Митохондриальная регуляция экспрессии белков теплового шока у растений и дрожжей тема диссертации и автореферата по ВАК РФ 03.01.05, кандидат биологических наук Федосеева, Ирина Владимировна

7. ВЫВОДЫ

1. Присутствие митохондриальных ингибиторов и разобщителей во время теплового стресса подавляет индукцию синтеза БТШ и развитие индуцированной термотолерантности в культуре клеток А. ШаИапа и дрожжей б*. сегеу1б'1ае.

2. Тепловой стресс вызывает усиление дыхательной активности и повышение электрохимического потенциала на внутренней митохондриальной мембране, что, по-видимому, имеет важное значение для активации экспрессии БТШ.

3. Повышение потенциала на внутренней митохондриальной мембране при тепловом стрессе сопровождается повышением уровня цитозольного кальция в клетках дрожжей 5. сеге\пя1ае.

4. Обработка экзогенным Са индуцирует синтез ШрКМ и повышает термотолерантность дрожжей сегеуЫае.

5. Полученные данные позволяют предполагать, что повышение уровня Са2+ при тепловом стрессе вызывает гиперполяризацию внутренней митохондриальной мембраны, что является важным условием для активации экспрессии генов БТШ.

6. ЗАКЛЮЧЕНИЕ

В последние годы стало очевидно, что функции митохондрий не ограничиваются окислительным фосфорилированием. Помимо производства энергии, эти органеллы играют активную роль в реализации программируемой клеточной смерти (Vianello et al., 2007; Cheng et al., 2008;). В ходе, так называемой ретроградной регуляции, митохондрии могут регулировать экспрессию ядерных генов у дрожжей и растений (Sweetlove et al. 2007; Vanlerberghe et al., 2009; Юрина, Одинцова, 2008; Юрина, Одинцова, 2010).

Полученные результаты позволяют предполагать, что митохондрии вовлечены в регуляцию экспрессии генов БТШ при тепловом стрессе. Нарушение функционирования митохондрий в результате обработки митохондриальными ингибиторами и разобщителями подавляет индукцию синтеза БТШ при тепловом стрессе в культуре клеток A. thaliana и в клетках дрожжей S. cerevisiae, что сопровождается ингибированием индуцированной термотолерантности. В то же время в ряде случаев обработка этими агентами при обычной температуре инкубации может также индуцировать синтез БТШ. Таким образом, в зависимости от условий, дисфункция митохондрий может активировать или подавлять экспрессию генов БТШ. Этот результат доказывает, что митохондрии растений и дрожжей играют активную роль в реализации защитной программы при тепловом стрессе.

Тепловой стресс, вызывающий индукцию синтеза БТШ, приводил к повышению mtA\|/ в клетках растений и дрожжей. Феномен повышения mtAvf/ при тепловом стрессе был подтвержден другими исследователями, использующими клетки животных (Balogh et al. 2005; Pallepati, Averill-Bates, 2010). Поскольку агенты, способные при данных экспериментальных условиях деполяризовать mtAv|/, одновременно подавляли тепловую индукцию синтеза БТШ и развитие индуцированной термотолерантности, то есть основание предполагать наличие причинно-следственной связи между гиперполяризацией внутренней митохондриальной мембраны и активацией экспрессии генов БТШ. Очевидно, что обнаруженная закономерность характерна только для условий теплового стресса. Деполяризация митохондриальной мембраны при обычных условиях инкубации также, в ряде случаев, приводила к индукции синтеза БТШ.

Согласно предположению Balogh et al. (2005) гиперполяризация внутренней митохондриальной мембраны в клетках животных при тепловом стрессе является следствием повышения уровня кальция в цитозоле. Известно, что митохондрии животных поглощают кальций в зависимости от mtA\|/ (Griffiths, Rutter, 2009). Поступление кальция в митохондрии в момент стресса стимулирует активность дыхательных ферментов (Denton, 2009), что приводит к гиперполяризации внутренней митохондриальной мембраны, усилению продукции АФК и изменению редокс-состояния клетки (Griffiths, Rutter, 2009). Изучение изменение уровня кальция в цитозоле дрожжевой клетки показало, что тепловой стресс приводит к практически мгновенному повышению уровня кальция в цитозоле дрожжевой клетки. Аналогичное явление происходит и в клетках растений (Бияшева и др., 1993; Saidi et al., 2011). В данной работе не удалось показать значительного эффекта делеций в генах MIDI и ССН1, кодирующих кальциевые каналы на плазматической мембране дрожжей, на значение mtAi|/, синтез Hspl04 и развитие индуцированной термотолерантности. Очевидно, на богатой кальциевой среде у дрожжей функционирует система транспорта кальция, независимая от этих белков (Muller et al., 2003). Тем не менее, по аналогии с клетками животных, полученные результаты позволяют предполагать, что причиной повышения mtAv|/ в клетках растений и дрожжей является временное повышение уровня кальция в цитозоле.

Изменение уровня кальция в клетке играет важную роль в активации экспрессии генов при различных стрессовых воздействиях (Тарчевский, 2002), в том числе, и при тепловом стрессе (Saidi et al., 2011). На это указывают результаты, демонстрирующие, что обработка экзогенным кальцием вызывает индукцию синтеза БТШ у растений (Liu et al., 2005; Liu et al., 2003). Аналогичным образом, обработка экзогенным кальцием клеток дрожжей индуцировала синтез Hspl04 и повышала их термотолерантность. Вероятно, сигнал, активирующий экспрессию Hspl04, зависит от транскрипционных факторов Msn2 и Msn4, поскольку делеция генов, кодирующих эти факторы, подавляла способность клеток дрожжей синтезировать Hspl04 и развивать термотолерантность в ответ на обработку экзогенным кальцием.

Таким образом, полученные результаты позволяют выдвинуть следующую последовательность событий, приводящих к экспрессии генов БТЩ при тепловом стрессе.

Тепловой стресс вызывает кратковременное повышение уровня кальция в цитозоле. Повышение уровня кальция в клетке непосредственно (в результате его поступления в митохондрии) или опосредованным образом активирует активность митохондрий и вызывает повышение яМу. Повышение тЛДу приводит к усилению генерации АФК митохондриями, что может активировать экспрессию генов БТШ. Митохондрии, в свою очередь, обеспечивают определённый уровень кальция в цитозоле, который необходим и достаточен для активации экспрессии генов БТШ. Если стресс слишком сильный, кальций повышается в клетке до критического уровня. Следствием этого является падение митохондриального потенциала, открытие митохондриальной поры и активация программируемой клеточной смерти.

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392. Хочется выразить благодарность доктору Hidetoshi Iida из Tokyo Gakugei University за предоставленную возможность работать в его лаборатории и в освоении новых методов исследования.1. Федосеева Ирина