Cholesterol regulation of PIP2: why cell type is so important

A commentary on 
 
How cholesterol regulates endothelial biomechanics 
 
by Hong, Z., Staiculescu, M. C., Hampel, P., Levitan, I., and Forgacs, G. (2012). Front. Physio. 3:426. doi: 10.3389/fphys.2012.00426 
 
Phosphatidylinositol 4,5-bisphosphate (PIP2) is a phospholipid found in cell membranes, and has been indicated to play important roles in cytoskeletal organization, cell motility, transduction of extracellular signals, regulation of ion channels at the plasma membrane, endocytosis, phagocytosis, and endosome function. It has also been linked to cancer in humans (Di Paolo and De Camilli, 2006). PIP2 can be hydrolyzed by membrane-bound phospholipase C beta into two second messengers, IP3 and diacylglycerol (DAG). Plasmalemmal cholesterol has been demonstrated to regulate PIP2 hydrolysis and thus its cellular function in skin fibroblasts and pancreatic β-cells (Kwik et al., 2003; Hao and Bogan, 2009). 
 
In this original research article, Hong et al. (2012) address the role of plasmalemmal cholesterol in regulating the localization and metabolism of PIP2 in endothelial cells and the result on cell stiffness. They suggest that a decrease in cholesterol leads to disruption of PIP2 hydrolysis, which in turn results in increased cross-links between the membrane and cytoskeleton via PIP2 and increased cell stiffness. These results are important for understanding certain diseases, such as atherosclerosis, in which cholesterol levels are central to the pathology. 
 
The mechanism by which cholesterol regulates PIP2 in the plasma membrane may not be the same for different cell types. Cholesterol depletion in fibroblasts leads to decreased levels of PIP2 in the plasma membrane, diminished membrane-cytoskeletal attachments, and decreased lateral motility (Kwik et al., 2003). Similarly, in cultured pancreatic β-cells, cholesterol depletion stimulates the hydrolysis of PIP2, thus reducing the amount of PIP2 at the plasma membrane (Hao and Bogan, 2009). These findings are in contrast to a study using HEK293 cells, in which membrane cholesterol enrichment promoted PIP2 depletion (Chun et al., 2010). Cholesterol depletion in lymphoblasts results in decreased lateral mobility of membrane proteins (Kwik et al., 2003). PIP2 lateral mobility has been described as low in atrial myocytes, and high in HEK293 cells and fibroblasts (Epand, 2008). Therefore, cholesterol may regulate PIP2 differently in various cell types. 
 
Compartmentalization and regulation of PIP2 metabolism within the plasma membrane may contribute to differences observed between cell types (Epand, 2008; Kwiatkowska, 2010). Cholesterol-rich membrane microdomains (lipid rafts), which are known to be intimately involved in regulating a variety of G-protein coupled receptor-mediated functions, including those regulating PIP2 metabolism (Allen et al., 2007), have bidirectional relationship with actin cytoskeleton. In response to external stimuli, Gαq/11 subunits stimulate membrane-bound phospholipase C beta, which then cleaves PIP2 into its two second messengers. Therefore, it is believed that the relationship among lipid raft-associated PIP2, G-proteins, and actin has strong implications in regulating actin assembly to modify cell shape and function. Conversely, actin associates with rafts and caveolae either as polymerized structures or as actin monomers, which might help to organize lipid raft domains and the molecules that are present in this structure to evoke a variety of cell signaling pathways in the cell interior (Caroni, 2001). Another exciting mechanism involves three proteins, namely GAP43, MARCKS, and CAP23, which accumulate at rafts, where they associate with PIP2, and promote its retention and clustering. By modulating PIP2 at plasmalemmal rafts, GAP43, MARCKS, and CAP23 regulate cell cortex actin dynamics through a common mechanism. It is believed that, in response to local signals, these proteins dissociate from PIP2, creating local pools of free PIP2, which result in diverse intracellular responses. 
 
Nonetheless, the mechanisms through which PIP2 effector molecules mediate the various cellular responses to localized liberation of PIP2 are mostly unknown. Investigations in this direction will foster our understanding of cholesterol-mediated PIP2 intracellular functions.


Phosphatidylinositol
4,5-bisphosphate (PIP 2 ) is a phospholipid found in cell membranes, and has been indicated to play important roles in cytoskeletal organization, cell motility, transduction of extracellular signals, regulation of ion channels at the plasma membrane, endocytosis, phagocytosis, and endosome function. It has also been linked to cancer in humans (Di Paolo and De Camilli, 2006). PIP 2 can be hydrolyzed by membrane-bound phospholipase C beta into two second messengers, IP3 and diacylglycerol (DAG). Plasmalemmal cholesterol has been demonstrated to regulate PIP 2 hydrolysis and thus its cellular function in skin fibroblasts and pancreatic β-cells (Kwik et al., 2003;Hao and Bogan, 2009).
In this original research article, Hong et al. (2012) address the role of plasmalemmal cholesterol in regulating the localization and metabolism of PIP 2 in endothelial cells and the result on cell stiffness. They suggest that a decrease in cholesterol leads to disruption of PIP 2 hydrolysis, which in turn results in increased cross-links between the membrane and cytoskeleton via PIP 2 and increased cell stiffness. These results are important for understanding certain diseases, such as atherosclerosis, in which cholesterol levels are central to the pathology.
The mechanism by which cholesterol regulates PIP 2 in the plasma membrane may not be the same for different cell types. Cholesterol depletion in fibroblasts leads to decreased levels of PIP 2 in the plasma membrane, diminished membrane-cytoskeletal attachments, and decreased lateral motility (Kwik et al., 2003). Similarly, in cultured pancreatic β-cells, cholesterol depletion stimulates the hydrolysis of PIP 2 , thus reducing the amount of PIP 2 at the plasma membrane (Hao and Bogan, 2009). These findings are in contrast to a study using HEK293 cells, in which membrane cholesterol enrichment promoted PIP 2 depletion (Chun et al., 2010). Cholesterol depletion in lymphoblasts results in decreased lateral mobility of membrane proteins (Kwik et al., 2003). PIP 2 lateral mobility has been described as low in atrial myocytes, and high in HEK293 cells and fibroblasts (Epand, 2008). Therefore, cholesterol may regulate PIP 2 differently in various cell types.
Compartmentalization and regulation of PIP 2 metabolism within the plasma membrane may contribute to differences observed between cell types (Epand, 2008;Kwiatkowska, 2010). Cholesterolrich membrane microdomains (lipid rafts), which are known to be intimately involved in regulating a variety of G-protein coupled receptor-mediated functions, including those regulating PIP 2 metabolism (Allen et al., 2007), have bidirectional relationship with actin cytoskeleton. In response to external stimuli, G αq/11 subunits stimulate membrane-bound phospholipase C beta, which then cleaves PIP 2 into its two second messengers. Therefore, it is believed that the relationship among lipid raftassociated PIP 2 , G-proteins, and actin has strong implications in regulating actin assembly to modify cell shape and function. Conversely, actin associates with rafts and caveolae either as polymerized structures or as actin monomers, which might help to organize lipid raft domains and the molecules that are present in this structure to evoke a variety of cell signaling pathways in the cell interior (Caroni, 2001). Another exciting mechanism involves three proteins, namely GAP43, MARCKS, and CAP23, which accumulate at rafts, where they associate with PIP 2 , and promote its retention and clustering. By modulating PIP 2 at plasmalemmal rafts, GAP43, MARCKS, and CAP23 regulate cell cortex actin dynamics through a common mechanism. It is believed that, in response to local signals, these proteins dissociate from PIP 2 , creating local pools of free PIP 2 , which result in diverse intracellular responses.
Nonetheless, the mechanisms through which PIP 2 effector molecules mediate the various cellular responses to localized liberation of PIP 2 are mostly unknown. Investigations in this direction will foster our understanding of cholesterol-mediated PIP 2 intracellular functions.