Расположение и возможная функциональная роль участков связывания транскрипционного фактора CTCF в локусе 19 хромосомы человека тема диссертации и автореферата по ВАК РФ 03.00.03, кандидат биологических наук Ветчинова, Анна Сергеевна

Стремительный прогресс в молекулярной биологии позволил расшифровать полные последовательности геномов многих организмов позвоночных (Lander et.al., 2001). В частности, была установлена полная первичная структура человеческого генома и определено положение в геноме человека большей части генов. Однако, установить функции генов на основании их первичной структуры возможно далеко не всегда. Для решения этой задачи требуется привлечение знаний из разных областей науки: биоинформатики, генетики, биологии развития, молекулярной биологии, биохимии и т. д. Достижения в определении первичной структуры и картировании геномов привели к появлению нового направления исследований - функциональной геномики, которая включает в себя главным образом идентификацию, локализацию в геноме и функциональный анализ новых генов.

В то же время геном содержит множество нетранскрибируемых функционально активных элементов, обладающих важнейшими регуляторными свойствами и имеющими решающее значение для его нормальной работы. Примерами таких элементов могут служить энхансеры, терминаторы транскрипции, участки связывания ДНК с регуляторными белками, участки начала репликации, места интеграции ретроэлементов и т.д. В большинстве случаев подобные структуры невозможно идентифицировать, имея данные только о нуклеотидной последовательности участков ДНК, которые их содержат. Одним из способов их корректной идентификации является соответствующий экспериментальный, функциональный подход. Картирование последовательностей с известной функциональной ролью значительно облегчает понимание общей организации и основных принципов регуляции работы генома как целого.

Известно, что многие белки способны специфически связываться с теми или иными участками ДНК. Связывание ядерных белков с регуляторными последовательностями ДНК является главным механизмом регуляции экспрессии у эукариот. Среди белков, вовлечённых в экспрессию эукариотических генов, существуют многофункциональные белки, действующие на разных этапах экспрессии генов: при инициации и элонгации транскрипции, трансляции.

Цели и задачи работы

Целью диссертационной работы является идентификация сайтов связывания транскрипционного фактора CTCF в локусе 19 хромосомы человека, длиной около 1 млн.п.н., находящегося между маркерами FXYD5 и Сох7А1. Этот локус содержит значительное число известных генов и его нуклеотидная последовательность полностью установлена, что позволит, как картировать все отобранные элементы с большой точностью, так и сделать выводы о взаимном расположении белок-связывающих элементов и генов и их возможной функциональной взаимосвязи.

Были поставлены следующие экспериментальные задачи:

- выявить с помощью метода сдвига электрофоретической подвижности (EMSA) участки связывания белка CTCF в локусе 19 хромосомы человека между маркёрами FXYD5 и Сох7А1;

- клонировать и секвенировать участки ДНК, связывающиеся с белком CTCF;

- выявить фрагменты ДНК, связывающиеся с белком CTCF in vivo с использованием метода иммунопреципитации хроматина (ChlP-assay), и сравнить их с выделенными в системе in vitro;

- построить карту распределения сайтов связывания CTCF в локусе 19 хромосомы человека между маркёрами FXYD5 и Сох7А1.

2.0бзор литературы.

Выводы

1. С помощью разработанного нами метода двумерного EMSA была получена библиотека фрагментов 19 хромосомы человека локуса FXYD5-COX7A1 длиной один миллион пар оснований, способных связываться с транскрипционным фактором CTCF.

2. В результате анализа библиотеки, выявлены и картированы десять участков связывания CTCF в локусе 19 хромосомы человека.

3. Произведен анализ расположения картированных последовательностей относительно генов локуса FXYD5-COX7A1.Показано, что семь из десяти последовательностей расположены внутри генов (преимущественно в интронах), три расположены в межгенных участках локуса.

4. Методом иммунопреципитации хроматина доказано специфическое связывание всех десяти картированных последовательностей с транскрипционным фактором CTCF in vivo.

5. Показано, что обнаруженные ранее семь последовательностей, обладающих инсуляторной активностью, способны связываться с транскрипционным фактором CTCF in vivo.

Я хочу выразить самую искреннюю признательность своему научному руководителю к.б.н. Сергей Борисовичу Акопову за советы, поддержку и помощь на каждом этапе работы.

Выражаю глубокую благодарность заведущему Лабораторией Структуры и Функций Генов Человека академику Евгению Давидовичу Свердлову, заместителю заведующего лабораторией Галине Сергеевне Монастырской, Льву Григорьевичу Николаеву, а также прекрасному коллективу лаборатории за дружеское и внимательное отношение. Без их советов и дружеского участия в работе ее выполнение было бы невозможно.

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