Metabolic organization in vascular smooth muscle: distribution and localization of caveolin-1 and phosphofructokinase

Vallejo, Johana; Hardin, Christopher D.

doi:10.1152/ajpcell.00483.2002

Cited by 18 publications

(18 citation statements)

References 68 publications

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“…The demonstration that CAV-1 functions as a scaffolding protein for the membrane recruitment of PFK is a very important step in elucidating the physical basis for glycolytic-membrane interactions and their role in the organization of carbohydrate metabolism as observed in our previous studies on VSM (59). Moreover, our studies are consistent with studies that have demonstrated that CAV-1 coimmunoprecipitates with PFK-M from 293T cells transiently overexpressing V5-tagged PFK-M (34).…”

Section: Discussionsupporting

confidence: 90%

“…In vascular smooth muscle, a compartmentation of glycolytic metabolism has been well established, and the role of caveolae in the compartmentation has been proposed (1). We have found previously that PFK appeared to colocalize with a fairly ubiquitous plasma membrane protein named caveolin-1 (CAV-1), consistent with a role for CAV-1 as an anchor for glycolysis to the plasma membrane (59). However, colocalization with confocal microscopy simply implies that two proteins are in close proximity.…”

Section: Discussionmentioning

confidence: 58%

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Expression of caveolin‐1 in lymphocytes induces caveolae formation and recruitment of phosphofructokinase to the plasma membrane

Vallejo

Hardin

2005

FASEB j.

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Compartmentation of carbohydrate metabolism has been shown in a wide range of tissues including reports of one compartment of glycolysis associated with the plasma membrane of cells. However, only in the erythrocyte has the physical basis for plasma membrane-associated glycolytic pathway been established. We have previously found that phosphofructokinase (PFK) appeared to colocalize with the fairly ubiquitous plasma membrane protein caveolin-1 (CAV-1), consistent with a role for CAV-1 as an anchor for glycolysis to the plasma membrane. To test the hypothesis that CAV-1 functions as a scaffolding protein for PFK, we transfected human lymphocytes (a cell without CAV-1 expression) with human CAV-1 cDNA. We demonstrate that expression of CAV-1 in lymphocytes results in the formation of caveolae at the plasma membrane and affects the subcellular localization of PFK by recruiting PFK to the plasma membrane. Targeting of PFK by CAV-1 also was validated by the significant colocalization between the proteins after transfection, which resulted in a correlation of 0.97 +/- 0.004 between the two fluorophores. This finding is significant in as much as it illustrates the CAV-1 feasibility of generating binding sites for glycolytic enzymes on the plasma membrane. We therefore conclude that CAV-1 functions as a scaffolding protein for PFK and that this may contribute to the elucidation of the basis for carbohydrate compartmentation to the plasma membrane in a wide variety of cell types.

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Section: Discussionsupporting

confidence: 90%

Section: Discussionmentioning

confidence: 58%

Expression of caveolin‐1 in lymphocytes induces caveolae formation and recruitment of phosphofructokinase to the plasma membrane

Vallejo

Hardin

2005

FASEB j.

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“…These recent studies have suggested that the mechanism of ouabain activation occurred through protein-protein interactions that had been previously shown for cardiac muscle and kidney epithelial cells (17,27,47). However, the cascade activates an hypertrophic pathway in cardiomyocytes and a proliferative pathway in the kidney cells.…”

Section: Discussionmentioning

confidence: 77%

“…The compound ␤-methyl-cyclodextrin has been shown to deplete membrane cholesterol (14,47). Thus if treatment of VSMCs would prevent the specific ouabain activation of ERK1/2, this would certainly lend credence to the suggestion that ouabain is activating the cascade via an interaction with a specific population of ␣ 1 -subunits.…”

Section: Colocalization Of Namentioning

confidence: 93%

Role of caveolae in ouabain-induced proliferation of cultured vascular smooth muscle cells of the synthetic phenotype

Liu

Abramowitz²,

Askari³

et al. 2004

American Journal of Physiology-Heart and Circulatory Physiology

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Role of caveolae in ouabain-induced proliferation of cultured vascular smooth muscle cells of the synthetic phenotype. Am J Physiol Heart Circ Physiol 287: H2173-H2182, 2004. First published July 15, 2004 doi:10.1152/ajpheart.00352.2004.-We have shown earlier that low concentrations of ouabain that do not perturb the ionic milieu can initiate proliferation of vascular smooth muscle cells (VSMCs) in the synthetic phenotype from three different species: canine, rodent, and human. This effect occurs by activation of Src and the epidermal growth factor receptor (EGFR), and thus supports the concept of an additional, nonionic, transducing function of the Na pump. The present study presents data suggesting that such activation occurs through specific Na pump sites localized to the caveolae, and subsequent interactions with selected signaling proteins resident within the same membrane microdomain. Our data show that at rest, 30% of the total number of Na pumps are concentrated within the caveolae. When the various VSMCs were treated with proliferating concentrations of ouabain, the key protein content in isolated caveolae was increased. However, the recruited proteins were different between the different tissues. Thus ouabain activated the recruitment of both the Na pump ␣ 1-subunit and EGFR in the caveolae from rat A7r5 cells, whereas in both human and canine cells, ouabain activated the recruitment of Src, with the caveolar content of the other proteins remaining constant. These data demonstrate that ouabain interacts with the ␣1-subunit of the Na pump that resides within the caveolar domain, and such interaction selectively recruits signal transducing proteins to this microdomain resulting in their activation, which is necessary for the initiation of the proliferative cascade. Na pump; ouabain signaling; vascular smooth muscle proliferation THE NA PUMP maintains normal ion gradients across the cell membrane of virtually all mammalian cells, and the mechanism of ion transport has been studied extensively for many years (7,21). Recently, however, it has become apparent that pump function can be modulated by a variety of interacting proteins with mechanisms other than enzymatic phosphorylation of PKA and PKC. Such protein modulators are the FXYD family of proteins, i.e., phospholemman (15, 16), the ␥-subunit (28), and corticosteroid hormone-induced factor (16), which have been known for some time but whose functions have only recently been delineated. Their interaction with the Na pump can alter affinity for both ATP and ions (42).However, these are not the only protein moieties that can interact with the pump. Recently, a number of studies have appeared indicating that the pump can also interact with proteins generally associated with the well-known growth-related transducing cascades. The functional manifestation of these pump-protein interactions are quite tissue specific (see below), and a common bond between all of these observations is that they are initiated by the binding of the cardiac glycoside inhibitor oua...

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“…K ATP channel microenvironment has been considered to be different from "bulk" cytosol as these channels exist in multimolecular complexes with [34][35][36][37][38] and are functionally regulated by many metabolic enzymes [39,40]. Glycolytic enzymes are specifically localized to caveolae [41]. It's been suggested that subsarcolemmal ATP may play an important role in activation of K ATP channels at relative high intracellular ATP [42].…”

Section: Discussionmentioning

confidence: 99%

Role for SUR2A in Coupling Cardiac K<sub>ATP</sub> Channels to Caveolin-3

Sun

Hu²

2010

Cell Physiol Biochem

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ATP-sensitive K⁺ channels in the heart are localized in the caveolae. However, little is known about the molecular mechanism underlying the caveolar targeting of those ion channels. The present study was designed to explore the molecular compositions involved in the interaction between cardiac K_ATP channels and caveolin-3. The HA-tagged wild-type (Kir6.2/SUR2A) or mutant K_ATP channel (Kir6.2C4A or Kir6.2Δ36) subunits were transiently transfected into COS-7 cells with or without caveolin-3. Both Kir6.2C4A and Kir6.2Δ36 are able to form tetrameric Kir6.2 channels on the cell membrane without SUR subunit. We demonstrated that caveolin-3 co-immunopreciptiated Kir6.2 in COS-7 cells transfected with Kir6.2/SUR2A/caveolin-3, whereas Kir6.2 was not detected in the caveolin-3 immunoprecipitates in cells transfected with either caveolin-3 or Kir6.2/SUR2A alone. In cells transfected with Kir6.2C4A/caveolin-3, Kir6.2C4A was detected with anti-HA antibody but at a significantly lower level in the caveolin-3 immunoprecipitates when compared with Kir6.2 detected in cells transfected with the Kir6.2/SUR2A/caveolin-3. Kir6.2C4A was not co-immunoprecipitated with caveolin-3 in cells transfected with caveolin-3 or Kir6.2C4A alone. The application of caveolin-3 scaffolding domain peptide, corresponding to amino acid residues 55-74 of caveolin-3, largely blocked the co-immunoprecipitation of caveolin-3 and Kir6.2/SUR2A octameric channels but did not prevent the co-immunoprecipitation of caveolin-3 and the Kir6.2 tetrameric channels. Disrupting caveolae with methyl-β-cyclodextrin significantly attenuated association of tetrameric Kir6.2 channels with caveolin-3. Immunofluorescence microscopy revealed that a higher percentage of cells showed significant colocalization of caveolin-3 with Kir6.2 than colocalization of caveolin-3 with Kir6.2C4A or Kir6.2Δ36. We further confirmed that in adult rat cardiac myocytes the association of endogenous octameric K_ATP channels with caveolin-3 was largely prevented by caveolin-3 scaffolding domain peptide but not control peptide. We concluded that SUR2A is important for coupling cardiac K_ATP channels to caveolin-3, possibly through the caveolin-3 scaffolding domain.

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Metabolic organization in vascular smooth muscle: distribution and localization of caveolin-1 and phosphofructokinase

Cited by 18 publications

References 68 publications

Expression of caveolin‐1 in lymphocytes induces caveolae formation and recruitment of phosphofructokinase to the plasma membrane

Expression of caveolin‐1 in lymphocytes induces caveolae formation and recruitment of phosphofructokinase to the plasma membrane

Role of caveolae in ouabain-induced proliferation of cultured vascular smooth muscle cells of the synthetic phenotype

Role for SUR2A in Coupling Cardiac K<sub>ATP</sub> Channels to Caveolin-3

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