Фосфолипаза А: Роль окисления фосфолипидов in vitro и in vivo в регуляции фосфолиполиза тема диссертации и автореферата по ВАК РФ 02.00.15, кандидат химических наук Купцова, Ольга Сергеевна

Фосфолипаза Аг представляет класс ферментов, ката. Г71зирующих гидролиз сложноэфирной связи в глицерофосфолипидах с образованием лизофосфолипидов и свободных жирных кислот [1].Фосфолипаза А2 специфично отщепляет жирные кислоты в 8п-2 положении фосфолипидов, в том положении, в котором в природе находится большинство (поли)ненасыщенных кислот. Как известно, ненасыщенные кислоты легко подвергаются окислению. Вопрос о влиянии окисления фосфолипидов в биологических мембранах на активность фосфолипазы А2, представляет, с одной стороны, фундаментальный интерес для энзимологов, для понимания закономерностей протекания механизмов липолиза. В свою очередь, эта проблема имеет прикладное значение. Известно, что пищевые продукты с высоким содержанием ненасыщенных жирных кислот быстро теряют свои пищевые качества, и основные процессы, лежащие в основе ухудшения качества таких продуктов — окисление липидов и липолиз [2-4]. Образование в результате совместного действия этих процессов различных окисленных производных жирных кислот вызьшает не только появление нежелательных запахов и вкуса, но и приводит к серьезным болезням [5-8]. В настоящее время в литературе имеются указания на то, что липолитические ферменты, в частности, фосфолипаза А2, присутствующая в продуктах с высоким содержанием ненасыщенных липидов, легко окисляющихся при хранении, могут провоцировать появление гидроперекисей жирных кислот [2,9,10]. Для нескольких фосфолипаз А2 обнаружен предпочтительный гидролиз окисленных фосфолипидов в изолированных клеточных мембранах и искусственных мембранных препаратах. Однако до сих пор подобные случаи активации фосфолипазы Аз объясняли исключительно повышенной специфичностью фермента к окисленному субстрату, не рассматривая влияния структуры мембраны. Между тем фосфолипиды являются не только субстратом, то и суперсубстратом. В качестве последнего они определяют поверхностные характеристики мембраны, которые влияют на сорбцию фосфолипа;;ы на мембране и последующее расщепление фосфолипидов в мембране. До настоящего времени не было проведено систематических исследований, которые охватывали бы одновременное рассмотрение специфичности фермента по отношению к окисленным фосфолипидам и роли структуры суперсубстрата in vitro и особенно in yivo. В живых клетках известны случаи стимуляции фосфолипазной-Аг активности в процессе окислительного взрыва, однако такая активация происходит чаще всего в результате последовательной передачи сигналов в клетках, при этом окисление, как правило, 11Ьедшествует фосфолиполизу.Для изучения взаимодействия фосфолипазы Аз с окисленными мембранами, таким образом, требуется новый подход, принимающий во внимание не только структуру молекулы фосфолипида, но и изменение структуры мембраны.

выводы

1. Изучено поведение фосфолипазы А2 по отношению к окисленным и неокисленным модельным фосфолипидам фосфатидил 1,2-диолеил-зп-глицеро-3-фосфохолин (DOPC) и 1-стеароил-2-арахидонил~л;?-глицеро-3-фосфохолин (SAPC), а также к природным фосфолипидам, in vitro. Показано, что для фермента из поджелудочной железы свиньи при увеличении доли окисленных фосфблипидов скорость фосфолиполиза возрастает равнозначно по отношению ко всем, включая неокисленные, фосфолипидам, составляющим мембрану. Для ФЛА2 из Naja Mossambica Mossambica, несмотря на уменьшение специфичности по отношению к окисленным фосфолипидам, происходит активация липолиза, с повышенной эффективностью расщепления неокисленных фосфолипидов.

2. Показано, что в активации фермента существенную роль играет изменение свойств мембраны при окислении, а именно, увеличение жесткости мембранной структуры. Это было продемонстрировано измерением вязкости и латеральной подвижности липидов в окисленных липосомах. Жесткость структуры может способствовать как улучшению связывания фосфолипазы А2 с мембраной, так и фиксированию продуктивной ориентации белка по отношению к расщепляемым фосфолипидам.

3. Впервые детектирована фосфолипазная активность в клетках табака BY-2.

Наблюдаемая активность локализована в плазматической и ядерной

2+ мембранах, является Са -зависимой, стимулируется активатором G-белков мастопараном. Наблюдаемая фосфолипазная активность принадлежит, вероятно, к А2-типу, поскольку она ингибируется известными ингибиторами фосфолипазы А2.

4. Показано, что при прямом окислении мембранных фосфолипидов в клетках BY-2 наблюдается значительное возрастание фосфолипазной активности типа А2. В свете результатов, полученных для взаимодействия фосфолипазы с окисленными фосфолипидами in vitro, наблюдаемая активация in vivo является, по-видимому, следствием повышения жесткости мембраны из-за ее окисления.

5. По совокупности результатов работы сделан вывод о том, что усиленная активность фосфолипазы А2 в окисленных мембранах может являться причиной быстрого' накопления нежелательных продуктов окисления жирных кислот при хранении пищевых продуктов, богатых ненасыщенными жирами.

БЛАГОДАРНОСТИ

Автор выражает огромную благодарность профессору Тону Фиссеру, Нине Фиссер и Яну Уиллему Борсту, кафедра Биохимии, Университет Вагенингена, Нидерланды, за предоставленную возможность и помощь в осуществлении части настоящей работы в Университете Вагенингена. Работа выполнялась в рамках проекта Европейского Сообщества FAIR 97 3228 "Роль липолиза в окислении мембранных липидов в ,;.пище с высоким содержанием ненасыщенных жиров". Пребывание и научные исследования в Университете Вагенингена финансировалась нидерландским грантом NOW (Tile Netherlans Organisation for Scientific Research) 047-007-005, поддерживающим научное сотрудничество между Российской Федерацией и Нидерландами. Хотелось бы выразить особую благодарность и признательность своим научным руководителям, профессору Наталье Львовне Клячко и профессору Андрею Вадимовичу Левашову за неоценимую помощь и поддержку на всех этапах исследования.

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