PH(pleckstrin homology)domains are well known to bind membrane phosphoinositides with different specificities and direct PH domain-containing proteins to discrete subcellular compartments with assistances of alternati...PH(pleckstrin homology)domains are well known to bind membrane phosphoinositides with different specificities and direct PH domain-containing proteins to discrete subcellular compartments with assistances of alternative binding partners.PH domain-containing proteins have been found to be involved in a wide range of cellular events,including signalling,cytoskeleton rearrangement and vesicular trafficking.Here we showed that a novel PH domain-containing protein,PEPP2(also known as PLEKHA5),displays moderate phosphoinositide binding specificity.Full length PEPP2 was observed to variably associate with both the plasma membrane and microtubules.The membrane-associated PEPP2 nucleated at cell-cell contacts and the leading edge of migrating cells.Overexpression of PEPP2 increased membrane microviscosity,indicating a potential role for PEPP2 in regulating function of microtubule-dependent membrane functions.展开更多
基金sponsored by the Science Foundation of the Ministry of Education of China(51208011)the setup grant of Jinan University(51207016).
文摘PH(pleckstrin homology)domains are well known to bind membrane phosphoinositides with different specificities and direct PH domain-containing proteins to discrete subcellular compartments with assistances of alternative binding partners.PH domain-containing proteins have been found to be involved in a wide range of cellular events,including signalling,cytoskeleton rearrangement and vesicular trafficking.Here we showed that a novel PH domain-containing protein,PEPP2(also known as PLEKHA5),displays moderate phosphoinositide binding specificity.Full length PEPP2 was observed to variably associate with both the plasma membrane and microtubules.The membrane-associated PEPP2 nucleated at cell-cell contacts and the leading edge of migrating cells.Overexpression of PEPP2 increased membrane microviscosity,indicating a potential role for PEPP2 in regulating function of microtubule-dependent membrane functions.
