Báo cáo khoa học: Separation and characterization of caveolae subclasses in the plasma membrane of primary adipocytes; segregation of specific proteins and functions docx

Abbreviations FATP, fatty acid transport protein; GLUT4, insulin-regulated glucose transporter; HD-caveolae, high-density caveolae; HDL, high-density lipoprotein; LD-caveolae, low-densit

the plasma membrane of primary adipocytes; segregation

of specific proteins and functions

Unn O¨ rtegren1

, Lan Yin1, Anita O¨ st1

, Helen Karlsson2, Fredrik H Nystrom3and Peter Stra˚lfors1

1 Department of Cell Biology and Diabetes Research Centre, University of Linko¨ping, Sweden

2 Department of Molecular and Clinical Medicine, University of Linko¨ping, Sweden

3 Department of Medicine and Care and Diabetes Research Centre, University of Linko¨ping, Sweden

Caveolae are defined by electron microscopy as

un-coated, omega- or flask-shaped invaginations of the

plasma membrane and also by the presence of the

structural protein caveolin (isoforms 1–3) [1]

Caveo-lin-1 and caveolin-2 are found in most cell types, inclu-ding adipocytes The caveolae membrane is rich in cholesterol and sphingomyelin [2–4] Adipocytes have

a very high number of caveolae in their plasma

Keywords

cholesterol; FATP; GLUT4; insulin

receptorSR-BI

Correspondence

P Stralfors, Department of Cell Biology,

Faculty of Health Sciences, SE58185

Linko¨ping, Sweden

Fax: +46 13 224314

Tel: +46 13 224315

E-mail: peter.stralfors@ibk.liu.se

(Received 7 April 2006, revised 27 April

2006, accepted 26 May 2006)

doi:10.1111/j.1742-4658.2006.05345.x

Caveolae are nearly ubiquitous plasma membrane domains that in adipo-cytes vary in size between 25 and 150 nm They constitute sites of entry into the cell as well as platforms for cell signalling We have previously reported that plasma membrane-associated caveolae that lack cell surface access can be identified by electron microscopy We now report the identifi-cation, after density gradient ultracentrifugation, of a subclass of very high-density apparently closed caveolae that were not labelled by cell sur-face protein labelling of intact cells These caveolae contained caveolin-1 and caveolin-2 Another class of high-density caveolae contained caveolin-1, caveolin-2 and specifically fatty acid transport protein-1, fatty acid transport protein-4, fatty acyl-CoA synthetase, hormone-sensitive lipase, perilipin, and insulin-regulated glucose transporter-4 This class of caveolae was specialized in fatty acid uptake and conversion to triacylglyc-erol A third class of low-density caveolae contained the insulin receptor, class B scavenger receptor-1, and insulin-regulated glucose transporter-4 Small amounts of these proteins were also detected in the high-density caveolae In response to insulin, the insulin receptor autophosphorylation and the amount of insulin-regulated glucose transporter-4 increased in these caveolae The molar ratio of cholesterol to phospholipid in the three caveolae classes varied considerably, from 0.4 in very high-density caveolae

to 0.9 in low-density caveolae There was no correlation between the caveo-lar contents of caveolin and cholesterol The low-density caveolae, with the highest cholesterol concentration, were particularly enriched with the cho-lesterol-rich lipoprotein receptor class B scavenger receptor-1, which medi-ated cholesteryl ester uptake from high-density lipoprotein and generation

of free cholesterol in these caveolae, suggesting a specific role in cholesterol uptake⁄ metabolism These findings demonstrate a segregation of functions

in caveolae subclasses

Abbreviations

FATP, fatty acid transport protein; GLUT4, insulin-regulated glucose transporter; HD-caveolae, high-density caveolae; HDL, high-density lipoprotein; LD-caveolae, low-density caveolae; LDL, low-density lipoprotein; SR-B1, class B scavenger receptor-1; sulfo-NHS-biotin, sulfo-N-hydroxysuccinimidyl-biotin; VHD-caveolae, very high-density caveolae; VLDL, very low-density lipoprotein.

membranes About one-third of the plasma membrane

of these cells constitutes caveolae membrane and the

caveolae vary considerably in size, from about 25 to

over 100 nm in diameter [5]

In adipocytes the insulin receptor resides in caveolae

[6,7], and insulin-stimulated uptake of glucose takes

place in caveolae after insulin-regulated glucose

trans-porter-4 (GLUT4) translocation to caveolae in the

plasma membrane [8,9] We recently reported that a

distinct class of caveolae in adipocytes harbour the

enzymatic machinery for synthesis of triacylglycerol

and represents a location for uptake of exogenous

fatty acids and their conversion to triacylglycerol [10]

We have earlier also reported that almost half of the

roughly 106caveolae in rat adipocytes are smaller than

about 50 nm in diameter [5] By labelling intact cells

with ruthenium red, which is electron dense and does

not permeate the plasma membrane, and examination

by electron microscopy we have demonstrated that

these caveolae are not open to the cell surface and the

surrounding medium [5] In contrast, the caveolae that

are larger than about 50 nm are labelled by ruthenium

red and are thus open cell surface caveolae [5] This

indicates the presence of additional specialized

sub-groups or classes of caveolin-containing membranes in

the plasma membrane

We now report the separation and biochemical

char-acterization of three classes of caveolae, which

demon-strate a segregation of functions in caveolae subclasses

Results

Primary rat adipocytes were homogenized and plasma

membranes isolated by differential and density

gradi-ent ultracgradi-entrifugation (Fig 1) The purified plasma

membrane fraction contained less than 1% of the cell’s

mitochondrial cytochrome oxidase and less than 7%

of the cell Golgi TGN38 protein, indicating a very

lim-ited contamination by other membrane fractions of the

purified plasma membrane [2]

Purified plasma membranes were disrupted by

soni-cation to release caveolae [2,11,12] and subjected to

lin-ear sucrose gradient ultracentrifugation Membranes in

collected fractions were pelleted and analysed for

cave-olin content by SDS⁄ PAGE and immunoblotting with

anticaveolin-1 antibodies A broad peak with a

shoul-der of caveolin suggested heterogeneity and the partial

separation of caveolin-containing membranes (Fig 2B)

Analysis of the specific protein and lipid composition

reported below demonstrated the presence of at least

three subclasses of caveolae, each with its specific

composition: a very high-density class of caveolae at

about 31% sucrose (VHD-caveolae; corresponding to

density¼ 1.11 gÆmL)1), and two caveolae classes of lower density, a high-density class of caveolae at about 25% sucrose (HD-caveolae; 1.09 gÆmL)1) and a low-density class of caveolae at about 18% sucrose (LD-caveolae; 1.06 gÆmL)1), respectively (Fig 2B) This should be compared to intact plasma membranes with

a density of 1.14 gÆmL)1 [13] It was not possible to attain complete separation of all three caveolae classes

in a sucrose gradient Utilizing a step sucrose gradient,

we demonstrated that the HD-caveolae and LD-caveo-lae can be separated and thus represent separate entities (Fig 3), although at the cost of the resolution from the caveolae at 31% sucrose

The distribution of caveolin-2 coincided with that

of caveolin-1 over all three caveolae (Fig 2C) Insulin did not affect the distribution between or amount of

Fig 1 Outline of the procedure used for isolation of caveolae sub-classes Also shown is the step at which other cellular fractions are removed.

B

C

D

E

F

G

H

I

J

K

L

Fig 2 Linear density gradient ultracentrifugal separation of closed and open invaginated plasma membrane caveolae Purified adipocyte plasma membranes were disrupted in alkaline carbonate buffer and subjected to sucrose density gradient ultracentrifugation as detailed in Experimental procedures Equal volumes of fractions were collected from the bottom of the tube, and membranes were collected by centrif-ugation and analysed for the distribution of indicated protein or EZ-Link-sulfo-NHS-LC-biotin labelling by SDS ⁄ PAGE and immunoblotting or avidin-labelled HRP, respectively The amounts of indicated proteins are expressed in arbitrary densitometric units and normalized to percent-age of maximum (A) Protein concentration (mgÆmL)1) (B) Caveolin-1 (C) Caveolin-2 (D) Cell surface biotin labelling of proteins (E) TGN38 (F) Insulin receptor (G) GLUT4 (H) Hormone-sensitive lipase (HSL) (I) FATP1 (J) FATP4 (K) Perilipin (L) SR-BI.

caveolin-1 in the different caveolae (Fig 4A) The

pro-tein profile mirrored the caveolin profile (Figs 2A and

4A), indicating that the caveolae fractions are not

con-taminated by noncaveolar membranes [2] Noncaveolar

membrane protein was found at the bottom of the

sucrose gradient (Fig 2A) By immunogold labelling

and transmission electron microscopy, membrane

vesi-cles in all three classes of caveolae were found to

con-tain caveolin-1 (Fig 5) In all three classes of caveolae,

the same fraction of membrane vesicles were labelled

against caveolin: VHD-caveolae 58 ± 3% (n¼ 13);

HD-caveolae 58 ± 5% (n¼ 12); LD-caveolae

59 ± 5% (n¼ 8) (mean ± SE, n ¼ number of grids

examined from two separate preparations)

We labelled the cell surface proteins of intact

adipocytes with sulfo-N-hydroxysuccinimidyl-biotin

(sulfo-NHS-biotin), which cannot penetrate the plasma

membrane, before isolation of the caveolin-containing membranes After SDS⁄ PAGE, blotting, and detection with horseradish peroxidase-labelled avidin, biotinylated

Fig 3 Separation of HD-caveolae and LD-caveolae by two-step

density gradient ultracentrifugation Purified adipocyte plasma

membranes were disrupted in alkaline carbonate buffer and

subjec-ted to step sucrose, density gradient ultracentrifugation: a sample

suspended in 45% sucrose was overlayered with 35%, 26% and

5% sucrose Equal volumes of fractions were collected from the

bottom of the tube, membranes were collected by centrifugation,

and analysed by SDS ⁄ PAGE and immunoblotting for the distribution

of caveolin (——), perilipin ( ), and SR-BI (– — –) The

HD-caveolae were collected at the 26 ⁄ 35% sucrose interphase and the

LD-caveolae at the 5 ⁄ 26% sucrose interphase.

A

B

C

Fig 4 Effects of insulin on caveolin-1, insulin receptor

autophosph-orylation, and GLUT4 translocation Isolated adipocytes were

incu-bated with (filled bars; insert lanes 4–6) or without (open bars;

insert lanes 1–3) 5 n M insulin for 20 min, after which caveolae were

prepared and separated by density gradient ultracentrifugation as in

Fig 2 Fractions corresponding to the three caveolae peaks were

analysed by SDS ⁄ PAGE and immunoblotting by loading equal

amounts of protein (lanes 1 and 4, VHD-caveolae; lanes 2 and 5,

HD-caveolae; lanes 3 and 6, LD-caveolae) The amount of the

analysed proteins is expressed as arbitrary densitometric units and

normalized to percentage of maximum (A) Caveolin-1 (B)

Tyrosine-phosphorylated insulin receptor b-subunit (C) GLUT4.

proteins were detected in the HD-caveolae and

LD-caveolae, particularly in the LD-caveolae, but there

was no labelling coinciding with the VHD-caveolae

(Fig 2D) As the sulfo-NHS-biotin reagent is negatively

charged and this may interfere with access to caveolae

and caveolar proteins, we repeated the experiment

with the noncharged TFP-PEO-biotin protein-labelling

reagent This produced protein labelling that was again limited to the HD-caveolae and LD-caveolae and especially the LD-caveolae (not shown) To examine whether the biotin labelling was restricted to the LD-caveolae, we separately subjected the higher-and lower-density half of the sulfo-NHS-biotin-labelled peak to a second density gradient ultracentrifugal separ-ation Each biotin-labelled density peak remained as a discrete entity, indicating that both HD-caveolae and LD-caveolae were subject to cell surface labelling (Fig 6)

SDS⁄ PAGE and silver staining of the three caveo-lin-containing membrane fractions showed that all three caveolae share a set of major proteins (Fig 7A) The major protein pattern also revealed that the indi-cated proteins with molecular masses of 75 kDa and

100 kDa were nearly absent from the VHD-caveolae and concentrated in the LD-caveolae Caveolin was enriched in all three caveolae fractions compared to the purified plasma membrane fraction (Fig 7B) TGN38, which is a trans-Golgi protein involved in trafficking to the plasma membrane, was present in the VHD-caveolae fractions (Fig 2E)

The insulin receptor was present in both HD-caveo-lae and LD-caveoHD-caveo-lae fractions, but was mainly concen-trated in the LD-caveolae (Fig 2F) The distribution

of the insulin receptor was not affected by insulin (not shown), although the receptor was tyrosine phosphor-ylated in response to insulin, predominantly in the LD-caveolae (Fig 4B)

The insulin-stimulated glucose transporter GLUT4

is present in low amounts in the plasma membrane, where it increases by translocation from intracellular locations in response to insulin stimulation of adipo-cytes [14,15] GLUT4 of the plasma membrane has been shown to mainly reside in caveolae under basal noninsulin-stimulated conditions and to translocate from intracellular stores to caveolae for glucose uptake

in response to insulin [8,9] Under basal noninsulin-stimulated conditions, GLUT4 was present mainly in the HD-caveolae (Fig 2G), but increased in response

to insulin in both the LD-caveolae and HD-caveolae, with the increase being particularly pronounced in the LD-caveolae (Fig 4C)

The presence of the triacylglycerol-hydrolysing enzyme hormone-sensitive lipase was identified specific-ally in the HD-caveolae (Fig 2H) The two fatty acid transport proteins FATP1 and FATP4 were largely confined to the HD-caveolae (Fig 2I,J) The triacyl-glycerol-synthesizing fatty acyl-CoA synthetase (not shown) [10] and the lipid-droplet protein perilipin (Fig 2K) were likewise confined to the HD-caveolae FATP1 has been found to translocate to the plasma

A

C

B

Fig 5 Immunogold labelling and electron microscopic visualization

of caveolin-1 in caveolae fractions Caveolae fractions from density

gradient ultracentrifugation were immunogold labelled against

cave-olin-1 and examined by transmission electron microscopy (A)

VHD-caveolae (B) HD-VHD-caveolae (C) LD-VHD-caveolae.

membrane in response to insulin stimulation of 3T3-L1

adipocytes, but much less so in primary rat adipocytes

[16] We found, however, no significant effect of

insulin on the amount of FATP1 in the plasma mem-brane or in caveolae (not shown)

Cholesterol, which is a critical and major component

of caveolae membranes [2,4], was, as expected, present

in all caveolae fractions The molar ratio of cholesterol

to phospholipid varied widely between the caveolae classes, however, from about 0.9 for the LD-caveolae

to about 0.4 for the VHD-caveolae (Table 1) Like-wise, the ratio of caveolin to cholesterol varied widely, being about six times lower in the LD-caveolae than in the closed VHD-caveolae (Table 1)

Interestingly, the class B type 1 scavenger receptor (SR-BI), which mediates uptake and efflux of choles-terol, was mainly found in the caveolae fraction with the highest concentration of cholesterol (Fig 2L) We confirmed the presence of SR-BI using different anti-bodies against the protein (see Experimental proce-dures), with the same results A functional role for the LD-caveolae in cholesterol metabolism was suggested

by a time-dependent uptake and hydrolysis of radiola-belled cholesteryl ester from high-density lipoprotein (HDL) in the LD-caveolae membrane (Fig 8) Uptake was apparently mediated by SR-BI, as it was inhibited

by the SR-BI inhibitor BLT-1 by 45% (not shown), which is similar to what has been reported for BLT-1 inhibition of SR-BI [17]

Discussion

Herein we have identified three caveolin-containing membrane fractions by their composition and cell sur-face accessibility, thus demonstrating the segregation

of proteins and functions in different classes of caveo-lae We refer to all three as caveolae, because we have earlier used immunogold labelling and electron

micro-Fig 6 Separate reseparation of cell surface biotin-labelled HD-caveolae and LD-caveolae by density gradient centrifugation Fractions con-taining HD-caveolae or LD-caveolae from the linear density gradient ultracentrifugation (corresponding to Fig 2 fractions 5 and 7, respect-ively) were separately subjected to a second round of linear density gradient ultracentrifugation, and analysed by SDS ⁄ PAGE and immunoblotting (A) HD-caveolae (B) LD-caveolae Caveolin-1 (——), cell surface biotin-labelled proteins (– – –).

A

B

Fig 7 Protein pattern and caveolin enrichment in caveolae

frac-tions (A) VHD-caveolae from density gradient ultracentrifugation

(lane a); HD-caveolae (lanes b1 and b2); LD-caveolae (lane c) a, b 1

and b2, and c were separately subjected to SDS ⁄ PAGE (9%

acryla-mide) and silver staining Indicated are apparent molecular masses

of reference proteins (B) SDS ⁄ PAGE and immunoblotting against

caveolin-1 of VHD-caveolae (lane 1), HD-caveolae (lane 2),

LD-caveolae (lane 3), and purified plasma membrane fraction (lane

4) Equal amounts of protein were subjected to analysis.

scopy to demonstrate that the localization of the

cave-olin in the plasma membrane of primary rat adipocytes

is found in caveolar structures, with negligible amounts

of caveolin in noninvaginated, nonvesicular structures

[5] Moreover, we herein used immunogold labelling

and electron microscopy to verify that membranes in

the sucrose density gradient, corresponding to all three

classes of caveolae, contained caveolin-1

The kinship between the three caveolae classes

iden-tified herein, which further justifies referring to all of

them as caveolae, was demonstrated by their content

of both caveolin-1 and caveolin-2 The coexistence of

caveolin-1 and caveolin-2 in all three caveolae

sub-classes is in line with earlier findings that caveolin-1

expression is a prerequisite for proper expression of

caveolin-2 [18] That at least three discrete classes of

caveolae were indeed identified was demonstrated by

both distinct subsets of specific proteins and

substan-tially different concentrations of cholesterol in them

In Table 1 we have summarized the composition of the three subclasses of caveolae

The three classes of caveolae were isolated from purified plasma membranes None of the three caveo-lae classes, which each represent about one-third of the caveolin, can for quantitative reasons therefore

be explained as contamination by other membrane fractions containing caveolin, such as Golgi mem-branes or lipid bodies that contain minor fractions of total adipocyte caveolin It needs to be kept in mind that all cellular membrane compartments communicate through continuous membranes or by vesicular traf-ficking, and therefore biochemically isolated mem-branes represent fractions of a continuum This is especially true for fractions of the plasma membrane where any fractionation is artificial and a complete separation based on density is unlikely Indeed, the classes of caveolae with specific functions overlap in terms of their constituents as well as in the sucrose gradient It was not possible to completely separate the caveolae subclasses, but their distinct identities were ascertained by using a step sucrose gradient that clearly demonstrated the presence of HD-caveolae and LD-caveolae (Fig 3) Overlapping densities were indi-cated by a small amount of the LD-caveolae protein SR-B1 (Fig 2L) collecting at the higher sucrose den-sity step together with the HD-caveolae and, likewise,

by the small amount of HD-caveolae protein perilipin (Fig 2K) collecting at the low-density step together

Table 1 Constituent proteins and lipids of three subclasses of

caveolae A compilation of components and properties.

Property

VHD-caveolae

HD-caveolae

LD-caveolae Approximate density

(gÆmL)1)

Enzymes of triacylglycerol

synthesis from fatty acids

Cholesterol

(lmolÆmg protein)1)

0.2 ± 0.01 0.4 ± 0.03 1.1 ± 0.1 Mean ± SE

(n ¼ 4 preparations) a

Phospholipids

(lmolÆmg protein)1)

0.4 ± 0.1 0.8 ± 0.1 1.2 ± 0.1 Mean ± SE

(n ¼ 3 preparations) a

Cholesterol ⁄ phospholipid

ratio (mol ⁄ mol)

Caveolin ⁄ cholesterol

relative ratio

a Measured in the indicated caveolae subclasses, represented by

fractions 3–4, 5–6, and 7, respectively, in Fig 2.

Fig 8 HDL cholesteryl ester uptake and conversion to free choles-terol Purified HDL with oleoyl-[ 3 H]cholesterol were prepared as

in Experimental procedures and incubated with isolated adipocytes for 2 min (open bars) or 10 min (closed bars), after which cells were homogenized and caveolae classes fractionated as in Fig 2 Fractions corresponding to the HD-caveolae or LD-caveolae were analysed for their content of free [ 3 H]cholesterol or oleoyl-[ 3 H]cho-lesterol by TLC.

with the LD-caveolae (Fig 3) It cannot be excluded

that additional classes of caveolae are hidden in the

partly separated peaks of caveolae defined herein Our

findings nevertheless clearly demonstrate the

segrega-tion of different funcsegrega-tions in different caveolae in the

adipocyte plasma membrane This identification of

caveolae subclasses can be compared with the initial

isolation and separation of subclasses of lipoproteins

from blood [e.g chylomicrons, very low-density

lipo-protein (VLDL), low-density lipoprotein (LDL)],

which were partially separated by gradient

ultracentrif-ugation as a crucial step in their identification and

definition This has been fundamental for

understand-ing cardiovascular disease

The concentration of cholesterol varied widely in the

three identified caveolae classes Also, the ratio of

caveolin to cholesterol varied widely, being about six

times lower in the LD-caveolae than in the closed

VHD-caveolae, demonstrating that factors other than

caveolin control the concentration of cholesterol in the

plasma membrane and its domains

Others have noticed two bands after sucrose

gradi-ent ultracgradi-entrifugation of the deterggradi-ent-resistant

resi-due of whole 3T3-L1 adipocytes, but only one was

found to represent caveolae [19] We have earlier

shown that detergent extraction is a poor method for

isolating caveolae from fat cells and that, for example,

the insulin receptor [6] and lipids are extracted with

the detergent [2], even at 0
C Two bands have also

been found after discontinuous sucrose gradient

cen-trifugation of a carbonate extract of rat adipocyte

plasma membranes [20]

VHD-caveolae lack cell surface access

The biotin labelling of cell surface proteins indicates

that the VHD-caveolae in particular, but to some

extent also the HD-caveolae, are not accessible to the

labelling reagents (negatively charged and uncharged)

This is fully supported by our previous electron

micro-scopic identification [5] of two morphologically distinct

classes of caveolae at the plasma membrane)

canon-ical caveolae that are open to the extracellular space

and caveolae lacking access from the cell surface

Closed caveolae have restricted access through

caveo-lae openings, and the presence of a ‘diaphragm’ over

some caveolae openings has indeed been demonstrated

by thin-section electron microscopy [21] However, we

cannot rule out the possibility that the lack of labelling

was due to these caveolae being void of cell surface

proteins

In addition to the high buoyant density, low

choles-terol concentration, and low cholescholes-terol to caveolin

ratio of the VHD-caveolae, these differed from the open caveolae in that they contained no or very little insulin receptor, SR-BI or GLUT4) membrane pro-teins that interact with extracellular ligands or sub-strates) or FATP1 and FATP4, which, presumably, bind fatty acids taken up in those caveolae [10] This again supports the interpretation that the VHD-caveo-lae are without cell surface access

We cannot exclude the possibility that these VHD-caveolae membranes originate intracellularly TGN38 was found in the fractions corresponding to the closed VHD-caveolae, and this protein is found in highest amount in Golgi and is involved in vesicle transport between the plasma membrane and the trans-Golgi network [22,23] Golgi⁄ microsomal contamination of the plasma membrane fraction may be the source of the small amounts of TGN38, but it is unlikely that the closed VHD-caveolae fraction is Golgi⁄ microsomal membrane, for the following reasons: (a) the ratio of TGN38 to caveolin content was 15 times higher in the microsomal fraction than in the VHD-caveolae frac-tion (not shown); (b) it has been reported that Golgi predominantly contains caveolin-2 [24–26], which was present in the VHD-caveolae with the same relation to caveolin-1 as in the HD-caveolae and LD-caveolae; (c) the VHD-caveolae contained almost a third of the plasma membrane caveolin, and the majority of cellu-lar caveolin is found in the plasma membrane of adipocytes; (d) the pattern of major proteins revealed

by SDS⁄ PAGE demonstrated a relation between the VHD-caveolae and HD-caveolae and LD-caveolae; and (e) closed caveolae without cell surface access have been demonstrated in the plasma membrane by elec-tron microscopy [5]

We do not know the function of this class of closed caveolae, but obvious possibilities are vesicular trans-port between the Golgi and plasma membrane, and a readily available pool of membrane and caveolin for replenishment and formation of open caveolae, or potocytosis [27] A related possibility is the recently described caveolae that cycle between fused and free forms, which remain close to the plasma membrane in

a volume limited by microfilaments [28]

HD-caveolae as sites of fatty acid uptake and triacylglycerol synthesis

We have previously used biochemical analysis, fluores-cence confocal microscopy and electron microscopy to identify the HD-caveolae as specific sites of fatty acid uptake and conversion to triacylglycerol, including the unique presence of fatty acyl-CoA synthetase and perilipin in these caveolae [10] These findings are here

corroborated by the identification of the fatty

acid-binding membrane proteins FATP1 and FATP4 in this

specific class of caveolae FATP1 and FATP4 are the

only FATP proteins expressed in adipocytes [16],

although very low levels of FATP2 mRNA have been

detected [16] Taken together, these findings strongly

implicate the HD-caveolae as specific sites of fatty acid

entry into the fat cells As previously pointed out [10],

the role of caveolae as gateways for fatty acid entry is

particularly relevant, since fatty acids are potent

deter-gents that dissolve cell membranes and lyse cells [29]

Owing to their relatively high detergent resistance,

caveolae are adapted to cope with the detergent

prop-erties of fatty acids

LD-caveolae as sites of cholesteryl ester uptake

The very high concentration of cholesterol in the

LD-caveolae, also when compared to the concentration

of caveolin, indicates a specific function in cholesterol

metabolism Such a notion is supported by the

abun-dance in this caveolae subclass of SR-BI, which

medi-ates binding of LDL and selective uptake of HDL

cholesteryl esters and the efflux of cholesterol [30,31]

SR-BI has previously been found in a

caveolin-enriched fraction of a cell line stably transfected with

the protein [32] As SR-BI has been difficult to identify

in adipocytes, despite very high levels of the

corres-ponding mRNA [33,34], we confirmed its presence in

the LD-caveolae peak with antibodies from two

differ-ent sources We also demonstrated that these caveolae

functioned in the uptake and hydrolysis of cholesteryl

ester from HDL The involvement of SR-B1 in this

uptake was indicated by the inhibition of the uptake

by the SR-BI inhibitor BLT-1

Conclusions

In conclusion, we demonstrate three subclasses of

caveolae with compositions that suggest their

involve-ment in specific processes at the plasma membrane

The HD-caveolae are apparently specialized in fatty

acid uptake and triacylglycerol synthesis [10], and the

LD-caveolae appear to be specifically involved in

cholesterol metabolism, while both classes have a role

in insulin-stimulated glucose uptake Further

investiga-tions are needed to determine the genesis and

func-tion(s) of the apparently closed VHD-caveolae vesicles

Obvious possibilities are Golgi–plasma membrane

vesicular transport, potocytosis [27], or a readily

avail-able pool of membrane and caveolin for formation of

open caveolae It will be important to elucidate the

functional and dynamic relationships between closed

and open caveolae, as well as how targeting and sequestration of the different proteins and lipids are regulated and maintained

Experimental procedures

Materials

Harlan Sprague Dawley rats (130–160 g) were obtained from B & K Universal (Sollentuna, Sweden) The animals were treated in accordance with Swedish animal care regu-lations Antibodies against insulin receptor b-subunit (rab-bit polyclonal) and caveolin-2 (mouse monoclonal) were from Santa Cruz Biotech (Santa Cruz, CA, USA), those against caveolin-1 (mouse monoclonal) were from Trans-duction Laboratories (Lexington, KY, USA), those against TGN38 (mouse monoclonal) were from Affinity Biorea-gents Inc (Golden, CO, USA), those against GLUT4 (rab-bit polyclonal) were from Biogenesis (Poole, UK) and those against SR-BI (rabbit polyclonal) were from Novus Biologi-cals (Littleton, CO, USA) Antibodies against FATP1 and FATP4 were a generous gift from A Stahl (Stanford Uni-versity School of Medicine), those against SR-BI were from

M Krieger (Massachusetts Institute of Technology), those against perilipin were from C Londos (National Institutes

of Health), those against hormone-sensitive lipase were from C Holm (Lund University), and those against fatty acyl-CoA synthetase were from JE Schaffer (Washington School of Medicine) EZ-link sulfo-NHS-LC-biotin and EZ-Link TFP-PEO-biotin were from Perbio⁄ Pierce (Tatten-hall, UK), and HRP-linked streptavidin was from Amer-sham Bisosciences (AmerAmer-sham, UK) Other chemicals were from Sigma-Aldrich (St Louis, MO, USA) or Boehringer Mannheim (Mannheim, Germany) or as indicated

Isolation and incubation of adipocytes

Adipocytes were isolated by collagenase digestion [35] Cells were kept in Krebs–Ringer solution (0.12 m NaCl, 4.7 mm KCl, 2.5 mm CaCl2, 1.2 mm MgSO4, 1.2 mm

KH2PO4) containing 20 mm Hepes, pH 7.40, 1% (w⁄ v) fatty acid-free BSA, 100 nm phenylisopropyladenosine, 0.5 UÆmL)1 adenosine deaminase and 2 mm glucose, at

37
C on a shaking water bath When indicated, cells were incubated with 5 nm insulin for 20 min before homogenization

To label plasma membrane proteins with biotin, adipo-cytes were incubated for 20 min at 13
C in the Krebs– Ringer solution with 0.1% (w⁄ v) fatty acid-free BSA and 0.5 mgÆmL)1 EZ-Link Sulfo-NHS-LC-biotin or EZ-Link TFP-PEO-biotin, as indicated Labelling was terminated by incubation for 10 min with 20 mm glycine Cells were washed three times with Krebs–Ringer solution, 1% (w⁄ v) fatty acid-free BSA and 20 mm glycine

Preparation of subfractions of caveolae

To prepare caveolae fractions without detergent [2],

adipo-cytes were homogenized in 10 mm Tris⁄ HCl, pH 7.4, 1 mm

EDTA, 0.5 mm EGTA, 0.25 m sucrose, 25 mm NaF, 1 mm

Na2-pyrophosphate, with protease inhibitors, 10 lm

leupep-tin, 1 lm pepstaleupep-tin, 1 lm aprotinin, 4 mm iodoacetate, and

50 lm phenylmethylsulfonyl fluoride using a motor-driven

Teflon⁄ glass homogenizer at room temperature Subsequent

procedures were carried out at 0–4
C Cell debris and nuclei

were removed by centrifugation (JA21, Beckman

Instru-ments, Fullerton, CA, USA) at 1000 g for 10 min A plasma

membrane-containing pellet, obtained by centrifugation

(JA21, Beckman) at 16 000 g for 20 min, was resuspended in

10 mm Tris⁄ HCl, pH 7.4, 1 mm EDTA and protease

inhibi-tors Purified plasma membranes, obtained by sucrose

den-sity gradient centrifugation, were pelleted and resuspended

in 0.5 m Na2CO3, pH 11, and sonicated with a probe-type

sonifier (Soniprep 150, MSE, Crawley, UK) for 3· 20 s

The homogenate was then adjusted to 40% (w⁄ v) sucrose in

12 mm Mes, pH 6.5, 75 mm NaCl, 0.25 m Na2CO3, made

into a linear sucrose gradient with 10% (w⁄ v) sucrose in

12 mm Mes, pH 6.5, 75 mm NaCl, 0.25 m Na2CO3, and

centrifuged at 200 000 g for 16–20 h in an SW41 rotor

(Beckman) Fractions of 1 mL were collected from the

bot-tom of the tube Caveolae purity has been documented

[2,12] A microsomal fraction was obtained as described [2]

SDS⁄ PAGE and immunoblotting

Membranes were pelleted by centrifugation, and after

SDS⁄ PAGE, separated proteins were electrophoretically

transferred to a polyvinylidene difluoride blotting

mem-brane (Immobilone-P, Millipore, Bedford, MA, USA) and

incubated with indicated antibodies When membranes were

reprobed after stripping bound antibodies, stripping

com-pleteness was ascertained by incubation with secondary

antibodies Bound antibodies were detected using ECL-plus

with HRP-conjugated anti-IgG as secondary antibodies

(Amersham Biosciences) Blots were quantitated by

chemi-luminiscence imaging (Las 1000, Fuji, Tokyo Japan)

Electron microscopy of immunogold-labelled

caveolae membranes

Membranes were collected on carbon formvar-covered nickel

grids by spotting a drop of indicated caveolae-containing

fractions from the ultracentrifugation sucrose gradient on

the grids After washing and fixation in 3%

paraformalde-hyde for 15 min, grids were air-dried Membranes on grids

were rehydrated and blocked in 5% (w⁄ v) BSA (BSA-c,

Aurion, The Netherlands), 1% (v⁄ v) normal goat serum, and

0.1% (w⁄ v) gelatine for 1 h at 37
C The grids were

incuba-ted with rabbit caveolin-1 polyclonal antibody overnight

at 4
C and then with secondary 15 nm colloidal

gold-conjugated goat antirabbit antibodies (Aurion) for 1 h at

37
C After washing, membranes on the grids were further fixed in 2% glutaraldehyde for 10 min and visualized with 1% (w⁄ v) uranylacetate Transmission electron microscopy was performed with a Jeol EX1200 TEM-SCAN (Tokyo, Japan)

Cholesteryl ester uptake from HDL and analysis

of cholesteryl ester hydrolysis

HDL3 was isolated from human blood as previously des-cribed [36,37] [1a,2a(n)-3H]Cholesteryl oleate (0.4 mCi) was dried on 20 mg of celite and incubated with HDL3(3 mL, about 1 mg of protein) overnight at 37
C under N2, and then the mixture was filtered (pore size 0.22 lm) The [1a,2a(n)-3H]cholesteryl oleate-HDL was added to the cells and incubated at 37
C Lipids were extracted from caveolae fractions using CHCl3⁄ CH3OH⁄ sample (1 : 1 : 0.9, v ⁄ v) Cholesterol and cholesteryl oleate were quantitated after separation by TLC developed in CHCl3⁄ CH3OH⁄ H2O (65 : 35 : 2.5, v⁄ v) for 2 cm and, after drying, in hexane ⁄ di-ethylether⁄ CH3COOH (70 : 30 : 1, v⁄ v) to the top of the plate Silica acid was scraped off plates, suspended in 0.2 mL

of methanol, and analysed for radioactivity by liquid scintil-lation To inhibit cholesteryl ester uptake, cells were incuba-ted with 100 lm BLT-1 (#5234221, Chembridge, San Diego,

CA, USA) for 30 min at 37
C prior to addition of HDL3, when radioactivity taken up by the cells was determined

Cholesterol determination

For determination of cholesterol content, membranes were pelleted by centrifugation and lipids extracted with 2-propanol Cholesterol was then quantitated spectrofluoro-metrically by measuring the amount of H2O2 produced

by cholesterol oxidase [38]

Phospholipid determination

For determination of phospholipid content, membranes were pelleted by centrifugation and lipids extracted with CHCl3⁄ CH3OH⁄ H2O (1 : 1 : 0.9, v⁄ v) Phospholipids were then determined as phosphate molybdate complexes after charring in perchloric acid, according to Fiske and Subar-row [39] and modified as in Svennerholm and Vanier [40]

Protein determination

Protein was quantitated using the protein quantitation kit Micro BCA from Pierce, with BSA as reference

Acknowledgements

We thank Drs A Stahl, M Krieger, C Londos,

C Holm, and J E Shaffer for generously sharing their