High-polarity Mycobacterium avium-derived lipids interact with murine macrophage lipid rafts

Cholesterol- and sphingolipid-rich membrane microdomains (lipid rafts) are widely recognized as portals for pathogenic micro-organisms. A growing body of evidence demonstrates mobilization of host plasma cell membrane lipid rafts towards the site of contact with several pathogens as well as a strict dependence on cholesterol for appropriate internalization. The fate of lipid rafts once the pathogen has been internalized and the nature of the pathogen components that interact with them is however less understood. To address both these issues, infection of the J774 murine cell line with Mycobacterium avium was used as a model. After demonstrating that M. avium induces lipid raft mobilization and that M. avium infects J774 by a cholesterol-dependent mechanism, it is shown here that mycobacterial phagosomes harbour lipid rafts, which are, at least in part, of plasma cell membrane origin. On the other hand, by using latex microbeads coated with any of the three fractions of M. avium-derived lipids of different polarity, we provide evidence that high-polarity, in contrast to low-polarity and intermediate-polarity, mycobacterial lipids or uncoated latex beads have a strong capacity to induce lipid raft mobilization. These results suggest that high-polarity mycobacterial lipid(s) interact with host cell cholesterol-enriched microdomains which may in turn influence the course of infection.     

The role of lipid rafts in LPS-induced signaling in a macrophage cell line

The significance of lipid rafts in lipopolysaccharide (LPS) signaling in macrophages was studied through isolation of them by gradient centrifugation and subsequent visualization of signal molecules using antibodies. LPS signaling is initiated by binding to Toll-like receptor-4 (TLR4) and the co-receptor CD-14, leading to activation of downstream targets, such as MAP kinases. In this study, we show that LPS causes translocation of CD-14 and MAP kinases (ERK-2 and p38) to lipid rafts in the macrophage cell line RAW 264.7. The adaptor proteins MyD88 and Gab-2, on the other hand, were not detected in the lipid raft fractions. These results indicate that lipid rafts play a role in LPS-induced signaling in macrophages.     

Recent controversy surrounding lipid rafts

Lipid rafts (LRs)are highly enriched in glycosphingolipids, sphingomyelins, and cholesterol membrane microdomains, existing in a liquid-ordered phase of the plasma membrane. In the literature, LRs are also known as detergent-insoluble membranes, detergent-resistant membranes, glycosphingolipids-enriched membranes, detergent-insoluble glycolipid-rich membranes, and Triton-insoluble floating fractions. These properties enabled their separation from the rest of the phospholipid bilayer, providing new insight into the structure of the plasma membrane, which until then was believed to represent a two-dimensional liquid structure with proteins uniformly solubilized in the lipid solvent. Although there have been many articles concerning LRs, there is still controversy about their existence in the natural state, their size, definition, and function. Different techniques have been developed to visualize LRs in living cells, but the results are contradictory. In this minireview, some recent papers concerning LRs, their existence in vivo, their dynamics, size, methods of isolation, and their association with different proteins are discussed.     

Lymphocyte lipid rafts: structure and function

Evidence has accumulated over the past few years to suggest that specialized plasma membrane regions enriched in cholesterol and glycolipids, called 'lipid rafts', are primarily involved in the initiation and propagation of the signal transduction cascade associated with lymphocyte activation. Considering the multitude of recent and often contradictory data, however, it appears that a critical reconsideration of the role of lipid rafts in lymphocyte activation is necessary and timely, particularly in light of a series of new experimental results that challenge the traditional view of the role of lipid rafts in lymphocyte activation.     

Contribution of metabolic reprogramming to macrophage plasticity and function

Macrophages display a spectrum of functional activation phenotypes depending on the composition of the microenvironment they reside in, including type of tissue/organ and character of injurious challenge they are exposed to. Our understanding of how macrophage plasticity is regulated by the local microenvironment is still limited. Here we review and discuss the recent literature regarding the contribution of cellular metabolic pathways to the ability of the macrophage to sense the microenvironment and to alter its function. We propose that distinct alterations in the microenvironment induce a spectrum of inducible and reversible metabolic programs that might form the basis of the inducible and reversible spectrum of functional macrophage activation/polarization phenotypes. We highlight that metabolic pathways in the bidirectional communication between macrophages and stromals cells are an important component of chronic inflammatory conditions. Recent work demonstrates that inflammatory macrophage activation is tightly associated with metabolic reprogramming to aerobic glycolysis, an altered TCA cycle, and reduced mitochondrial respiration. We review cytosolic and mitochondrial mechanisms that promote initiation and maintenance of macrophage activation as they relate to increased aerobic glycolysis and highlight potential pathways through which anti-inflammatory IL-10 could promote macrophage deactivation. Finally, we propose that in addition to their role in energy generation and regulation of apoptosis, mitochondria reprogram their metabolism to also participate in regulating macrophage activation and plasticity.     

Role of lipid rafts in T cells

The plasma membrane of T cells is made up of a combination of phospholipids and proteins organized as glycolipoprotein microdomains termed lipid rafts. The structural assembly of lipid rafts was investigated by various physical and biochemical assays. Depending on the differentiation status of T cells, the lipid rafts seclude various protein receptors instrumental for the early T cell signaling, cytoskeleton reorganization, protein and membrane trafficking, and the entry of infectious organisms into the cells. This review article summarizes recent information on the assembly of lipid rafts in plasma membrane of T cells and their signaling output in mature and thymic precursors towards cell growth and differentiation, and possible modalities by which the function of lipid rafts can be altered by drugs and T cell ligands. The concept of using lipid rafts as a target for pharmaceutical compounds and biological T cell ligands to ultimately alter the T cell function is discussed.     

Analysis of lipid rafts in T cells

The plasma membrane of T cells is made of a combination of glycosphingolipids and protein receptors organized in glycolipoprotein microdomains termed lipid rafts. The structural assembly of lipid rafts was investigated by various physical and biochemical assays. Depending on the differentiation status of T cells, the lipid rafts seclude various protein receptors involved in T cell signaling, cytoskeleton reorganization, membrane trafficking, and the entry of infectious organisms into the cells. This review article summarizes the most common methods, and their limits and advantages for analyzing the composition and assembly of lipid rafts with protein receptors into lipid rafts microdomains in plasma membrane of T cells. It also includes new methods such as ELISA/Polysorp and flow cytometry, and a combined sucrose gradient centrifugation-FPLC-Western blot strategy developed in our laboratory to study non-covalent interactions between the GM1 glycosphingolipid and protein receptors in plasma membrane of T cells.     

Oxidative stress, lens gap junctions, and cataracts

The eye lens is constantly subjected to oxidative stress from radiation and other sources. The lens has several mechanisms to protect its components from oxidative stress and to maintain its redox state, including enzymatic pathways and high concentrations of ascorbate and reduced glutathione. With aging, accumulation of oxidized lens components and decreased efficiency of repair mechanisms can contribute to the development of lens opacities or cataracts. Maintenance of transparency and homeostasis of the avascular lens depend on an extensive network of gap junctions. Communication through gap junction channels allows intercellular passage of molecules (up to 1 kDa) including antioxidants. Lens gap junctions and their constituent proteins, connexins (Cx43, Cx46, and Cx50), are also subject to the effects of oxidative stress. These observations suggest that oxidative stress-induced damage to connexins (and consequent altered intercellular communication) may contribute to cataract formation.     

The inner side of T cell lipid rafts

A key question in understanding the functional role of lipid rafts is whether lipid microdomains at the plasma membrane outer leaflet are coupled to lipid microdomains at the inner leaflet. By using a cyan-fluorescent protein (CFP) targeted to inner plasma membrane rafts of Jurkat T cells, we found that raft domains at the outer and inner leaflets are physically coupled and that this coupling requires cholesterol. Interestingly, TCR/CD3 cross-linking induces co-capping of the raft bilayer independently of cholesterol or signaling events, indicating that cholesterol-extracting drugs are unable to destroy TCR-lipid rafts interaction.     

Oxidative stress and endometriosis

BACKGROUND: Little is known about the aetiology of endometriosis; however, in the presence of oxidative stress, reactive oxygen species might increase growth and adhesion of endometrial cells in the peritoneal cavity, leading to endometriosis and infertility. Within a study investigating persistent organic compounds and endometriosis, the authors evaluated the association between oxidative stress and endometriosis. METHODS: Women aged 18-40 years who were undergoing laparoscopy were contacted to participate in the study (n = 100); 84 were eligible and agreed to be interviewed; 78 provided blood specimens. Four markers of oxidative stress and antioxidant status were measured in serum for 61 women. Multiple imputation of missing data was used to generate values for the missing oxidative stress data. RESULTS: Thirty-two women had visually confirmed endometriosis at laparoscopy while 52 did not, including 22 undergoing tubal ligation and 30 with idiopathic infertility. There was a weak association between thiobarbituric acid-reactive substances (nmol/ml) and endometriosis, after adjusting for age, body mass index, current smoking, hormone use in the past 12 months, gravidity, serum vitamin E, serum estradiol, and total serum lipids (beta = 1.18; 95% CI-0.04, 2.39). CONCLUSIONS: These results suggest that oxidative stress might play a role in the development and progression of endometriosis, which should be evaluated in larger studies.     

Oxidative stress and autophagy

Organisms respond to oxidative injury by orchestrating a stress response to prevent further damage. An increase in the intracellular levels of antioxidant agents, and at the same time the removal of already damaged components, are both part of the oxidative stress response. Lysosomes have been classically considered one of the main targets of the reactive oxygen species. In fact, the destabilization of the lysosomal membrane during oxidizing conditions promotes the leakage of the enzymes contained in these organelles and contributes to cellular damage. However, recent evidence supports a protective role of the lysosomal system, which can eliminate altered intracellular components through autophagy, at least in the first stages of oxidative injury. Consequently, activation of the main intracellular proteolytic systems, the ubiquitin/proteasome, and also the lysosomal/autophagic system occurs during the oxidative stress response. The opposing roles for the lysosomal system under oxidizing conditions are discussed in this review.     

Oxidative stress, beta-amyloide peptide and Alzheimer's disease

Alzheimer's disease, the leading cause of dementia in the elderly is characterized by the presence in the brain of senile plaques formed of insoluble fibrillar deposits of beta-amyloid peptide. This peptide is normally produced in a monomeric soluble form and it is present in low concentrations in the blood and spinal fluid. At physiological concentrations, this peptide is a neurotrophic and neuroprotector factor; nevertheless, with aging and particularly in Alzheimer's disease this peptide accumulates, favors the formation of insoluble fibrils and causes neurotoxicity. beta-Amyloid peptide toxicity has been associated with the generation of free radicals that in turn promote lipid peroxidation and protein oxidation. Through the recognition of specific receptors such as the scavenger receptor, the beta-amyloid peptide becomes internalized in the form of aggregates. Independently of the way the peptide enters the cell, it generates oxidative stress that eventually triggers a state of neurotoxicity and cell death. Recent studies in our laboratory have shown the effect caused by an extracellular oxidative stress upon the internalization of the scavenger receptor. We have also demonstrated that the process of protein translation of molecules implicated in the mechanism of endocytosis through the scavenger receptor, such as the case of beta-adaptin, is arrested in microglial cells treated with beta-amyloid.     

Physiological T cell activation starts and propagates in lipid rafts

Lipid rafts are plasma membrane compartments enriched in key signaling molecules. We have previously shown that in T lymphocytes anti-CD3 stimulation is insensitive to cholesterol extraction by methyl-beta-cyclodextrin (MbetaCD), suggesting that anti-CD3 induced signal transduction is independent of raft integrity. Here we show that, in contrast to T cell stimulation by anti-CD3 antibodies, T cell activation by a physiological ligand is mediated by signaling events taking place in lipid raft. Indeed, cholesterol depletion by MbetaCD resulted in reduced T cell activation in response to Epstein Barr Virus (EBV)-transformed B cells pulsed with a bacterial superantigen. Moreover, T cell stimulation by pulsed EBV-B cells, but not by anti-CD3 antibodies, induced recruitment of active Lck in detergent-resistant membranes, where the signal transduction is organized and amplified.     

Binding and internalization of Clostridium perfringens iota-toxin in lipid rafts

Clostridium perfringens iota-toxin is a binary toxin composed of an enzymatic component (Ia) and a binding component (Ib). The oligomer of Ib formed in membranes induces endocytosis. We examined the binding and internalization of Ib by using Cy3-labeled Ib. Labeled Ib was retained at the membranes of MDCK cells for 60 min of incubation at 37 degrees C, and later it was detected in cytoplasmic vesicles. To determine whether Ib associates with lipid rafts, we incubated MDCK cells with Ib at 4 or 37 degrees C and fractionated the Triton-insoluble membranes. An Ib complex of 500 kDa was localized at 37 degrees C to the insoluble fractions that fulfilled the criteria of lipid rafts, but it did not form at 4 degrees C. The amount of complex in the raft fraction reached a maximum after 60 min of incubation at 37 degrees C. When the cells that were preincubated with Ib at 4 degrees C were incubated at 37 degrees C, the complex was detected in the raft fraction. The treatment of MDCK cells with methyl-beta-cyclodextrin reduced the localization of the Ib complex to the rafts and the rounding of the cells induced by Ia plus Ib. When 125I-labeled Ia was incubated with the cells in the presence of Ib at 37 degrees C, it was localized in the raft fraction. Surface plasmon resonance analysis revealed that Ia binds to the oligomer of Ib. We conclude that Ib binds to a receptor in membranes and then moves to rafts and that Ia bound to the oligomer of Ib formed in the rafts is internalized.     

Leucine-rich repeat kinase 2 associates with lipid rafts

Leucine-Rich Repeat Kinase 2 (LRRK2) is a causative gene for the autosomal dominant form of Parkinson's disease (PD). The gene encodes the approximately 280 kDa LRRK2 protein composed of domains such as leucine-rich repeats, Ras in complex proteins (Roc) followed by C-terminal of Roc (COR), mitogen-activated protein kinase kinase kinase (MAPKKK) and WD40. However, the normal function of the protein as well as its contribution to the pathogenesis of PD remains largely unknown. Here we describe the localization of LRRK2 in Golgi apparatus, plasma membrane and synaptic vesicles in cultured cells including mouse primary neurons. The membrane association of LRRK2 resists solubilization by ice-cold 1% Triton X-100, indicating its association through lipid rafts. To investigate whether mutations found in PD patients affect the localization of LRRK2, we transfected various LRRK2 mutants into cultured cells and performed fractionation experiments. Unexpectedly, the mutants are collected in both membrane and soluble fractions in a manner similar to wild type (WT). I2020T mutant LRRK2 associates with lipid rafts, similar to the WT. The lipid raft association of LRRK2 mutants as well as WT LRRK2 suggests that alteration of LRRK2 function on lipid rafts contributes to the pathogenesis of PD.