In contrast to transmembrane glycoproteins, surface molecules inserted into the plasma membrane via a glycosylphosphatidylinositol (GPI)¹ membrane anchor are confined to the outer leaflet of the plasma membrane and do not directly communicate with the cell interior (Low, 1989 ). However, several GPI-anchored proteins have been shown to be potent signal transducers, because their cross-linking leads to increased protein-tyrosine phosphorylation, calcium fluxes, gene expression, and cell activation and/or proliferation (Robinson, 1991 ). GPI-anchored proteins such as neurotrophic factor receptors transduce signals by ligand-induced interactions with transmembrane receptor protein-tyrosine kinases (PTKs) (Massague, 1996 ), whereas other GPI-anchored molecules such as CD87 (uPAR), CD16B (FcγRIIIB), and CD14 (lipopolysaccharide receptor) interact with integrins (Petty and Todd, 1996 ) and appear to signal via integrin-dependent pathways. For most other GPI-anchored proteins, signaling is presumed to require association with sphingolipid microdomains (Romagnoli and Bron, 1997 ; Stulnig et al., 1997 ), and their coprecipitation with Src family PTKs has been documented in hematopoietic (Stefanova et al., 1991 ), epithelial (Shenoy-Scaria et al., 1992 ), and neuronal (Zisch et al., 1995 ; Kunz et al., 1996 ) cells. The molecular nature of this indirect association between GPI-anchored receptors and Src kinases, however, remains unresolved.

Sphingolipid microdomains are thought to consist of clusters of sphingolipids that achieve a liquid-ordered state in the presence of cholesterol (Ahmed et al., 1997 ; Schroeder et al., 1998 ) and resist solubilization by nonionic detergents. Such sphingolipid microdomains can be isolated as low-density, buoyant membrane complexes in equilibrium sedimentation gradients (Brown, 1992 ) or as membrane vesicles by gel filtration chromatography (Hoessli and Rungger-Brändle, 1985 ; Draberova and Draber, 1993 ; Cinek et al., 1995 ). In cells where caveolae are morphologically detectable, detergent-resistant membrane domains are also enriched in caveolin, the caveolar coat protein. However, recent morphological and biochemical investigations have provided evidence that sphingolipid microdomains enriched in GPI-anchored proteins and caveolin are not identical to caveolae (Schnitzer et al., 1995 ; Liu et al., 1997 ; Doyle et al., 1998 ). Other observations suggest that in cells expressing caveolin, sphingolipid microdomains are located close to caveolae, and some of their components may translocate to caveolae after interaction with physiological agonists (Sevinsky et al., 1996 ) or antibodies (Fujimoto, 1996 ). In cells lacking caveolin expression, sphingolipid microdomains have been difficult to demonstrate morphologically, but biochemical evidence suggests their importance in signaling through GPI-anchored surface molecules (van den Berg et al., 1995 ; Stulnig et al., 1997 ) as well as certain transmembrane receptors (Field et al., 1997 ; Deans et al., 1998 ). Moreover, in vitro reconstitution of detergent-resistant membranes has been achieved by mixing sphingolipids and cholesterol in suitable proportions (Ahmed et al., 1997 ; Schroeder et al., 1998 ), and single-particle–tracking studies on whole cells have documented transient confinement of GPI-anchored receptors and glycosphingolipids in the plane of the membrane (Sheets et al., 1997 ; Simson et al., 1998 ). Very recently, physical and biochemical studies have demonstrated the existence of submicron-sized GPI-domains in the plasma membrane (Friederichson and Kurzchalia, 1998 ; Varma and Mayor, 1998 ).

In this study, we have examined the catalytic activity of the Lck and Fyn kinases in different plasma membrane fractions from lymphoma cells. We show that Lck and Fyn kinases appear to be differentially regulated in different plasma membrane microdomains. This regulation is independent of the membrane-associated CD45 tyrosine phosphatase but dependent on the specific membrane microenvironment in which the kinases reside.

Rat mAb against murine CD45 (mAb M1/9.3.4HL.2; ATCC TIB122), Thy-1.2 (mAb 30-H12; ATCC TIB107), and the heat-stable antigen (HSA) CD24 (M1/69.16.11.HL; ATCC TIB 125) were obtained from the American Type Culture Collection (Rockville, MD) and used as culture supernatants. Rat anti-murine CD26 hybridoma (H207.773) was a kind gift from Dr. H.-T. He (Center d’Immunologie, Institut National de la Santé et de la Recherche Médicale–Centre National de la Recherche Scientifique, Marseille, France). Rabbit polyclonal antibodies against Lck and Fyn and HRP-conjugated goat anti-mouse, goat anti-rat, and goat anti-rabbit immunoglobulin G were obtained from Santa Cruz Biotechnology (Santa Cruz, CA).

Ilangumaran et al., 1996

Arni et al., 1996

Figure 1 Methodology and terminology used in this study. P1798 murine T lymphoma cells (109) were homogenized in TKM buffer containing 73% (wt/vol) sucrose. Aliquots of the cell homogenate (equivalent to 150 × 106 cells), treated with detergent (more ...)

Ilangumaran et al., 1996

For measuring kinase activities in membrane vesicles with Thy-1 or Lck exposed on the vesicle surface, 1 ml of the GPI-enriched membrane pool was diluted twofold with TKM buffer and precleared with 100 μl of Pansorbin (Calbiochem) for 30–60 min at 4°C with constant mixing. After the addition of anti-Thy-1 (100 μl of culture supernatant) or anti-Lck (10 μl) antibodies, the samples were incubated for 1 h at 4°C. After adding 25 μl of protein A/G-agarose beads preblocked with BSA (Santa Cruz Biotechnology), the samples were incubated for a further 4–16 h at 4°C with gentle mixing. The immune complexes were sedimented, washed three times in TKM buffer and once in kinase buffer, and subjected to kinase assay as described above. To test the effects of lipids, purified lipids were dried under N₂ and added either as TX-100 mixed micelles, or in some cases as sonicated lipid vesicles in the absence of any detergent, to the membrane preparations and incubated for 15 min at 30°C before initiation of the kinase reaction.

Kamps and Sefton, 1989

Munoz and Marshall, 1990

Arni et al., 1996

Table 1 Effects of various detergents on the floatability of cell surface and intracellular membrane-associated molecules

We then examined how different detergents affect the recovery of membrane molecules in GPI-enriched membrane fractions by treating the cell homogenate before gradient centrifugation (Figure 1B). In addition to GPI-linked and transmembrane glycoproteins and intracellular kinases, we also followed the distribution of GM1 ganglioside in the density gradient fractions (Table 1). The proportion of buoyant Thy-1, HSA, CD26, and GM1 in fractions 3–5 (top) remained unchanged or increased after treatment with TX-100, NP-40, or CHAPS. On the other hand, OTG dissociated >50% of HSA and 30% of GM1 from the top fractions but did not affect the Thy-1 density distribution. Detergent treatment in general decreased the amounts of transmembrane type I CD45 recovered in the GPI-enriched buoyant fractions, whereas the recovery of type II transmembrane protein CD26, Lck, or Fyn was not significantly altered. A higher detergent-to-cell ratio dissociated more CD45, but not CD26 or the kinases, from the buoyant fractions (Ilangumaran et al., 1997 ). Only OTG moderately dissociated Lck. These results show that the association of GPI-linked proteins and membrane-associated intracellular PTKs with low-density membrane lipids are relatively resistant to most of the detergents used except OTG. The presence of GM1 ganglioside in the low-density fractions was also unaffected by detergents, except OTG, which has been reported to perturb interactions between sphingolipids (Melkonian et al., 1995 ).

Figure 2 Kinase activities in GPI-enriched membranes isolated using different detergents. Buoyant, GPI-enriched membranes (0.5 ml, equivalent to ~25 × 106 cells) from the same cell homogenate, untreated (None) or after treatment with indicated (more ...)

Total phosphotransferase assays on sedimented GPI-enriched membranes revealed strong phosphorylation of 40-, 58-, 59-, 60-, 80- to 85-, and 120-kDa proteins in TX-100–treated membranes (Figure 2C); longer exposure showed that most of these proteins were also phosphorylated in the untreated membranes, although much less efficiently (Figure 2C, right panel). NP-40– and CHAPS–treated membranes showed elevated kinase activities comparable to that of TX-100–treated ones (Figure 2C) but contained significantly more proteins (Figure 2A). OTG extraction dissociated most proteins from the buoyant membranes (Figure 2A) without loss of the kinases or their protein substrates (Figure 2C). Addition of detergents (at of the concentration added to the cell homogenate before gradient centrifugation) directly to the untreated GPI-enriched membranes enhanced the kinase activities in a similar manner (see Figure 5 and our unpublished results). The anti-phosphotyrosine blot showed that hyperphosphorylated bands (Figure 2D, arrowheads) corresponding to Src family PTKs (see Figure 4A) appear after an in vitro phosphotransferase assay using cold ATP only in the TX-100–treated membranes but not in untreated membranes (Figure 2D).

Figure 5 Detergent-induced enhancement of kinase activities in GPI-enriched membranes is further augmented by vanadate. Kinase activities in untreated GPI-enriched membranes from 25 × 106 cells were measured by in vitro phosphorylation as described in (more ...)

Figure 4 GPI-enriched membranes harbor both Tyr and Ser/Thr kinase activities. (A) Immunoprecipitation of Lck and Fyn kinases. After the kinase assay, [32P]ATP on TX-100–isolated, GPI-enriched membranes (as in Figure 2C, lane 2), phosphorylated (more ...)

These results suggested that the observed differences in kinase activities between untreated and detergent-treated GPI-enriched membranes are likely to result from modifications of the membrane environment caused by detergents. A direct effect of the detergents on the catalytic activity on the kinases is unlikely because all detergents tested influenced the membrane-associated tyrosine kinases only when used at a concentration above their critical micelle concentration in an all-or-none manner (our unpublished results). In case of a direct effect of the detergent on kinase activity, a dose-dependent increase in enzymatic activity would be expected with increasing detergent concentration, which was not the case.

It could be envisaged that the elevated kinase activities in detergent-isolated, GPI-enriched membranes were due to facilitated access of the ATP substrate to the intravesicular kinases rather than an increase in phosphotransferase activity per se. The marked differences in the effects of various detergents on the membrane-associated kinase activities (Figure 2C) already argue against this possibility, because all detergents at the concentration used (above their critical micellar concentration values) will permeabilize the vesicles to ATP equally well. To settle this point, we carried out kinase assays on membrane vesicles recovered from solid-phase anti-Lck, corresponding to vesicles in the inside-out orientation (i.e., containing the kinases on their exposed leaflet) and compared their activity with that of right-side-out vesicles isolated on solid-phase anti-Thy-1 antibodies. The marked quantitative difference in phosphotransferase activity between the untreated and detergent-treated buoyant membranes was manifest in both inside-out (anti-Lck–selected) and right-side-out (anti-Thy-1–selected) vesicles. Much fewer inside-out vesicles were recovered with anti-Lck, suggesting that GPI-enriched membrane vesicles are predominantly in the right-side-out orientation and are best retained on solid-phase anti-Thy-1. However, the qualitative differences among the various detergent-treated membranes were negligible in either anti-Thy-1– or anti-Lck–selected vesicles, both of which showed a very similar pattern of phosphoproteins (40, 58–60, and 80–85 kDa; Figure 3). The proportionally stronger labeling of the 80- to 85-kDa band in anti-Lck–precipitated vesicles suggests an intracellular orientation for this phosphoprotein similarly to Lck. Controls with antibody-free or irrelevant antibody-bound beads did not show any significant phosphorylation (our unpublished results).

Figure 3 Detergent-induced modulation of kinases activities in right-side-out and inside-out GPI-enriched membrane vesicles. One milliliter of the pooled GPI-enriched membrane fractions defined in Table 1 was immunoselected with anti-Thy-1 (A) or anti-Lck (B) (more ...)

Stefanova et al., 1991

Arni et al., 1993

Garnett et al., 1993

Minoguchi et al., 1994

Marie-Cardine et al., 1997

Deans et al., 1998

We also document the Tyr kinase activity in GPI-enriched membranes by direct phosphorylation of the exogenous Tyr kinase substrates enolase and α-casein (Figure 4C), and preincubation of the GPI-rich vesicles with genistein markedly reduced phosphorylation of Lck, Fyn, and the 80- to 85-kDa bands and completely abolished enolase phosphorylation at 100 μM (Figure 4E). Similar results have been obtained with herbimycin as an inhibitor. These results show that GPI-enriched membranes contain Tyr and Ser/Thr kinase activities that are both enhanced by nonionic detergents. The Ser/Thr kinase activity does not seem to include a conventional PKC, because it was not enhanced in the presence of Ca²⁺, phorbol myristate acetate, and phosphatidylserine (our unpublished results). The decrease in labeling of the 40-kDa phosphoprotein bands in response to genistein suggests that the Ser/Thr kinase activity may depend on Tyr phosphorylation.

Sieh et al., 1993

Gordon, 1991

Figure 6 Enzyme kinetics of PTK activity in GPI-enriched membranes isolated without or with TX-100. Untreated and TX-100–treated GPI-enriched membranes equivalent to 25 × 106 cells and originating from the same cell homogenate were sedimented and (more ...)

Rameh et al., 1995

Figure 7 Lipid analysis of untreated and TX-100–treated GPI-enriched membranes. Untreated (lane 2) and TX-100–treated (lane 3), GPI-enriched membranes pelleted from one gradient (150 × 106 cells) were suspended in 200 μl of water (more ...)

Figure 8 Native GPI domains contain negative regulators of the associated kinases. Untreated and TX-100–treated GPI-enriched membranes equivalent to 25 × 106 cells and originating from the same cell homogenate were sedimented and tested for in (more ...)

Arni et al., 1996

Ilangumaran et al., 1997

Ilangumaran and Hoessli, 1998

Arni et al., 1996

Arni et al., 1996

Figure 9 Kinase actvities in heavy membranes are augmented by detergents but not by membrane pore-forming agents or sonication. Aliquots of light and heavy membranes containing 5 μg of total proteins were assayed for total phosphotransferase activity alone (more ...)

In lymphocytes, cross-linking the GPI-anchored surface receptors leads to rapid tyrosine phosphorylation of several intracellular protein substrates, including the nonreceptor PTKs Lck and Fyn (Hsi et al., 1989 ; Thompson et al., 1989 ), and cellular activation (Fischer et al., 1990 ; Korty et al., 1991 ; Shenoy-Scaria et al., 1992 ; Lund-Johansen et al., 1993 ; Morgan et al., 1993 ; Rowan et al., 1994 ; Stulnig et al., 1997 ). Signaling through GPI-anchored receptors is thought to require Src family PTKs, because several of them have been coprecipitated with GPI-anchored receptors (Stefanova and Horejsi, 1991 ; Stefanova et al., 1991 ; Cinek and Horejsi, 1992 ; Thomas and Samelson, 1992 ; Bohuslav et al., 1993 ; Garnett et al., 1993 ; Hatakeyama et al., 1994 ; Skubitz et al., 1995 ). The wealth of reports documenting these associations suggested the existence of transmembrane mechanism(s) for linking the GPI-anchored receptors to Src family PTKs, confined respectively to the outer and inner leaflets of the plasma membrane, but the precise nature of this interaction remains largely unresolved (Robinson, 1991 ; Brown, 1993 ). Although putative transmembrane connectors have been identified for Thy-1 (Lehuen et al., 1995 ) and CD55 (Kuraya and Fujita, 1998 ), the quest for a transmembrane linker to connect GPI-anchored receptors in general to intracellular PTKs has not been rewarding.

In recent years it has become apparent that GPI-anchored proteins are enriched in specialized regions of the plasma membrane (variously designated glycolipid-enriched membranes [Rodgers and Rose, 1996 ], detergent-resistant membranes [Brown and Rose, 1992 ], Triton X-100–insoluble floating fractions [Kurzchalia et al., 1995 ], sphingolipid “rafts” [Simons and Ikonen, 1997 ], and GPI domains [Arni et al., 1996 ]), wherein substantial amounts of membrane-associated Src family PTKs are also included that could account for the signaling capacity of GPI-anchored receptors. Mechanisms underlying the targeting of the doubly acylated PTKs to GPI-enriched membrane domains have been studied in detail (Shenoy-Scaria et al., 1993 ; van’t Hof and Resh, 1997 ). Whether these membrane domains also represent a unique site for Src family PTKs in terms of their regulation (Arni et al., 1996 ; Rodgers and Rose, 1996 ; Kabouridis et al., 1997 ) is only beginning to be addressed. In this paper, we show that Lck and Fyn kinases are differentially regulated in different plasma membrane environments. In membrane microdomains containing both GPI-anchored and transmembrane proteins, the associated PTKs are down-regulated by a mixed, noncompetitive mechanism of inhibition. This inhibition mechanism is abrogated by nonionic detergents, most likely upon disruption of the membrane structure, and can be restored by adding back the intact membranes.

The doubly acylated Lck interacts with the plasma membrane throughout the inner leaflet and does not require transmembrane CD4 receptor for membrane localization (Bijlmakers et al., 1997 ). The Fyn kinase was shown to rapidly associate with membranes after synthesis and then to more slowly localize to detergent-resistant membranes (van’t Hof and Resh, 1997 ). In resting cells, clustering of PTKs has not been demonstrated in any particular membrane region, but accumulation of PTKs underneath agonist-induced clusters of sphingolipid microdomains has been documented after antibody-mediated cross-linking of sphingolipid microdomain components (Zisch et al., 1995 ; Harder et al., 1998 ). The submembrane topology of Lck seems to be important in determining the signaling interactions of the molecule. For instance, Lck fused with a transmembrane protein can mediate the early steps of signaling via the T-cell receptor; however, the later steps in the T-cell receptor signaling pathway were only carried out by the doubly acylated Lck bound to the plasma membrane through hydrophobic and electrostatic interactions (Kabouridis et al., 1997 ). These findings indeed suggest that the hydrophobic and electrostatic interaction of Src family PTKs with the inner leaflet (Murray et al., 1998 ) could influence the conformation of the kinase molecule and thereby affect the modular interactions with substrates and the catalytic activity. In this study, we provide evidence for modulation of PTK activity by the local membrane environment of the kinase in the absence of agonist- or antibody-induced aggregation of sphingolipid microdomains. The membrane environment influences both the overall catalytic activity (increased phosphotransferase activity and enolase tyrosine phosphorylation) and autophosphorylation (appearance of hyperphosphorylated bands).

Sphingolipid microdomains may be viewed as sphingolipid- and cholesterol-rich core structures surrounded by a membrane area containing both GPI-anchored and transmembrane proteins. GPI-anchored proteins are probably tightly bound to the core sphingolipids, and both GPI-anchored proteins and glycosphingolipids can associate with transmembrane receptors at the periphery of the core sphingolipid microdomains through lateral, extracellular (integrins; Petty and Todd, 1996 ), and intramembraneous (CD44; Neame et al., 1995 ) interactions. Upon detergent extraction, the majority of the phospholipids are solubilized, disrupting these lateral interactions to a variable extent and leaving behind the core of the “detergent-insoluble” sphingolipid domains, still buoyant in density gradients (Ilangumaran et al., 1997 ; Ilangumaran and Hoessli, 1998 ). However, under these conditions, the amount of Lck and Fyn recovered in association with the sphingolipid domains was not significantly increased, suggesting that PTKs are not artifactually included in the detergent-resistant framework after extraction. Limited amounts of core sphingolipid domains could also be recovered under detergent-free conditions in a multistep sucrose gradient as light membranes, which are highly enriched for GPI-anchored proteins and deficient in transmembrane proteins. PTKs in the core sphingolipid microdomains (TX-100–treated GPI-enriched membranes and light membranes) were considerably more active than PTKs in sphingolipid microdomains associated with transmembrane proteins (untreated GPI-enriched membranes and heavy membranes). The down-regulated PTKs in the latter were efficiently reactivated by the TX-100, NP-40, CHAPS, and OTG detergents but not by the pore-forming α-toxin and SLO toxins, whereas the optimally active PTKs in the core sphingolipid microdomains (light membranes) were only minimally perturbed by the detergents or the pore-forming toxins. This enhancement of PTK activity probably results from modification of the PTK membrane environment by detergents and cannot be attributed to increased availability of ATP to the kinases, because neither sonication nor the pore-forming toxins resulted in the kind of enhancement observed after detergent treatment. Moreover, this enhancing effect of detergents is also observed in the minority of “inside-out” vesicles that were recovered on solid-phase anti-Lck, in which the PTKs are directly facing the extravesicular medium.

Adding back the untreated GPI-enriched membranes to the TX-100–treated ones restored the inhibition of PTK activity in the latter, probably after fusion of detergent-treated and untreated vesicles. This is, however, not a space-filling effect of the added lipids, because many different lipids (phosphoglycerides and ceramides), added as sonicated lipid vesicles or lipid–detergent mixed micelles to fully active kinases in detergent-treated membranes, failed to restore this inhibition. Despite the striking effect of nonionic detergents on membrane-bound PTK activity, the enhancement of kinase activity is attributable to the membrane perturbation induced by the detergent rather than a direct effect of the detergent on the kinase itself. Independently of detergents, membrane fractions of different densities and lipid–protein contents exhibit very distinct levels of PTK activity (light versus heavy membranes; Arni et al., 1996 ). This distinction is further exemplified by the different responses of light and heavy membrane PTKs to detergents and pore-forming agents. The membrane environment of PTKs therefore appears to be an important regulator of their catalytic activity.

Src family PTKs are regulated by an intramolecular interaction between the Src homology 2 domain and the C-terminal phosphotyrosine residue that locks the kinase in an inactive conformation (Cooper and Howell, 1993 ). Dephosphorylation of this regulatory tyrosine by PTPases such as CD45 relieves this repression (Mustelin et al., 1989 ). Enhancement of the PTK activities associated with GPI-enriched membranes by PTPase inhibitor sodium orthovanadate strongly suggests that Lck and Fyn PTKs residing in sphingolipid microdomains are neither in a “locked,” inactive conformation (Sieh et al., 1993 ) nor activated by the PTPase CD45 at the periphery of the microdomains, as proposed earlier (Rodgers and Rose, 1996 ). Actually, when the association of CD45 with detergent-resistant membranes was diminished by TX-100, NP-40, CHAPS, or OTG, we observed an increase, rather than a decrease, in PTK activity, strongly suggesting that removal of CD45 from membranes does not compromise PTK activity. Src family PTKs can also be activated by allosteric mechanisms that disrupt the intramolecular modular interactions (Moarefi et al., 1997 ; Williams et al., 1998 ), which “open” the kinase from the locked conformation without dephosphorylating the C-terminal Tyr-505 (Hardwick and Sefton, 1997 ). In addition, the locked conformation of the Src kinases is not static, because intermittent opening and closing mediated by allosteric mechanisms is believed to allow transient activation (“breathing”) of the kinase (Cooper and Howell, 1993 ). Recent evidence showing simultaneous phosphorylation of the regulatory and activation domain Tyr residues on the same Lck molecule support this notion (Hardwick and Sefton, 1997 ). In fact, PTKs in untreated GPIenriched membranes appear to be modulated by novel regulatory mechanisms. Despite the complexity of the experimental system involving at least two PTKs and several substrates, our kinetic data suggest that PTKs in untreated GPI-enriched membranes are down-regulated by a mixed, noncompetitive type of inhibition. In this situation, a negative regulator influences both V_max and K_m through binding to a site distinct from the active site and allosterically modifies the substrate binding. The kinetic difference in PTK activity observed between untreated and TX-100–treated GPI-enriched membranes is likely to be encountered when the enzyme:inhibitor dissociation constant (K_I = [E][I]/[EI]) is greater than that of the enzyme-substrate:inhibitor (K′_I = [ES][I]/[ESI]), i.e., when the affinity of the inhibitor for the enzyme alone is less than for the enzyme–substrate complex. This would suggest that in untreated GPI-enriched membranes the Lck and Fyn kinases are in the activated state forming complexes with their substrates, and that inhibition of their activity is brought about by regulatory mechanisms acting on protein domains outside the catalytic site of the enzyme. This regulatory input, which is perturbed by detergents, appears to be dependent on the specialized lipid environment of the GPI-rich membrane domains rather than any single membrane constituent.

Based on these results, we propose a model in which the PTKs associated with GPI-enriched core sphingolipid microdomains are catalytically active, but those interacting with the glycerophospholipid-rich surroundings are down-modulated by regulatory inputs probably acting on the modular, noncatalytic domains of the kinases. Within the core of sphingolipid microdomains the detergent-resistant membrane environment rich in glycosphingolipids and GPI-anchored receptors appears to promote both optimal conditions for high PTK activity and a close interaction of PTKs with other membrane protein substrates (i.e. with the 80-kDa phosphoprotein), whereas in membrane environments of a less restricted composition (i.e., the sphingolipid microdomains abutting the glycerophospholipid-rich membrane region), PTKs become liable to many more regulatory inputs. The removal of transmembrane proteins and glycerophospholipids by nonionic detergents apparently relieves PTKs from those regulatory inputs and restores a membrane environment that resembles that of core sphingolipid microdomains. Cross-linking of the surface GPI-linked receptors or gangliosides would also lead to coalescence of the sphingolipid domains and presumably reduces the quantum of external regulatory inputs, resulting in the reactivation of the sphingolipid domain–associated PTKs.

Transmembrane receptors that interact with sphingolipid microdomains may also acquire signaling competence from the microdomains, as it was shown for the FcεRI receptor (Field et al., 1995 ; Stauffer and Meyer, 1997 ), CD44 (Ilangumaran et al., 1998 ), and CD20 (Deans et al., 1998 ). Although the association of the GPI-anchored proteins with sphingolipid microdomains is thought to arise from the interaction of GPI anchor acyl chains with glycosphingolipids, the nature of interaction of the transmembrane proteins with sphingolipid domains is less clear. The CD44 transmembrane domain seems to confer the capacity to associate with detergent-resistant membrane domains, because swapping of the transmembrane domain abolished this capacity (Neame et al., 1995 ). For other transmembrane proteins, the mechanisms of association with sphingolipid domains have not yet been defined, but the possibility of extracellular interactions with gangliosides or GPIanchored receptors such as those reported for integrins (Petty and Todd, 1996 ) could be envisaged. Cross-linking these transmembrane receptors would then cross-link the sphingolipid microdomains and signal via the active Src family kinases present at the inner face of such remodeled domains. Such dependence of the T-cell receptor pathway on the integrity of sphingolipid microdomains was documented in several recent studies (Romagnoli and Bron, 1997 ; Montixi et al., 1998 ; Xavier et al., 1998 ).

Our results lend support to the view that PTKs associated with sphingolipid microdomains indeed represent a unique pool of signaling molecules that are controlled by the microdomain structure of the bilayer. Mechanisms underlying the higher activity of Src family PTKs within the core sphingolipid domains and the nature of the inhibition exerted on kinases outside microdomains require further definition. Likewise, how the microdomain-associated pool of kinases is linked to physiological means of cellular stimulation will have to be studied specifically in each of the different systems in which GPI-anchored receptors and transmembrane proteins interacting with the microdomains are implicated in cellular activation.

We thank H. Chap (Institut National de la Santé et de la Recherche Médicale U 326, Toulouse, France) for experiments involving lipids and helpful discussions, K. Rose (Department de Biochimie Médicale, University of Geneva, Geneva, Switzerland) for help with enzyme kinetics, and M. Poincelet for excellent technical assistance. This work was supported by Swiss National Science Foundation grant 31-39-709-93, Swiss Cancer League grant 35-462-2-1997, and the Aargauische Krebsliga.