Russian Journal of Biological Physics and Chemisrty Russian Journal of Biological Physics and Chemisrty АКТУАЛЬНЫЕ ВОПРОСЫ БИОЛОГИЧЕСКОЙ ФИЗИКИ И ХИМИИ 2499-9962 54630 Общая биофизика General biophysics Общая биофизика The role of the lateral tension in calcium-dependent phospholipid membrane fusion Роль латерального натяжения в кальций-зависимом слиянии фосфолипидных мембран Чантурия А Н Chanturia A N lexandr32@hotmail.com Eastern Scientific ru Eastern Scientific ru 25 06 2021 25 06 2021 6 2 230 234 20 06 2021 20 06 2021 https://rusjbpc.ru/en/nauka/article/54630/view

Слияние гранул кортекса яйцеклеток морского ежа Strongylocentrotus purpuratus исследовалось в экспериментальной системе, позволяющей медленное увеличение концентрации кальция в микро молярном диапазоне. Установлено, что кроме пороговой концентрации, запускающей слияние гранул с плазматической мембраной, существует порог скорости роста концентрации, ниже которого слияние не происходит. Так же показано что инкубация препаратов кортекса в растворах с повышенным содержанием кальция приводит к инактивации гранул, выражающейся в потере ими способности сливаться при более высоких концентрациях кальция. Полученные данные указывают на то, что опосредованное белками слияние мембран может происходить вследствие возникновения латерального стресса по типу ранее предложенного механизма слияния чисто фосфолипидных мембран.

Fusion of the cortical granules of the sea urchin Strongylocentrotus purpuratus eggs was studied in an experimental system that allows a slow increase in the concentration of calcium in micro-molar range. It was found that in addition to the threshold concentration that trigger fusion of granules with the plasma membrane, there is a threshold for the rate of concentration growth, below which fusion does not occur. It is also shown that incubation of cortex preparations in solutions with an increased calcium content leads to inactivation of granules, which is expressed in the loss of their ability to fuse at higher concentrations of calcium. These data indicate that protein-mediated membrane fusion can be driven by the membrane lateral stress, similarly to the earlier proposed mechanism for fusion of purely phospholipid membranes.

 Мембраны кальций латеральное натяжение слияние микроскопия Membranes calcium tension fusion microscopy

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