Purpose. To conduct in vitro screening of different genotypes of winter triticale for resistance to salinity in the shoot apical meristem culture. Methods. Plant tissue culture in vitro, in vitro breeding, statistical analysis. Results. It was found that the increase of sodium chloride concentration from 0.6 to 1.5% resulted in inhibition of the callus culture growth in all genotypes that was indicative of the toxic effect of the stress factor. It turns out that 1.2% sodium chloride concentration allowed to differentiate triticale genotypes for salt tolerance. The line ‘38/1296’ appeared to be the most resistant to salinity stress because under breeding conditions calli of this genotype were characterized by higher morphogenetic potential, had the highest crude mass increase, and plants-regenerants were obtained only from explants of this line after cultivation on the medium containing 1.5% sodium chloride. The ‘ADM 11’ variety was the most sensitive to saline stress as mass necrosis and lack of regenerative ability in its calli were observed under breeding conditions. In the studied forms, genotypic dependence of morphogenesis processes in vitro culture was registered. From the induced calli, plants-regenerants were obtained, and their completion of growing, root development and transfer to in vivo conditions were optimized. Conclusions. Genotypic response to salinity stress in the culture of shoot apical meristems of winter triticale was expressed by various crude mass increase and different morphogenetic potential on exposure to a stress factor. The line ‘38/1296’ can be used as a valuable material for further breeding of winter triticale. The culture of shoot apical meristems is recommended to apply as a test system for screening of triticale genotypes for resistance to salinity stress

Purpose. To conduct in vitro screening of different genotypes of winter triticale for resistance to salinity in the shoot apical meristem culture. Methods. Plant tissue culture in vitro, in vitro breeding, statistical analysis. Results. It was found that the increase of sodium chloride concentration from 0.6 to 1.5% resulted in inhibition of the callus culture growth in all genotypes that was indicative of the toxic effect of the stress factor. It turns out that 1.2% sodium chloride concentration allowed to differentiate triticale genotypes for salt tolerance. The line ‘38/1296’ appeared to be the most resistant to salinity stress because under breeding conditions calli of this genotype were characterized by higher morphogenetic potential, had the highest crude mass increase, and plants-regenerants were obtained only from explants of this line after cultivation on the medium containing 1.5% sodium chloride. The ‘ADM 11’ variety was the most sensitive to saline stress as mass necrosis and lack of regenerative ability in its calli were observed under breeding conditions. In the studied forms, genotypic dependence of morphogenesis processes in vitro culture was registered. From the induced calli, plants-regenerants were obtained, and their completion of growing, root development and transfer to in vivo conditions were optimized. Conclusions. Genotypic response to salinity stress in the culture of shoot apical meristems of winter triticale was expressed by various crude mass increase and different morphogenetic potential on exposure to a stress factor. The line ‘38/1296’ can be used as a valuable material for further breeding of winter triticale. The culture of shoot apical meristems is recommended to apply as a test system for screening of triticale genotypes for resistance to salinity stress

Purpose. To analyze the level of cross-resistance of obtained salt- and osmotolerant cell lines and plants regenerants of winter triticale to osmotic and salt stresses. Methods. Cultures of tissue and organs in vitro, in vitro breeding, biochemical, statistical analysis. Results. It was established that the stability of cross-resistance trait display to saline and osmotic stresses in obtained cell lines of winter triticale was rather high – from 50 to 76% of calli have survived to the end of the sixth passage. It has been shown that despite the presence of sublethal concentrations of the stress-factor (mannitol/sodium chloride) in selective medium, stable cell lines of the triticale actively continued to grow and accumulate biomass. It was found that in the line ‘38/1296’ cell lines 5L/sl and 5L/os respectively were the most resistant to osmotic and salt stresses, and lines 1C/s1 and 1C/os respectively in the ‘Obrii’ variety, since they had the highest percent of living calli and biomass increment under the selective conditions and their plant regenerant – the highest level of survival after the impact of the abiotic stressors complex. The salt-resistant cell lines of both genotypes of winter triticale as compared to the control were also characterized by significantly higher free proline content under the selective factors impact. The results obtained may indicate that the cell lines and triticale plant regenerants have a genetically determined trait of resistance to stress factors. Conclusions. Verification of traits of resistance to abiotic stressors has shown a significantly high level of cross-tolerance of the obtained cell lines of both triticale genotypes for saline and osmotic stresses. Resistance to saline and osmotic stresses of cells separated in vitro was preserved in induced plants and at the organism level has increased tolerance to abiotic environmental factors. It is shown that due to the general non-specific mechanisms of resistance, the capacity of the callus cultures of triticale to resist to one abiotic stressor can lead to increased tolerance for another one.

Мета. Проаналізувати рівень перехресної стійкості отриманих соле- та осмостійких клітинних ліній і рослин-регенерантів тритикале озимого до осмотичного та сольового стресів.Методи. Культури тканин і органів in vitro, селекції in vitro, біохімічні, статистичний аналіз.Результати. Встановлено, що стабільність прояву ознаки перехресної стійкості як до сольового, так і до осмотичного стресів у отриманих клітинних ліній тритикале озимого була на досить високому рівні – до кінця шостого пасажу виживало від 50 до 76% калюсів. Показано, що, незважаючи на наявність у селективному середовищі сублетальної концентрації стрес-фактора (маніту/хлориду натрію), стійкі клітинні лінії тритикале активно продовжували рости й накопичувати біомасу. Виявлено, що у лінії ‘38/1296’ найбільш стійкими до осмотичного та сольового стресів були клітинні лінії 5Л/сл та 5Л/ос відповідно, а в сорту ‘Обрій’ – 1С/сл та 1С/ос відповідно, оскільки вони мали найвищу частку живих калюсів та приріст біомаси за селективних умов, а рослини-регенеранти з них – найвищий рівень виживання після дії комплексу абіотичних стресорів. Солестійкі клітинні лінії обох генотипів тритикале озимого порівняно з контролем характеризувались також достовірно вищим вмістом вільного проліну за дії селективних чинників. Одержані результати можуть свідчити про те, що клітинні лінії та рослини-регенеранти тритикале мають генетично обумовлену ознаку стійкості до стресових факторів.Висновки. Перевірка ознак стійкості до абіотичних стресорів засвідчила досить високий рівень перехресної толерантності отриманих клітинних ліній обох генотипів тритикале як до сольового, так і до осмотичного стресів. Стійкість до сольового та осмотичного стресів виділених in vitro клітин збереглась у індукованих рослинах і на організмовому рівні забезпечила підвищення толерантності до абіотичних факторів середовища. Показано, що завдяки загальним неспецифічним механізмам стійкості резистентність калюсних культур тритикале до одного абіотичного стресора може призводити до підвищення толерантності й до іншого. | Purpose. To analyze the level of cross-resistance of obtained salt- and osmotolerant cell lines and plants regenerants of winter triticale to osmotic and salt stresses. Methods. Cultures of tissue and organs in vitro, in vitro breeding, biochemical, statistical analysis. Results. It was established that the stability of cross-resistance trait display to saline and osmotic stresses in obtained cell lines of winter triticale was rather high – from 50 to 76% of calli have survived to the end of the sixth passage. It has been shown that despite the presence of sublethal concentrations of the stress-factor (mannitol/sodium chloride) in selective medium, stable cell lines of the triticale actively continued to grow and accumulate biomass. It was found that in the line ‘38/1296’ cell lines 5L/sl and 5L/os respectively were the most resistant to osmotic and salt stresses, and lines 1C/s1 and 1C/os respectively in the ‘Obrii’ variety, since they had the highest percent of living calli and biomass increment under the selective conditions and their plant regenerant – the highest level of survival after the impact of the abiotic stressors complex. The salt-resistant cell lines of both genotypes of winter triticale as compared to the control were also characterized by significantly higher free proline content under the selective factors impact. The results obtained may indicate that the cell lines and triticale plant regenerants have a genetically determined trait of resistance to stress factors.Conclusions. Verification of traits of resistance to abiotic stressors has shown a significantly high level of cross-tolerance of the obtained cell lines of both triticale genotypes for saline and osmotic stresses. Resistance to saline and osmotic stresses of cells separated in vitro was preserved in induced plants and at the organism level has increased tolerance to abiotic environmental factors. It is shown that due to the general non-specific mechanisms of resistance, the capacity of the callus cultures of triticale to resist to one abiotic stressor can lead to increased tolerance for another one. | Цель. Проанализировать уровень перекрестной устойчивости полученных соле- и осмоустойчивых клеточных линий и растений-регенерантов тритикале озимого к осмотическому и солевому стрессам. Методы. Культуры тканей и органов in vitro, селекции in vitro, биохимические, статистический анализ. Результаты. Установлено, что стабильность проявления признака перекрестной устойчивости как к солевому, так и осмотическому стрессам у полученных клеточных линий тритикале озимого была на достаточно высоком уровне – к концу шестого пассажа выживало от 50 до 76% каллусов. Показано, что, несмотря на наличие в селективной среде сублетальной концентрации стресс-фактора (маннита/хлорида натрия), устойчивые клеточные линии тритикале активно продолжали свой рост и накапливали биомассу. Выявлено, что в линии ‘38/1296’ наиболее устойчивыми к осмотическому и солевому стрессам были клеточные линии 5Л/сл и 5Л/ос соответственно, а у сорта ‘Обрий’ – 1С/сл и 1С/ос соответственно, поскольку они имели самую высокую долю живых каллусов и прирост биомассы в селективных условиях, а растения-регенеранты из них – наивысший уровень выживания после воздействия комплекса абиотических стрессоров. Солеустойчивые клеточные линии обоих генотипов тритикале озимого по сравнению с контролем характеризовались также достоверно более высоким содержанием свободного пролина при действии селективных факторов. Полученные результаты могут свидетельствовать о том, что клеточные линии и растения-регенеранты тритикале имеют генетически обусловленный признак устойчивости к стрессовым факторам. Выводы. Проверка признаков устойчивости к абиотическим стрессорам показала достаточно высокий уровень перекрестной толерантности полученных клеточных линий обоих генотипов тритикале как к солевому, так и к осмотическому стрессам. Устойчивость к солевому и осмотическому стрессам выделенных in vitro клеток сохранилась в индуцированных растениях и на уровне организма обеспечила повышение толерантности к абиотическим факторам среды. Показано, что благодаря общим неспецифическим механизмам устойчивости резистентность каллусных культур тритикале к одному абиотическому стрессору может приводить к повышению толерантности и к другому.

Purpose. To analyze the level of cross-resistance of obtained salt- and osmotolerant cell lines and plants regenerants of winter triticale to osmotic and salt stresses. Methods. Cultures of tissue and organs in vitro, in vitro breeding, biochemical, statistical analysis. Results. It was established that the stability of cross-resistance trait display to saline and osmotic stresses in obtained cell lines of winter triticale was rather high – from 50 to 76% of calli have survived to the end of the sixth passage. It has been shown that despite the presence of sublethal concentrations of the stress-factor (mannitol/sodium chloride) in selective medium, stable cell lines of the triticale actively continued to grow and accumulate biomass. It was found that in the line ‘38/1296’ cell lines 5L/sl and 5L/os respectively were the most resistant to osmotic and salt stresses, and lines 1C/s1 and 1C/os respectively in the ‘Obrii’ variety, since they had the highest percent of living calli and biomass increment under the selective conditions and their plant regenerant – the highest level of survival after the impact of the abiotic stressors complex. The salt-resistant cell lines of both genotypes of winter triticale as compared to the control were also characterized by significantly higher free proline content under the selective factors impact. The results obtained may indicate that the cell lines and triticale plant regenerants have a genetically determined trait of resistance to stress factors. Conclusions. Verification of traits of resistance to abiotic stressors has shown a significantly high level of cross-tolerance of the obtained cell lines of both triticale genotypes for saline and osmotic stresses. Resistance to saline and osmotic stresses of cells separated in vitro was preserved in induced plants and at the organism level has increased tolerance to abiotic environmental factors. It is shown that due to the general non-specific mechanisms of resistance, the capacity of the callus cultures of triticale to resist to one abiotic stressor can lead to increased tolerance for another one.