у 2016 р. Візуалізація GGE biplot «хто-де-переміг» дала змогу розподілити середовища на два сектори: перший – умови МІП 2015–2017 рр. і НСДС 2016–2017 рр., другий – умови КДСГДС 2016–2017 рр. У першому секторі суттєву перевагу мав сорт ‘МІП Мирний’, у другому – сорт ‘Скарб’. Диференційовано й виділено сорти ячменю ярого з оптимальним рівнем прояву врожайності в середовищах, найближчих до гіпотетичного «ідеального» генотипу GGE biplot моделі – ‘МІП Мирний’, ‘МІП Богун’, ‘Талісман Миронівський’, ‘МІП Азарт’, ‘Доказ’, ‘Пан’.Висновки. Моделювання багатосередовищних сортовипробувань шляхом комбінування контрастних за гідротермічним режимом років і різних екологічних умов з інтерпретацією результатів досліджень за сучасними статистично-графічними методами сприяє детальнішій характеристиці взаємодії «генотип–середовище», ранжируванню і виділенню перспективних генотипів.

Purpose. To study the effect of weather conditions on grain quality in soft spring wheat lines that are undergoing competitive variety trial. To identify indices to be least affected by weather conditions. To investigate the correlation dependence between grain quality indices in the years with contrasting weather conditions and conduct the analysis of variance. Methods. Parameters of grain and flour quality of bread spring wheat lines were determined using conventional methods at the laboratory of grain quality of V. M. Remeslo Myronivka Institute of Wheat, NAAS of Ukraine, protein content in flour was measured with the use of the SPECTRAN 119M device. Results. Contrasting weather conditions were considered including arid ones (2013) – that had negative effect on 1000 kernel weight, but at the same time positively influenced the averaged grain quality indices; with excess humidity (2014) – they resulted in decreasing of all technological indices; optimal ones (2015) – allowed to obtain maximum indices of grain and flour quality. Paired coefficients of correlation between different para­meters of grain and flour quality were calculated. The most number of strong and medium correlations was found in a dry year (33.3%), the smallest one – in a wet year (13.0%). Such indices as flour strength, dough dilution and protein content depended on the conditions of the growing year least of all. Grain-unit response was the most considerable to the humid conditions of the year. The analysis of variance showed that climatic conditions had significant effect on the quality indices of grain and flour. At the same time, an important genotypic component was revealed in indices of dough resilience (63%), bread volume and rating (61 and 53% respectively), the flour strength (42%), crude gluten quality (33%), bread porosity (30%). With climate variations, the genotypic conditionality of the content of protein and especially crude gluten was expressed insignificantly. Conclusions. When creating high quality cultivars, plant breeders should be guided by such indices as flour strength, dough resilience, gluten quality, bread volume and rating as only they are more genetically determined

Purpose. To study the effect of weather conditions on grain quality in soft spring wheat lines that are undergoing competitive variety trial. To identify indices to be least affected by weather conditions. To investigate the correlation dependence between grain quality indices in the years with contrasting weather conditions and conduct the analysis of variance. Methods. Parameters of grain and flour quality of bread spring wheat lines were determined using conventional methods at the laboratory of grain quality of V. M. Remeslo Myronivka Institute of Wheat, NAAS of Ukraine, protein content in flour was measured with the use of the SPECTRAN 119M device. Results. Contrasting weather conditions were considered including arid ones (2013) – that had negative effect on 1000 kernel weight, but at the same time positively influenced the averaged grain quality indices; with excess humidity (2014) – they resulted in decreasing of all technological indices; optimal ones (2015) – allowed to obtain maximum indices of grain and flour quality. Paired coefficients of correlation between different para­meters of grain and flour quality were calculated. The most number of strong and medium correlations was found in a dry year (33.3%), the smallest one – in a wet year (13.0%). Such indices as flour strength, dough dilution and protein content depended on the conditions of the growing year least of all. Grain-unit response was the most considerable to the humid conditions of the year. The analysis of variance showed that climatic conditions had significant effect on the quality indices of grain and flour. At the same time, an important genotypic component was revealed in indices of dough resilience (63%), bread volume and rating (61 and 53% respectively), the flour strength (42%), crude gluten quality (33%), bread porosity (30%). With climate variations, the genotypic conditionality of the content of protein and especially crude gluten was expressed insignificantly. Conclusions. When creating high quality cultivars, plant breeders should be guided by such indices as flour strength, dough resilience, gluten quality, bread volume and rating as only they are more genetically determined

Purpose. To analyze the Ukrainian names of the fruit crops which varieties are undergoing scientific and technical examination. Results. Names of fruit crops form a separate terminological system based on one-word fruit plant names. Names of new introduced fruit crops usually are borrowed from the language of that country where the crop has extended and whence it has spread, or on the basis of a Latin generic name. Conclusions. The registered varieties of fruit plants in Ukraine belong to 48 crops. Formation of names of fruit crops has begun in ancient times and is continuing until now. Crop names, as a rule, consist of one word; two-word names occur as an exception, if so, an adjective should be places ahead of a noun. Names of fruit crops and the name of botanic taxa are specific, belong to different terminological systems and perform different functions.

Purpose. To analyze the Ukrainian names of the fruit crops which varieties are undergoing scientific and technical examination. Results. Names of fruit crops form a separate terminological system based on one-word fruit plant names. Names of new introduced fruit crops usually are borrowed from the language of that country where the crop has extended and whence it has spread, or on the basis of a Latin generic name. Conclusions. The registered varieties of fruit plants in Ukraine belong to 48 crops. Formation of names of fruit crops has begun in ancient times and is continuing until now. Crop names, as a rule, consist of one word; two-word names occur as an exception, if so, an adjective should be places ahead of a noun. Names of fruit crops and the name of botanic taxa are specific, belong to different terminological systems and perform different functions.

Purpose. To determine morphological and morphometric features of vegetative and generative organs of Persica species and varieties under the conditions of the Forest-Steppe zone of Ukraine for further use in breeding. Methods. Biological (morphological analysis) and statistical (processing of morphometric parameters) ones. Results. It was found that except ternate multiple buds, in peach hybrid ‘Suputnyk’collateral buds were prevalent which was not common to other tested varieties and species. Buds of each species and variety have a certain number of scales. The most scales were observed in ‘Suputnyk’. Pubescence of abaxial side of the leaf in P. davіdiana and ‘Suputnyk’ plants was not revealed. Species of P. vulgaris (‘Pecherskyi’, ‘Antotsianovyi’, ‘Poleskyi’) was characterized by increase in size of leaf blades, flowers and fruits. The distinctive features of P. davidiana and ‘Suputnyk’ are that stamens were accumulated in their flowers while in P. vulgaris they are branched. Raphe of a P. vulgaris stone protrudes above the edges of the bordering creases and consists of a number of narrow plates. Conclusions. For the breeding purposes, plants have an advantage for some basic criteria: the most flower buds that is common to interspecies hybrid ‘Suputnyk’; increase in photosynthetic productivity of the leaf apparatus to be typical for the variety ‘Pecherskyi’; large fruits that ‘Pecherskyi’ variety is noted for; intense red color of fruits that is inherent feature of ‘Antocianovyi’ variety.

Abstract One of the most promising aquaculture species is the Atlantic bluefin tuna (Thunnus thynnus) with high market value; disease control is crucial to prevent and reduce mortality and monetary losses. Microsporidia (Fungi) are a potential source of damage to bluefin tuna aquaculture. A new microsporidian species is described from farmed bluefin tunas from the Spanish Mediterranean. This new pathogen is described in a juvenile associated with a highly severe pathology of the visceral cavity. Whitish xenomas from this microsporidian species were mostly located at the caecal mass and ranged from 0.2 to 7.5 mm. Light and transmission electron microscopy of the spores revealed mature spores with an average size of 2.2 × 3.9 μm in size and a polar filament with 13–14 coils arranged in one single layer. Phylogenetic analysis clustered this species with the Glugea spp. clade. The morphological characteristics and molecular comparison confirm that this is a novel microsporidian species, Glugea thunni. The direct life-cycle and the severe pathologies observed makes this parasite a hard risk for bluefin tuna cultures.

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.

Цель. Выявить биологические особенности роста и развития растений и формирования посадочного материала мискантуса гигантского в зависимости от элементов технологии выращивания.Методы. Полевой, лабораторный, визуальный, измерительно-весовой и математико-статистический. Результаты. Исследованы особенности роста и развития биоэнергетической культуры мискантуса, формирования посадочного материала в зависимости от комплексного применения элементов технологии, а именно: сроков посадки, массы ризом, а также гранул и геля абсорбента MaxiMarin в период посадки. Установлено, что прирост высоты растений, увеличение площади листьев и формирование стеблей мискантуса зависели как от сроков посадки ризом, их величины, так и от применения абсорбента. За трёхлетний период прирост высоты растений был более интенсивным, а площадь листовой поверхности – наибольшей при применении абсорбента по сравнению с контролем во всех фазах развития и при обоих сроках посадки независимо от массы ризом. В среднем наибольшей – 1905,9 см3 – площадь листовой поверхности была на период окончания вегетации при втором сроке посадки крупных ризом при совместном использовании гранул и геля абсорбента. Увеличение наземной массы за счет высоты растений, площади листовой поверхности и количества стеблей способствовало повышению продуктивности фотосинтеза и влияло не только на урожайность культуры, но и на увеличение корневой системы выхода посадочного материала мискантуса. Установлены прямые сильные корреляционные связи между этими показателями и массой корневища. С нарастанием наземной массы увеличенивалась масса корневища и, соответственно, выход посадочного материала – ризом. При совместном внесении гранул и использовании геля абсорбента прирост наземной массы был наиболее интенсивным и, соответственно, наибольшей была масса корневища: при первом сроке посадки малых ризом – вдвое, при посадке больших ризом – в 2,4 раза больше, чем на контроле и составляла 1090,5 г, при посадке малых ризом – 2,4 раза и 1763,9 г соответственно. При втором сроке совместное использование гранул и геля абсорбента обеспечило увеличение массы корневища при посадке малых ризом в 1,9 раза, больших – в 2,1 раза по сравнению с контролем.Выводы. Между интенсивностью нарастания наземной массы – высотой растений, количеством листьев, площадью листовой поверхности, количеством почек и массой корневища выявлены прямые сильные корреляционные связи. Нарастание наземной массы растений способствовало увеличению корневой системы – выходу посадочного материала. Во всех фазах развития растений нарастание массы корневища было интенсивнее при использовании абсорбента, независимо от сроков посадки ризом, по сравнению с контролем. Совместное использование гранул и геля абсорбента обеспечило формирование наибольшей массы корневища. | 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. | Мета. Виявити біологічні особливості росту й розвитку рослин та формування садивного матеріалу міскантусу гігантського залежно від елементів технології вирощування.Методи. Польовий, лабораторний, візуальний, вимі­рювально-ваговий, математично-статистичний.Результати. Досліджено особливості росту й розвитку біоенергетичної культури міскантусу, формування садивного матеріалу залежно від комплексного застосування елементів технології, а саме: строків висаджування, маси ризом, гранул і гелю абсорбенту MaxiMarin у період садіння. Встановлено, що приріст висоти рослин, збільшення площі листків та формування стебел міскантусу залежали як від строків садіння ризом, їх величини, так і від застосування абсорбенту. За трирічний період приріст висоти рослин був інтенсивнішим, а площа листкової поверхні – найбільшою у разі застосування абсорбенту, порівняно з контролем у всіх фазах розвитку за обох строків садіння незалежно від маси ризом. У середньому найбільша площа листкової поверхні – 1905,9 см3 – була на період закінчення вегетації за другого строку садіння великих ризом за спільного використання гранул та гелю абсорбенту. Збільшення наземної маси за рахунок висоти рослин, площі листкової поверхні та кількості стебел сприяло підвищенню продуктивності фотосинтезу, що впливало на збільшення кореневої системи – виходу садивного матеріалу міскантусу. Виявлено прямі сильні кореляційні зв’язки між цими показниками та масою кореневища. З наростанням наземної маси збільшувалася маса кореневища, а відповідно й вихід садивного матеріалу – ризом. За спільного внесення гранул і використання гелю абсорбенту найінтенсивніше наростала наземна маса рослин і, відповідно, найбільшою була маса кореневища: в перший строк садіння малих ризом вдвічі більшою, ніж на контролі та становила 1090,5 г, за садіння великих ризом – у 2,4 раза та 1763,9 г відповідно. За другого строку спільне застосування гранул і гелю абсорбенту забезпечило збільшення маси кореневища за садіння малих ризом у 1,9, великих – у 2,1 раза порівняно з контролем.Висновки. Між інтенсивністю наростання наземної маси – висотою рослин, кількістю листків, площею листкової поверхні, кількістю бруньок і масою кореневища виявлено прямі сильні кореляційні зв’язки. Наростання наземної маси рослин сприяло збільшенню кореневої системи – виходу садивного матеріалу. У всіх фазах розвитку рослин наростання маси кореневища було інтенсивнішим у разі використання абсорбенту, незалежно від строків садіння ризом, порівняно з контролем. Спільне використання гранул і гелю абсорбенту забезпечило формування найбільшої маси кореневища.

The analysis of the structure of State Register of Plant Varieties Suitable for Dissemination in Ukraine is presented. The descriptions of new lupine's varieties important for economic use are given. The state of new varieties introduction in production and ways of improving of the soil fertility with a low humus content and the overcoming of crisis in the forage sphere are shown.

Purpose. To study Ukrainian potato market at the current stage of the development and determine its future prospects. Results. The features of Ukrainian potato market were determined. Production is almost fully provided by private households, meeting the needs of the domestic market. Main regions with the highest gross output and production of potatoes were defined. Ukraine is one of the major potato producing countries in the world. Today our country is not a key supplier or importer of this product because of the low export orientation of the industry, its technological backwardness, limited product range and the large number of small producers. Ukraine exports potato mainly to CIS countries, the highest share of potato import comes from the European Union. Now there are only a few large manufacturing companies in the market, which can be classified as industrial. Most potato varieties, officially permitted for dissemination in Ukraine, are classified as table ones and recommended for cultivation in the Forest-Steppe and Polissia zones. Achievements of the industry include the development of such very popular and promising trend as organic potato growing, which area in our country is one of the largest in the world. Conclusions. Potato produced in Ukraine is used for human consumption, animal feeding, planting and processing, its volumes are relatively stable. Large-scale industrial production of potato is not widely practiced because of low wholesale prices and high labor intensity of the cultivation process. During next few years, in view of current trends, production of potato and severe limitations of the domestic market for foreign operations will remain unchanged. A shift in emphasis in the product range – from fresh potato to processed food products should be a prospect for domestic industrial producers to improve their position in Ukraine and abroad.

Abstract Forests are a natural source of airborne bolete spores. The timing of sporulation and its intensity as well as the dispersal of airborne spores and in consequence their concentrations depend in particular on the type of land use determining the availability of matter on which they develop and on meteorological factors. The aim of this study was to perform a spatial and temporal analysis of the occurrence of Boletus-type spores in the warm temperate climate of the Northern Hemisphere. An assumption was made that the spore concentrations depend on the type of land cover and weather conditions. The volumetric method was applied to investigate differences in spore concentrations and using spore traps installed at different heights and at locations with different land cover types. Boletus-type spores occurred in the air at high concentrations in late summer and in the autumn. The season start dates and maximum concentrations did not differ significantly between sites and seasons, but the season intensity varied. Higher spore concentrations were usually found in the region with a larger proportion of green areas, including forests. An analysis of the diurnal cycles showed that within 24 h spore concentration reached high levels twice, which was especially noticeable in ground level monitoring. Air temperature and air humidity were the main weather factors affecting the occurrence of airborne spores. This research indicates that when studying the effects of different factors on the concentration of airborne basidiospores, many environmental elements should be analyzed, including the characteristics of habitats in which basidiomycetes grow. Climate, weather, geobotany, and land use type should be taken into account in analysis and interpretation of aeromycological phenomena.