脂筏在G蛋白偶联受体信号转导中的调控作用

脂筏是细胞上富含特殊脂质和蛋白质的微结构域.随着脂筏作为细胞膜上信号传导的平台的认识,这个特征化的区域受到了越来越多的关注.大量的研究已经显示脂筏参与G蛋白偶联受体信号转导的调控.通过精细的调节G蛋白偶联受体、G蛋白和下游信号效应物等信号元件的活性,脂筏可以影响信号转导的专一性和信号偶联的效率.本综述主要介绍脂筏对G蛋白偶联受体信号转导的调控机制的研究进展.     

Bacterial penetration of bladder epithelium through lipid rafts

Type 1 fimbriated Escherichia coli represents the most common human uropathogen, owing much of its virulence to invasion of the uroepithelium, which is highly impermeable due to the preponderance of uroplakins and highly ordered lipid components. We sought to elucidate the molecular basis for E. coli invasion of the bladder epithelium by employing human 5637 bladder epithelial cells, and we found the following: (i) intracellular E. coli associated with caveolae and lipid raft components; (ii) RNA(i) reduction of caveolin-1 expression inhibited bacterial invasion; (iii) a signaling molecule required for E. coli invasion was located in lipid rafts and physically associated with caveolin-1; (iv) bacterial invasion was inhibited by lipid raft disrupting/usurping agents. In the mouse bladder, the E. coli type 1 fimbrial receptor, uroplakin Ia, was located in lipid rafts, and lipid raft disruptors inhibited E. coli invasion. Cumulatively, E. coli uroepithelial invasion occurs through lipid rafts, which, paradoxically, contribute to bladder impermeability.     

Docosahexaenoic acid affects cell signaling by altering lipid rafts

With 22 carbons and 6 double bonds docosahexaenoic acid (DHA) is the longest and most unsaturated fatty acid commonly found in membranes. It represents the extreme example of a class of important human health promoting agents known as omega-3 fatty acids. DHA is particularly abundant in retinal and brain tissue, often comprising about 50% of the membrane's total acyl chains. Inadequate amounts of DHA have been linked to a wide variety of abnormalities ranging from visual acuity and learning irregularities to depression and suicide. The molecular mode of action of DHA, while not yet understood, has been the focus of our research. Here we briefly summarize how DHA affects membrane physical properties with an emphasis on membrane signaling domains known as rafts. We report the uptake of DHA into brain phosphatidylethanolamines and the subsequent exclusion of cholesterol from the DHA-rich membranes. We also demonstrate that DHA-induced apoptosis in MDA-MB-231 breast cancer cells is associated with externalization of phosphatidylserine and membrane disruption ("blebbing"). We conclude with a proposal of how DHA incorporation into membranes may control cell biochemistry and physiology.     

A role for lipid rafts in immune cell signaling

Cross-linking of surface receptors in hematopoietic cells results in the enrichment of these receptors in the rafts along with other downstream signaling molecules. A possible explanation how signal is transduced through the plasma membrane has arisen from the concept of raft. From the study of cellular responses in the plasma membrane which enrich members of the Src-family tyrosine kinase, rafts can function as centers of signal transduction by forming patches. Under physiological conditions, these elements synergize to transduce successfully a signal at the plasma membrane. Rafts are suggested to be important in controlling appropriate protein interactions in hematopoietic cells, and aggregation of rafts following receptor ligation may be a general mechanism for promoting immune cell signaling.     

Compartmentalization of integrin alpha6beta4 signaling in lipid rafts

Integrin alpha6beta4 signaling proceeds through Src family kinase (SFK)-mediated phosphorylation of the cytoplasmic tail of beta4, recruitment of Shc, and activation of Ras and phosphoinositide-3 kinase. Upon cessation of signaling, alpha6beta4 mediates assembly of hemidesmosomes. Here, we report that part of alpha6beta4 is incorporated in lipid rafts. Metabolic labeling in combination with mutagenesis indicates that one or more cysteine in the membrane-proximal segment of beta4 tail is palmitoylated. Mutation of these cysteines suppresses incorporation of alpha6beta4 in lipid rafts, but does not affect alpha6beta4-mediated adhesion or assembly of hemidesmosomes. The fraction of alpha6beta4 localized to rafts associates with a palmitoylated SFK, whereas the remainder does not. Ligation of palmitoylation-defective alpha6beta4 does not activate SFK signaling to extracellular signal-regulated kinase and fails to promote keratinocyte proliferation in response to EGF. Thus, compartmentalization in lipid rafts is necessary to couple the alpha6beta4 integrin to a palmitoylated SFK and promote EGF-dependent mitogenesis.     

Cytoskeleton keratin regulation of FasR signaling through modulation of actin/ezrin interplay at lipid rafts in hepatocytes

FasR stimulation by Fas ligand leads to rapid formation of FasR microaggregates, which become signaling protein oligomerization transduction structures (SPOTS), through interactions with actin and ezrin, a structural step that triggers death-inducing signaling complex formation, in association with procaspase-8 activation. In some cells, designated as type I, caspase 8 directly activates effector caspases, whereas in others, known as type II, the caspase-mediated death signaling is amplified through mitochondria. Keratins are the intermediate filament (IF) proteins of epithelial cells, expressed as pairs in a lineage/differentiation manner. Hepatocyte IFs are made solely of keratins 8/18 (K8/K18), the hallmark of all simple epithelia. We have shown recently that in comparison to type II wild-type (WT) mouse hepatocytes, the absence of K8/K18 IFs in K8-null hepatocytes leads to more efficient FasR-mediated apoptosis, in link with a type II/type I-like switch in FasR-death signaling. Here, we demonstrate that the apoptotic process occurring in type I-like K8-null hepatocytes is associated with accelerated SPOTS elaboration at surface membrane, along with manifestation of FasR cap formation and internalization. In addition, the lipid raft organization is altered in K8-null hepatocytes. While lipid raft inhibition impairs SPOTS formation in both WT and K8-null hepatocytes, the absence of K8/K18 IFs in the latter sensitizes SPOTS to actin de-polymerization, and perturbs ezrin compartmentalization. Overall, the results indicate that the K8/K18 IF loss in hepatocytes alters the initial FasR activation steps through perturbation of ezrin/actin interplay and lipid raft organization, which leads to a type II/type I switch in FasR-death signaling.     

Imaging lipid rafts

Lipid rafts are plasma membrane microdomains enriched in sphingolipids and cholesterol. These domains have been suggested to serve as platforms for various cellular events, such as signaling and membrane trafficking. However, little is known about the distribution and dynamics of lipids in these microdomains. Here we report investigations carried out using recently developed probes for the lipid components of lipid rafts: lysenin, a sphingomyelin-binding protein obtained from the coelomic fluid of the earthworm Eisenia foetida; and the fluorescein ester of poly(ethyleneglycol) cholesteryl ether (fPEG-Chol), which partitions into cholesterol-rich membranes. Lysenin reveals that the organization of sphingomyelin differs between different cell types and even between different membrane domains within the same cell. When added to live cells, fPEG-Chol is distributed exclusively on the outer leaflet of the plasma membrane and is clustered dynamically upon activation of receptor signaling. The surface-bound fPEG-Chol is slowly internalized via a clathrin-independent pathway into endosomes with lipid raft markers.     

Full CD3/TCR activation through cholesterol-depleted lipid rafts

Exogenous bacterial sphingomyelinase (SMase) and C6-Ceramides (C6-Cer) considerably lower buoyant cholesterol on sucrose density-gradient (at least 55% less cholesterol). In opposition, short C2-Cer fails to displace buoyant cholesterol. Note that neither SMase nor C6-Cer delocalize raft markers (Lck, LAT, CD55, and GM1). They are still anchored in ceramides-rich/cholesterol-poor domains, demonstrating that cholesterol is not necessary for their buoyancy. SMase-treated cells, i.e. cells exhibiting cholesterol-depleted rafts, optimally transmit CD3-induced phosphorylations (tyrosine, threonine, and serine). SMase, that extracts and partially displaces buoyant cholesterol, does not inhibit PLCgamma1-LAT interaction, Vav 1 phosphorylation, the actin polymerization, IL-2 and NF-kappaB (EMSA and luciferase assays) activation, and CD25 up-regulation (RT-PCR and cytometry) at all. Nevertheless, Ca(2+) influx and diacylglycerol (palmitoyl-DAG and arachidonoy-DAG) production are lowered. The drop of CD3-induced Ca(2+) influx is due to a strong plasma membrane depolarization because of Cer. The decreased DAG level is a consequence of the drop of intracellular Ca(2+) that is a cofactor for the PLCgamma1. In conclusion, our study challenges the real role of cholesterol-rich rafts in CD3/TCR signaling and suggests that other membrane domains than cholesterol-rich rafts can optimally transmit CD3/TCR signals.     

Membrane organization and lipid rafts

Cell membranes are composed of a lipid bilayer, containing proteins that span the bilayer and/or interact with the lipids on either side of the two leaflets. Although recent advances in lipid analytics show that membranes in eukaryotic cells contain hundreds of different lipid species, the function of this lipid diversity remains enigmatic. The basic structure of cell membranes is the lipid bilayer, composed of two apposing leaflets, forming a two-dimensional liquid with fascinating properties designed to perform the functions cells require. To coordinate these functions, the bilayer has evolved the propensity to segregate its constituents laterally. This capability is based on dynamic liquid-liquid immiscibility and underlies the raft concept of membrane subcompartmentalization. This principle combines the potential for sphingolipid-cholesterol self-assembly with protein specificity to focus and regulate membrane bioactivity. Here we will review the emerging principles of membrane architecture with special emphasis on lipid organization and domain formation.     

GPI-anchored proteins and lipid rafts

Several proteins are anchored to membranes via a post-translational lipid modification, the glycosylphosphatidylinositol (GPI) anchor. In mammals and other vertebrates, GPI-anchored proteins have been found in almost all tissues and cells examined. Several studies have provided significant insight into the functions of this ubiquitous modification. An intriguing relevant feature of GPI-anchored proteins is their association with lipid rafts, specialized regions of elevated cholesterol and sphingolipid content, that are present within most cell membranes. In addition to the structure and biosynthesis of the GPI-anchor, recent researches have focused on its molecular interaction with lipid rafts and the biological meaning of such interaction. The aim of this review is to examine the emerging evidences of association between lipid rafts and GPI-anchored proteins, and their relationship with the modulation of important cellular functions such as protein/lipid sorting, signaling mechanisms and with human disease.     

Aggregation of lipid rafts accompanies signaling via the T cell antigen receptor.

The role of lipid rafts in T cell antigen receptor (TCR) signaling was investigated using fluorescence microscopy. Lipid rafts labeled with cholera toxin B subunit (CT-B) and cross-linked into patches displayed characteristics of rafts isolated biochemically, including detergent resistance and colocalization with raft-associated proteins. LCK, LAT, and the TCR all colocalized with lipid patches, although TCR association was sensitive to nonionic detergent. Aggregation of the TCR by anti-CD3 mAb cross-linking also caused coaggregation of raft-associated proteins. However, the protein tyrosine phosphatase CD45 did not colocalize to either CT-B or CD3 patches. Cross-linking of either CD3 or CT-B strongly induced tyrosine phosphorylation and recruitment of a ZAP-70(SH2)(2)-green fluorescent protein (GFP) fusion protein to the lipid patches. Also, CT-B patching induced signaling events analagous to TCR stimulation, with the same dependence on expression of key TCR signaling molecules. Targeting of LCK to rafts was necessary for these events, as a nonraft- associated transmembrane LCK chimera, which did not colocalize with TCR patches, could not reconstitute CT-B-induced signaling. Thus, our results indicate a mechanism whereby TCR engagement promotes aggregation of lipid rafts, which facilitates colocalization of LCK, LAT, and the TCR whilst excluding CD45, thereby triggering protein tyrosine phosphorylation.     

G(s) signaling is intact after disruption of lipid rafts.

Membrane microdomains enriched in cholesterol and sphingolipids modulate a number of signal transduction pathways and provide a residence for heterotrimeric G proteins, their receptors, and their effectors. We investigated whether signaling through G(s) was dependent on these membrane domains, characterized by their resistance to detergents, by depleting cells of cholesterol and sphingolipids. For cholesterol depletion, rat salivary epithelial A5 cells were cultured under low-cholesterol conditions, and then treated with the cholesterol chelator methyl-beta-cyclodextrin. For sphingolipid depletion, LY-B cells, a mutant CHO cell line that is unable to synthesize sphingolipids, were incubated under low-sphingolipid conditions. Depletion of cholesterol or sphingolipid led to a loss or decrease, respectively, in the amount of Galpha(s) from the detergent-resistant membranes without any change in the cellular or membrane-bound amounts of Galpha(s). The cAMP accumulation in response to a receptor agonist was intact and the level slightly increased in cells depleted of cholesterol or sphingolipids compared to that in control cells. These results indicate that localization of Galpha(s) to detergent-resistant membranes was not required for G(s) signaling. Analysis of the role of lipid rafts on the kinetics of protein associations in the membrane suggests that compartmentalization in lipid rafts may be more effective in inhibiting protein interactions and, depending on the pathway, ultimately inhibit or promote signaling.     

Leaky guts and lipid rafts

The intestinal epithelium functions as a physical barrier separating luminal microorganisms from the underlying immune system. There is compelling evidence that several intestinal diseases are associated with the translocation of commensal bacteria across the epithelial barrier. Recent work has identified a novel mechanism by which normally non-invasive enteric bacteria breach the intestinal epithelium during periods of inflammation.     

Effect of docosahexaenoic acid on interleukin-2 receptor signaling pathway in lipid rafts

Recent studies have shown that polyunsaturated fatty acids (PUFA) regulated the functions of membrane receptors in T cells and suppressed T cell-mediated immune responses. But the molecular mechanisms of immune regulation are not yet elucidated. Lipid rafts are plasma membrane microdomains, in which many receptors localized. The purpose of this study was to investigate the effect of DHA on IL-2R signaling pathway in lipid rafts. We isolated lipid rafts by discontinuous sucrose density gradient ultracentrifugation, and found that DHA could change the composition of lipid rafts and alter the distribution of key molecules of IL-2R signaling pathway, which transferred from lipid rafts to detergent-soluble membrane fractions. These results revealed that DHA treatment increased the proportion of polyunsaturated fatty acids especially n−3 polyunsaturated fatty acids in lipid rafts and changed the lipid environment of membrane microdomains in T cells. Compared with controls, DHA changed the localization of IL-2R, STAT5a and STAT5b in lipid rafts and suppressed the expression of JAK1, JAK3 and tyrosine phosphotyrosine in soluble membrane fractions. Summarily, this study concluded the effects of DHA on IL-2R signaling pathway in lipid rafts and explained the regulation of PUFAs in T cell-mediated immune responses.     

Spatial and temporal patterns of ERK signaling during mouse embryogenesis

Signaling between tissues is essential to form the complex, three-dimensional organization of an embryo. Because many receptor tyrosine kinases signal through the RAS-MAPK pathway, phosphorylated ERK can be used as an indicator of when and where signaling is active during development. Using whole-mount immunohistochemistry with antibodies specific to phosphorylated ERK1 and ERK2, we analyzed the location, timing, distribution, duration and intensity of ERK signaling during mouse embryogenesis (5-10.5 days postcoitum). Spatial and temporal domains of ERK activation were discrete with well-defined boundaries, indicating specific regulation of signaling in vivo. Prominent, sustained domains of ERK activation were seen in the ectoplacental cone, extra-embryonic ectoderm, limb buds, branchial arches, frontonasal process, forebrain, midbrain-hindbrain boundary, tailbud, foregut and liver. Transient activation was seen in neural crest, peripheral nervous system, nascent blood vessels, and anlagen of the eye, ear and heart. In the contiguous domains of ERK signaling, phospho-ERK staining was cytoplasmic with no sign of nuclear translocation. With few exceptions, the strongest domains of ERK activation correlated with regions of known or suspected fibroblast growth factor (FGF) signaling, and brief incubation with an inhibitor of the fibroblast growth factor receptor (FGFR) specifically diminished the phospho-ERK staining in these regions. Although many domains of ERK activation were FGFR-dependent, not all domains of FGF signaling were phospho-ERK positive. These studies identify key domains of sustained ERK signaling in the intact mouse embryo, give significant insight into the regulation of this signaling in vivo and pinpoint regions where downstream target genes can be sought.     

Effect of docosahexaenoic acid on interleukin-2 receptor signaling pathway in lipid rafts

PUFAs have been shown to mediate immune re-sponse especially the functions of T cells[1]. Recent researches have demonstrated that PUFAs can in-crease membrane fluidity and modify the functions of membrane receptors and enzymes in T cell membra-ne[2,3]. M…