Выделение и структурная характеристика белково-пептидных антибиотиков растительного происхождения тема диссертации и автореферата по ВАК РФ 02.00.10, кандидат химических наук Финкина, Екатерина Ивановна

Повсеместное присутствие патогенных микроорганизмов является одним из основных неблагоприятных факторов окружающей среды, и способность противостоять их воздействию является ключевым моментом в жизни биологического вида. В ходе эволюции растения и животные выработали ряд эффективных защитных механизмов. Важнейшим компонентом защитной системы высших животных является адаптивный иммунный ответ, который характеризуется специфическим распознаванием микроорганизма и наличием иммунной памяти. Для растений описаны такие характерные только для них защитные стратегии как гиперчувствительный ответ, утолщение клеточной стенки, повышение концентрации фитогормонов, обеспечение локальной и системной резистентности, в том числе путем синтеза белков, связанных с патогенезом (Pathogenesis-Related Proteins или PRP), и вторичных метаболитов, обладающих антимикробным действием.

Среди всех имеющихся в арсенале растений защитных механизмов особый интерес у исследователей вызывает синтез PRP. В настоящее время выделены и охарактеризованы PRP представителей различных ботанических семейств. Эти стресс-индуцируемые белки растений подразделяются на 17 классов и синтезируются только в ответ на воздействие неблагоприятных факторов, таких как присутствие фитопатогенов, дефицит влаги, механическое повреждение, изменение температуры или обработка химическими агентами. Общим для PRP является относительно низкая молекулярная масса, устойчивость к воздействию протеаз и сред с низкими значениями рН, наличие сигнальной последовательности в структуре предшественника, преимущественно внеклеточная локализация и антимикробная активность. На сегодняшний день выделено и охарактеризовано большое число PRP из различных растений. Однако механизмы антимикробного действия большинства растительных антибиотиков до конца не исследованы и находятся в стадии изучения.

Интерес исследователей к РИР растений обусловлен возможностью их применения в сельскохозяйственной отрасли, которая несет огромные убытки из-за потери урожая культурных растений, поражаемых патогенными микроорганизмами, вирусами и насекомыми-вредителями. Традиционные методы борьбы, основанные на искусственной селекции растений, в последнее время становятся неэффективными вследствие опережающей автоселекции патогенных микроорганизмов. Применение пестицидов и инсектицидов имеет такие негативные последствия, как загрязнение окружающей среды, гибель непатогенной микрофлоры, насекомых и птиц, а также появление устойчивых патогенных микроорганизмов и насекомых. В этой ситуации перспективным представляется создание трансгенных растений, имеющих низкую себестоимость и повышенную устойчивость к фитопатогенам.

Второе направление для возможного применения растительных РЯР связано с их способностью наряду с фитопатогенами эффективно подавлять рост патогенных для человека микроорганизмов. Такие характеристики, как высокая специфичность действия и отсутствие токсического воздействия на животные клетки, также свидетельствуют в пользу того, что растительные антимикробные белки и пептиды могут стать альтернативой современных антибиотиков, эффективность использования которых постоянно снижается в связи со стремительно растущей резистентностью бактерий и грибов.

Многие РЫР растений имеют аллергенную природу и являются причиной развития аллергических реакций на пыльцу, растительные пищевые продукты и латекс. Обнаружение и изучение свойств новых растительных аллергенов является важным направлением экспериментальной медицины, которое не только способствует пониманию причин и механизмов развития аллергии, но и имеет важное прикладное значение. Широко используемые для проведения аллергодиагностики экстракты растительных тканей представляют собой многокомпонентные смеси, что осложняет их стандартизацию и зачастую является причиной ложно положительных или ложно отрицательных результатов. В то же время, для лечения аллергии используются различные фармацевтические препараты, направленные в основном на устранение аллергических симптомов. Природные и рекомбинантные белковые растительные аллергены могут стать основой для создания новых диагностических тест-систем, а также использоваться для специфической аллерговакцинации, направленной на снижение чувстсвительности организма к аллергенам.

Целью работы являлся поиск, выделение и структурно-функциональное исследование новых белково-пептидных антибиотиков растительного происхождения. В качестве объекта исследования была выбрана распространенная во многих странах, но малоизученная культура - чечевица обыкновенная Lens culinaris subsp. culinaris [семейство - бобовые (Leguminosae, Fabaceae), род - чечевица (Lens)]. В задачи работы входили поиск новых антимикробных белков и пептидов, разработка методик их выделения и очистки, определение полных аминокислотных последовательностей и структур кДНК, кодирующих предшественники антимикробных белков и пептидов, а также функциональная характеристика выделенных веществ.

5. Выводы

1. В семенах чечевицы Lens culinaris обнаружено 9 новых PRP, выполняющих защитную функцию в растениях, а именно: новый растительный дефенсин Lc-def и подсемейство из 8 новых липид-транспортирующих белков Lc-LTPl-8. Разработаны методики выделения растительного дефенсина Lc-def и четырех липид-транспортирующих белков из проращённых семян чечевицы Lens culinaris. Определены полные аминокислотные последовательности выделенных PRP.

2. Установлены структуры полноразмерных к ДНК, кодирующих белки-предшественники дефенсина Lc-def и шести изоформ липид-транспортирующих белков из семян чечевицы Lens culinaris, и соответствующие им полные аминокислотные последовательности предшественников этих белков.

3. Проведено исследование функциональной активности выделенных PRP. Показано, что дефенсин чечевицы Lc-def обладает противогрибковой активностью и характеризуется специфичностью действия в отношении ряда фитопатогенных грибов. Показано, что липид-транспортирующие белки чечевицы обладают антибактериальной активностью и ингибируют рост фитопатогенных грибов.

4. Установлено, что липид-транспортирующий белок чечевицы Lc-LTP2 является новым пищевым аллергеном. Lc-LTP2 внесен в международную базу данных по аллергенам как Len с 3.

6. Благодарности

Осуществление данной работы оказалось возможным благодаря помощи многих людей, которым автор выражает свою глубокую признательность.

Автор выражает огромную благодарность своему научному руководителю, кандидату химических наук, руководителю отдела «Учебно-научный центр» ИБХ РАН, Татьяне Владимировне Овчинниковой, за теплое отношение, поддержку, консультации и оценку результатов дисссертационных исследований.

Автор выражает особую благодарность Баландину Сергею Владимировичу и Шрамовой Елене Ивановне за непосредственное участие в исследованиях (определении структур кДНК предшественников антимикробных белков).

Автор выражает благодарность Потапенко Наталие Анатольевне, проводившей определение С-концевых аминокислотных остатков; Тагаеву Андрею Азисовичу и Юлии Федоровне Леоновой за секвенирование белков; Серябриковой Марине Васильевне за проведение масс-спектрометрического анализа; Светлане Владимировне Кузницовой за синтез олигонуклеотидов, использованных в работе.

Автор благодарен всем сотрудникам Учебно-научного центра ИБХ РАН и своим коллегам за обучение методам лабораторной работы, организационную помощь, критические замечания и советы.

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