Role of lipid rafts in persistent Helicobacter pylori infection: a narrative review

Introduction

Cell membrane is an elastic, fluid structure composed of a phospholipid bilayer (skeleton) and multiple other substances that separates the intracellular and extracellular environments. It carries out specific functions such as barrier protection, selective permeability, endocytosis/secretion, cell-cell recognition, and signal transduction, to name a few. It is also the place where some enzymatic reactions take place (1). The substances enclosed by the cell membrane are not always homogenously distributed, but are compartmentalized into a batch of special functional regions formed by high aggregation of certain substances that are often present at low levels outside these special domains (2). Lipid rafts are one of such functional microdomains that contain cholesterol, sphingolipids, and proteins (3), with many tumor- (4) and immunity-associated (5) molecules. Lipid rafts are exploited by intracellular pathogens as a gateway (6,7) to invade the cells, making it a new hot spot in the studies on host cells and pathogen infections. At present, researchers regard lipid rafts potential therapeutic targets for some diseases (8) in the search for the mechanisms and new therapies of tumorigenesis or persistent infection.

Helicobacter pylori (Hp) is a Gram-negative, health-threatening bacterium that is estimated to have infected more than 50% of the global population (9). In most cases, there are no obvious clinical symptoms after infection, and only a small number of infected people develop gastritis, gastric ulcers, or other diseases. In severe cases, Hp can lead to stomach cancer. It is difficult to eradicate due to its ability to evade the immune system (10) via a variety of mechanisms. Thus, Hp infections are often long-lived. Recent study has revealed that persistent Hp infection is closely associated with the development of gastric cancer, so eradication of Hp can lower the risk of gastric cancer (11). In 2012, the World Health Organization (WHO) classified Hp (infection) as a class 1 carcinogen.

The clinical treatment of Hp patients has long been dominated by antibiotics (12), but with the continuous expansion of Hp eradication indications and the increasing rate of drug resistance (13), it is necessary to discover novel treatment strategies. Research on vaccines and non-antibiotic drugs for the prevention and treatment of Hp infection is currently the focus of the medical field. We present the following article in accordance with the Narrative Review reporting checklist (available at https://atm.amegroups.com/article/view/10.21037/atm-22-1000/rc).

Methods

Relevant studies published over the last 20 years were identified via a PubMed search using different combinations of the following search terms: “Helicobacter pylori”, “lipid raft/membrane microdomain”, “infection”, “therapeutic/treatment”, “cholesterol”. Most of the search formulas we use are shown in Table 1. Additional papers were identified by reviewing reference lists of relevant publications. Publications with relative low credibility and non-English publications were excluded. Data were extracted based on their relevance to the topic instead of implementing a systematic approach to paper selection. More details of the method are shown in Table 2.

What is the nature of lipid rafts?

In 1973, Yu et al. used the non-ionic detergent Triton X-100 to treat cells, and discovered that it was difficult to solubilize some components in the lysate with the detergent (14). In 1997, Simons et al. put forward the concept of “lipid raft” for special structures on the cell membrane, namely, clustering of sphingolipids and cholesterol as a lipid “raft” to which some special proteins can be anchored. This “lipid raft” can form a liquid-ordered (Lo) functional area on the liquid-disordered (Ld) cell membrane for the cell to carry out specific physiological activities (3). Subsequently, an interaction of preferential aggregation between some of the lipids was observed on the biomimetic model (biomembrane), resulting in liquid-liquid phase separation (15), a phenomenon that further supports the “lipid raft” theory. In 2006, a conference updated the definition of lipid raft: lipid rafts are tiny (10–200 nm), heterogeneous, dynamic (lateral movement across the membrane, dynamic polymerization-dissociation), cholesterol- and sphingolipid-rich membrane nanodomains that compartmentalize cellular life activities; they can also form larger platforms through protein-protein interactions and protein-lipid interactions (>300 nm) (16). The microscopic scale of 10–200 nm is beyond the resolution of an optical microscope, and this has delayed the conduction of experiments for direct observation of lipid rafts. With further studies, there is now a tendency, based on the above definition, to regard lipid raft as a transient, relatively ordered membrane nanodomain (17), which is in a dynamic process of formation and dissolution (18) rather than a long-term stable inherent structure. This means that except the lipid composition is roughly the same, there are different proteins in lipid rafts of different cells, and the components on the same lipid raft also change over time.

In what ways are lipid rafts researched?

In the process of verifying the authenticity of this structure, scientists have constructed a wide range of model membranes and employed numerous research techniques to study the morphological and kinetic aspects of lipid rafts. Baumgart et al. [2007] demonstrated that the giant plasma membrane vesicles (GPMVs) induced on the plasma membranes of cultured mammalian cells can also be separated into micron-scale fluid phase domains, suggestive of a non-ideal, non-randomized distribution (19) of membrane components in living cells (19), further corroborating the existence of lipid rafts, and providing a classical tool to understand the formation and kinetics of lipid rafts. Chiantia et al. [2006] used atomic force microscopy (AFM) and dual-focus fluorescence correlation spectroscopy (2fFCS) (20) and Štefl et al. [2012] used 2fFCS and cross-linking agents (21) to study the lipid distribution in dioleoyl phosphatidylcholine/sphingomyelin/cholesterol (DOPC/SM/cholesterol) model membranes. These studies have clearly confirmed the fact that some components spontaneously aggregate in cell membranes and liquid-liquid phase separation in the natural state, making important contributions to improving lipid raft-related theories. Recently, the development of novel techniques such as super-resolution observation technology has brought hope to direct observation of lipid rafts. Ando et al. [2015], for instance, studied the distribution of sphingolipids in lipid rafts on artificial monolayers with the help of a Raman microscope (22). Dumitru et al. [2018] observed the lateral structure of lipid membrane under AFM and a toxin derivative probe (23). Ryu et al. [2019] used epi-fluorescence microscopy (EFM) to confirm that cholesterol infiltration into sphingolipid-rich structural domain plays a vital role in membrane phase separation (24). These studies on the physical properties of lipid rafts have greatly promoted the development of the lipid raft theory.

The locating and tracing of the components on lipid rafts by tracers and fluorescent labeling techniques have greatly enriched and simplified the methods for studying lipid rafts. Researchers have noticed that the specific ligand recognized by the cholera toxin B subunit (CTB) is the ganglioside GM1 in the cell membrane (25), and GM1 is highly enriched in lipid rafts. Scientists have recently chosen CTB as a marker molecule to trace lipid rafts, and have carried out a lot of fruitful research (26-28). More and more new tracing techniques have been developed, such as fluorescently labeled gangliosides for lipid raft imaging synthesized by Konishi et al. in 2020 (29), and the strategy established by Shi et al. in 2021 for analyzing the glycan distribution in lipid rafts and beyond (30). These labeling and tracing techniques have greatly promoted the study of lipid raft structures and functions, and provided new ideas for the research of lipid raft components-targeted drugs (31).

Lipid rafts and persistent Hp infection

Are there studies on both lipid rafts and infection of host cells with pathogens?

Lipid rafts are enriched with substances that are less common in other cell membrane regions, such as cholesterol, in addition to proteins with distinct functions. The proteins that have their own functions and the lipids that form liquid-liquid phase separation make the functions of lipid rafts complicated.

Early studies have shown that lipid raft components like cholesterol are of great significance to the entry and survival of influenza virus in the cell (32-34), and this finding continues to inspire many researchers, such as Ohkura et al., who found that the binding of influenza A virus hemagglutinin and neuraminidase to lipid rafts promoted it’s trafficking (35), and Verma et al., who demonstrated that the lipid rafts of the host cell play a leading role in the binding and endocytosis of influenza A viruses (36). Lipid rafts also have a place in the currently hottest field of severe acute respiratory distress syndrome coronavirus 2 (SARS-CoV-2) research. For instance, Fantini et al. concluded that the effective action mechanism of hydroxychloroquine in combination with azithromycin for the treatment of SARS-CoV-2 is related to the sphingolipids GM1 on lipid rafts: because of a structural similarity between azithromycin and GM1 glycan part, azithromycin is able to competitively bind the ganglioside-binding domain of the SARS-CoV-2 spike protein; hydroxychloroquine, on the other hand, is able to saturate the virus attachment sites of ganglioside near the coronavirus receptor of host cell membrane (37). The combined use of these 2 drugs bidirectionally blocks the binding of the virus to the host cell for antiviral purposes (37). In addition, Gekara et al. showed that Listeria monocytogenes can induce the concentration of host cell lipid rafts via listeriolysin O (38). Fine-Coulson et al. also discovered that the induction of lipid raft aggregation during infection of type II alveolar epithelial cells could be caused by Mycobacterium tuberculosis (39). All of these studies suggest that lipid rafts are closely associated with pathogen-host interactions in several diseases, and studying the mechanism of action of lipid rafts in diseases is of great significance for the treatment of these diseases. Then, do lipid rafts play an important role in the persistence of Hp infection?

How do lipid rafts mediate signal transduction in host cells during persistent Hp infection?

Lipid rafts, as an important platform for signal transduction, are capable of recruiting a variety of inflammatory signaling-related receptors. Kwok et al. demonstrated that Hp injects cytotoxin-associated protein (CagA) and peptidoglycan into host cells via its type IV secretion system binding to integrin α5β1, so that nuclear factor-κB (NF-κB) is activated and proinflammatory cytokines such as interleukin 8 (IL-8) (40) will be produced, while α5β1 is localized on lipid rafts (41). In other words, Hp induces NF-κB-dependent inflammatory response in gastric epithelial cells through lipid rafts (Figure 1A) (42). Lin et al. pointed out that Hp can also promote the inflammation of gastric epithelial cells by activating the expression of high-mobility group box 1 (HMGB1) and recruiting the receptor for advanced glycosylation end-products (RAGE) to lipid rafts to activate the NF-κB/IL-8 signaling pathway (Figure 1B) (43). These findings have demonstrated that Hp promotes the inflammatory response of the body by recruiting inflammatory factors to lipid rafts in diverse ways. Blouin et al. also showed that proper assembly of the interferon-γ receptor (IFNGR) subunits IFNGR1 and IFNGR2 on lipid rafts is critical for IFNG/JAK/STAT signaling transduction, as shown in Figure 1C (44), meaning that lipid rafts are also important platform for IFNG signal transduction. Then, how does Hp evade the killing by these inflammatory responses and form persistent infection of the host cell?

Figure 1 Signal transduction mediated by lipid rafts in persistent Hp infection. (A) Hp infects the host cell by binding to integrin α5β1 on lipid rafts and injects CagA into the host cell to activate the NF-κB/IL-8 signaling pathway and promote inflammation. (B) Hp recruits RAGE into the lipid raft to activate the NF-κB/IL-8 signaling pathway and promote inflammation. (C) The correct assembly of IFNGR subunits is dependent on the lipid raft integrity and essential for IFNG/JAK/STAT signal transduction. (D) Hp uses CGT to disrupt the structure of the lipid raft on the host cell membrane, making IFNGR unable to assemble properly, which in turn frustrates IFN-γ signaling, and helps Hp evade inflammatory response. RAGE, receptor for advanced glycosylation end-products; CagA, cytotoxin-associated protein; NF-κB, nuclear factor-κB; IL-8, interleukin 8; IFN-γ, interferon-γ; CGT, cholesterol-α-glucosyltransferase; Hp, Helicobacter pylori; IFNGR, interferon-γ receptor.

Why does persistent Hp infection destruct lipid rafts?

Trampenau et al. found that Hp has a specific affinity for cholesterol in the process of culturing (45), and the large amount of cholesterol (3) enriched in lipid rafts seems to suggest a possible link between Hp and lipid rafts. Haque et al. discovered that the lipid composition of Hp contains an abundant number of characteristic cholesteryl glucosides (CGs) (46). The experiments by Testerman et al. confirmed that exogenous cholesterol is required for the growth of Hp during in vitro culturing (47), suggesting that Hp does not appear to possess an enzyme for cholesterol synthesis. So, where does the cholesterol required for the synthesis of CGs by Hp during in vivo infection come from? It must be that, in some way, Hp obtains a profuse amount of cholesterol for the synthesis of CGs from the host in vivo. However, the largest cholesterol reservoir in the surrounding environment of Hp infection is the lipid rafts in the gastric epithelial cell membrane. This seems to imply the disruption of host cell lipid rafts by Hp.

In 2006, Wunder et al. identified hp0421, a gene encoding a cholesterol-α-glucosyltransferase (CGT) that can extract cholesterol from host cell lipid rafts, and elucidated that CGT plays the role of extracting cholesterol from the lipid rafts on the host cell membrane to synthesize CGs; they also found that Hp strains whose hp0421 genes are knocked out are more readily ingested by macrophages, and the knockout strain stimulated T cell activations compared to the wild strain (48). Furthermore, mice challenged with the knockout strain were cleared of bacteria after a period of time compared with 2 controls, namely, wild-type strains, and strains of CGT gene-containing plasmids (48), suggesting that the function of CGT is important for the immune escape of Hp, perhaps because the extraction of cholesterol by CGT has impaired lipid rafts, and thus inhibited phagocytosis of phagocytes and T cell-dependent immune response.

Morey et al. found that the downstream JAK/STAT1 pathway failed to be activated by IFNG after prolonged infection while treating Hp-infected MKN45 cells with interferon-γ (IFN-γ) (49). The key factor CGT responsible for this effect is subsequently identified through experiments performed by knocking out the virulence genes of Hp strains one by one (49). The mechanistic pattern is shown in Figure 1D. As Blouin et al. had demonstrated the importance of proper assembly of IFNGR on lipid rafts for IFNG/JAK/STAT signaling (44), Morey et al. then speculated: does Hp inhibit the inflammatory response of the host cell by disrupting the integrity of lipid rafts and thus affecting the correct assembly of IFNGR through CGT extraction of cholesterol from the lipid rafts on the host cell membrane (49)? To test this hypothesis, they treated the cell with methyl-β-cyclodextrin (capable of solubilizing the cholesterol in cell membranes), and found that JAK1/STAT1 phosphorylation levels were significantly reduced; at the same time, after protecting the integrity of cell membrane lipid rafts via a cholesterol coating prior to infection, the IFNG/JAK/STAT signals in the cells infected with wild-type Hp whose CGT gene is not knocked out can be normally transduced, and JAK1/STAT1 is normally phosphorylated to regulate downstream gene expression. Furthermore, by adding cholesterol to the culture system already infected with wild-type Hp, the impaired IFNG signaling is partially restored (49). These experiments have confirmed that Hp can weaken the lipid raft to block the IFNG signaling pathway, and thus achieve immune escape. Similarly, they found that Hp also inhibits the IFNB, IL-6, and IL-22 signal transduction of the receptors localized on lipid rafts, as well as the downstream human β-defensin 3 (HBD3) response, by disrupting lipid rafts (49). Cholesterol extraction by Hg CGT from the lipid raft helps to inhibit multiple inflammatory signaling pathways allows for continuous, localized Hp colonization. So, are other inflammatory signaling pathways such as NF-κB affected? Further investigation is required.

What can we do to repair the lipid rafts affected by Hp infection?

Morey et al. demonstrated that adding cholesterol to a co-culture system where the cells are infected with wild-type Hp and IFNG signaling is suppressed can up-regulate JAK1/STAT1 phosphorylation (49), implying that the addition of cholesterol repairs part of the lipid rafts, allows some IFNGR to assemble properly, and unblocks the IFNG/JAK/STAT inflammatory signaling pathway. Are other inflammatory signaling pathways affected? Does this phenomenon have practical significance for the control of Hp infection? Wunder et al. demonstrated that, by continually adding 2% cholesterol to the diets of Hp-infected mice, the bacterial load is reduced by more than 95% compared to cholesterol-free diets, and in the gastric tissue samples of the mice with reduced bacterial loads there is massive infiltration of neutrophils and lymphocytes, whereas no inflammatory infiltration was observed in the tissues cut from the stomachs of the uninfected mice that eat the food containing 2% cholesterol (48).

Kobayashi et al. added the cholesterol analog, cholestenone, to the co-culture system of Hp and gastric cancer cells, and found that it also restrains the synthesis of CGs in Hp (50). This cholesterol analogue differs from cholesterol in that the hydroxyl group on the third C atom of cholesterol that can be linked to glucosides under the influence of CGT is turned into a carbonyl group, making CGT unable to attach the glucoside. In contrast, 2 other cholesterol analogs, namely β-sitosterol and cholestyramine, that modify the carbon atoms at other positions, do not have anti-Hp activities (50). Moreover, during in vitro experiments, the cholestenone can efficiently resist Hp regardless of whether there is cholesterol in the system. This effect is enhanced with increasing concentrations of cholestenone (50). The addition of 0.5% cholestenone to the diet can greatly reduce the bacterial load in the gastric mucosa of C57BL/6 mice already infected with the Hp SS1 strain (50). More delightfully, cholestenone is also effective against clarithromycin-resistant Hp strain 2460 (50). This brings new hope to eradication therapy for Hp, which is now plagued by rising drug resistance rates.

Kawakubo et al. discovered that the mucous cells deep in gastric mucosa can secrete O-glycans with α1,4-N acetylglucosaminoglycan terminals. Such O-glycans have natural anti-Hp activities, which is a key factor in the protection of mucous cells from Hp attack (51). Then, how is the anti-Hp effect of O-glycan achieved? Through mass spectrometry and thin-layer chromatography (TLC), they found that the content of CGs in Hp is significantly lowered by adding O-glycans, meaning that the anti-Hp effect of O-glycan is achieved by interfering with the synthesis of CGs (51). This suggests that to resist Hp infection, we need to prevent CGT from damaging lipid rafts first. Nevertheless, up to now, there is still no anti-Hp drug with repairing lipid rafts as the therapeutic target in the world.

The addition of cholesterol and O-glycans can help clear Hp infection (50,51), and whether the mechanism is associated with the repair of the immune pathways on lipid rafts remains to be investigated. Recent studies have discovered that some Hp strains resistant to multiple antibiotics contain a very high level of CGs (52), and the study conducted by McGee et al. confirmed that such high levels of CGs can enhance Hp resistance to antibiotics (53). Qaria et al. demonstrated that removal of CGs from the Hp surface can make some drug-resistant strains vulnerable to antibiotics (54). Although CGs synthesis is not the only antibiotic tolerance mechanism, CGs play a specific role in Hp resistance to various antibiotics.

Conclusions and outlook

Lipid rafts are key to persistent Hp infection, and a new field of research on pathogen-host cell interactions and signal transduction. The destruction of lipid rafts is of great Importance for understanding chronic gastritis, peptic ulcers, and stomach cancer from Hp persistent infection. Recent studies have revealed that lipid rafts are the transportation hubs of multiple inflammatory pathways (40-44), and Hp evades immune response by damaging lipid rafts to form persistent infections (48,49). The addition of cholestenone or O-glycan affecting lipid rafts has a significant effect on the inhibition of Hp persistent infection, which undoubtedly suggests that lipid rafts are effective drug targets against persistent Hp infection, thus important for eradicating persistent Hp infection and reducing the resistance of drug-resistant strains to antibiotics. The current studies suggest that cholestenone and O-glycan can control Hp infection by hindering the synthesis of CGs (50,51), and are therefore ideal targets for the treatment of persistent Hp infection. But if cholestenone and O-glycan can achieve this effect, why not use them as anti-Hp drugs? Are the antibacterial effects of these substances determined? What are the mechanisms that produce the effect other than those described above? Can they be used in combination with antibiotics to improve the efficacy of Hp eradication therapies? Are they good or bad for host cells? These questions all require further research and discussion.

At present, some achievements have been made in the drug research with lipid rafts as the therapeutic target (55). This means that it is also a very valuable research direction to target lipid rafts in the treatment of persistent infection of Hp. However, most of these experimental therapies are targeting destroying pathological lipid rafts, including examples of inflammarafts and clusters of apoptotic signaling molecule-enriched rafts (55). Drug research aimed at repairing damaged lipid rafts is relatively rare (55). This means that relevant researches are also significantly pioneering and innovative. Drugs repairing lipid rafts in persistent Hp infection may became a supplement to existing therapy.

Acknowledgments

Funding: This dissertation was funded jointly by two projects, which are the Key R & D Project of Science and Technology Department in Sichuan Province (No. 2021YFS0054) and the Technological Innovation R & D Project of Chengdu Science and Technology Bureau (No. 2019-YF05-00298-SN).

Footnote

Reporting Checklist: The authors have completed the Narrative Review reporting checklist. Available at https://atm.amegroups.com/article/view/10.21037/atm-22-1000/rc

Conflicts of Interest: All authors have completed the ICMJE uniform disclosure form (available at https://atm.amegroups.com/article/view/10.21037/atm-22-1000/coif). The authors have no conflicts of interest to declare.

Ethical Statement: The authors are accountable for all aspects of the work in ensuring that questions related to the accuracy or integrity of any part of the work are appropriately investigated and resolved.

Open Access Statement: This is an Open Access article distributed in accordance with the Creative Commons Attribution-NonCommercial-NoDerivs 4.0 International License (CC BY-NC-ND 4.0), which permits the non-commercial replication and distribution of the article with the strict proviso that no changes or edits are made and the original work is properly cited (including links to both the formal publication through the relevant DOI and the license). See: https://creativecommons.org/licenses/by-nc-nd/4.0/.

References

1. Vereb G, Szöllosi J, Matkó J, et al. Dynamic, yet structured: The cell membrane three decades after the Singer-Nicolson model. Proc Natl Acad Sci U S A 2003;100:8053-8. [Crossref] [PubMed]
2. Mukherjee S, Maxfield FR. Membrane domains. Annu Rev Cell Dev Biol 2004;20:839-66. [Crossref] [PubMed]
3. Simons K, Ikonen E. Functional rafts in cell membranes. Nature 1997;387:569-72. [Crossref] [PubMed]
4. Capuano C, Paolini R, Molfetta R, et al. PIP2-dependent regulation of Munc13-4 endocytic recycling: impact on the cytolytic secretory pathway. Blood 2012;119:2252-62. [Crossref] [PubMed]
5. Anderson HA, Hiltbold EM, Roche PA. Concentration of MHC class II molecules in lipid rafts facilitates antigen presentation. Nat Immunol 2000;1:156-62. [Crossref] [PubMed]
6. Takeda M, Leser GP, Russell CJ, et al. Influenza virus hemagglutinin concentrates in lipid raft microdomains for efficient viral fusion. Proc Natl Acad Sci U S A 2003;100:14610-7. [Crossref] [PubMed]
7. Aybeke EN, Belliot G, Lemaire-Ewing S, et al. HS-AFM and SERS Analysis of Murine Norovirus Infection: Involvement of the Lipid Rafts. Small 2017; [Crossref] [PubMed]
8. Sviridov D, Miller YI, Ballout RA, et al. Targeting Lipid Rafts-A Potential Therapy for COVID-19. Front Immunol 2020;11:574508. [Crossref] [PubMed]
9. Hooi JKY, Lai WY, Ng WK, et al. Global Prevalence of Helicobacter pylori Infection: Systematic Review and Meta-Analysis. Gastroenterology 2017;153:420-9. [Crossref] [PubMed]
10. Mejías-Luque R, Gerhard M. Immune Evasion Strategies and Persistence of Helicobacter pylori. Curr Top Microbiol Immunol 2017;400:53-71. [Crossref] [PubMed]
11. Kumar S, Metz DC, Ellenberg S, et al. Risk Factors and Incidence of Gastric Cancer After Detection of Helicobacter pylori Infection: A Large Cohort Study. Gastroenterology 2020;158:527-36.e7. [Crossref] [PubMed]
12. Kumar S, Metz DC, Kaplan DE, et al. Low Rates of Retesting for Eradication of Helicobacter pylori Infection After Treatment in the Veterans Health Administration. Clin Gastroenterol Hepatol 2021;19:305-13.e1. [Crossref] [PubMed]
13. Sugano K, Tack J, Kuipers EJ, et al. Kyoto global consensus report on Helicobacter pylori gastritis. Gut 2015;64:1353-67. [Crossref] [PubMed]
14. Yu J, Fischman DA, Steck TL. Selective solubilization of proteins and phospholipids from red blood cell membranes by nonionic detergents. J Supramol Struct 1973;1:233-48. [Crossref] [PubMed]
15. Simons K, Vaz WL. Model systems, lipid rafts, and cell membranes. Annu Rev Biophys Biomol Struct 2004;33:269-95. [Crossref] [PubMed]
16. Pike LJ. Rafts defined: a report on the Keystone Symposium on Lipid Rafts and Cell Function. J Lipid Res 2006;47:1597-8. [Crossref] [PubMed]
17. Sezgin E, Levental I, Mayor S, et al. The mystery of membrane organization: composition, regulation and roles of lipid rafts. Nat Rev Mol Cell Biol 2017;18:361-74. [Crossref] [PubMed]
18. Bolmatov D, Soloviov D, Zhernenkov M, et al. Molecular Picture of the Transient Nature of Lipid Rafts. Langmuir 2020;36:4887-96. [Crossref] [PubMed]
19. Baumgart T, Hammond AT, Sengupta P, et al. Large-scale fluid/fluid phase separation of proteins and lipids in giant plasma membrane vesicles. Proc Natl Acad Sci U S A 2007;104:3165-70. [Crossref] [PubMed]
20. Chiantia S, Ries J, Kahya N, et al. Combined AFM and two-focus SFCS study of raft-exhibiting model membranes. Chemphyschem 2006;7:2409-18. [Crossref] [PubMed]
21. Štefl M, Šachl R, Humpolíčková J, et al. Dynamics and size of cross-linking-induced lipid nanodomains in model membranes. Biophys J 2012;102:2104-13. [Crossref] [PubMed]
22. Ando J, Kinoshita M, Cui J, et al. Sphingomyelin distribution in lipid rafts of artificial monolayer membranes visualized by Raman microscopy. Proc Natl Acad Sci U S A 2015;112:4558-63. [Crossref] [PubMed]
23. Dumitru AC, Conrard L, Lo Giudice C, et al. High-resolution mapping and recognition of lipid domains using AFM with toxin-derivatized probes. Chem Commun (Camb) 2018;54:6903-6. [Crossref] [PubMed]
24. Ryu YS, Yun H, Chung T, et al. Kinetics of lipid raft formation at lipid monolayer-bilayer junction probed by surface plasmon resonance. Biosens Bioelectron 2019;142:111568. [Crossref] [PubMed]
25. Dertzbaugh MT, Peterson DL, Macrina FL. Cholera toxin B-subunit gene fusion: structural and functional analysis of the chimeric protein. Infect Immun 1990;58:70-9. [Crossref] [PubMed]
26. Gonzalez Porras MA, Fogarty MJ, Gransee HM, et al. Frequency-dependent lipid raft uptake at rat diaphragm muscle axon terminals. Muscle Nerve 2019;59:611-8. [Crossref] [PubMed]
27. Tan SS, Yin Y, Lee T, et al. Therapeutic MSC exosomes are derived from lipid raft microdomains in the plasma membrane. J Extracell Vesicles 2013; [Crossref] [PubMed]
28. Glebov OO, Nichols BJ. Lipid raft proteins have a random distribution during localized activation of the T-cell receptor. Nat Cell Biol 2004;6:238-43. [Crossref] [PubMed]
29. Konishi M, Komura N, Hirose Y, et al. Development of Fluorescent Ganglioside GD3 and GQ1b Analogs for Elucidation of Raft-Associated Interactions. J Org Chem 2020;85:15998-6013. [Crossref] [PubMed]
30. Shi H, Chen Y, Li Y, et al. Hierarchical Fluorescence Imaging Strategy for Assessment of the Sialylation Level of Lipid Rafts on the Cell Membrane. Anal Chem 2021;93:14643-50. [Crossref] [PubMed]
31. Guan J, Zhang Z, Hu X, et al. Cholera Toxin Subunit B Enabled Multifunctional Glioma-Targeted Drug Delivery. Adv Healthc Mater 2017; [Crossref] [PubMed]
32. Scheiffele P, Roth MG, Simons K. Interaction of influenza virus haemagglutinin with sphingolipid-cholesterol membrane domains via its transmembrane domain. EMBO J 1997;16:5501-8. [Crossref] [PubMed]
33. Keller P, Simons K. Cholesterol is required for surface transport of influenza virus hemagglutinin. J Cell Biol 1998;140:1357-67. [Crossref] [PubMed]
34. Scheiffele P, Rietveld A, Wilk T, et al. Influenza viruses select ordered lipid domains during budding from the plasma membrane. J Biol Chem 1999;274:2038-44. [Crossref] [PubMed]
35. Ohkura T, Momose F, Ichikawa R, et al. Influenza A virus hemagglutinin and neuraminidase mutually accelerate their apical targeting through clustering of lipid rafts. J Virol 2014;88:10039-55. [Crossref] [PubMed]
36. Verma DK, Gupta D, Lal SK. Host Lipid Rafts Play a Major Role in Binding and Endocytosis of Influenza A Virus. Viruses 2018;10:650. [Crossref] [PubMed]
37. Fantini J, Chahinian H, Yahi N. Synergistic antiviral effect of hydroxychloroquine and azithromycin in combination against SARS-CoV-2: What molecular dynamics studies of virus-host interactions reveal. Int J Antimicrob Agents 2020;56:106020. [Crossref]
38. Gekara NO, Weiss S. Lipid rafts clustering and signalling by listeriolysin O. Biochem Soc Trans 2004;32:712-4. [Crossref] [PubMed]
39. Fine-Coulson K, Reaves BJ, Karls RK, et al. The role of lipid raft aggregation in the infection of type II pneumocytes by Mycobacterium tuberculosis. PloS One 2012;7:e45028. [Crossref] [PubMed]
40. Kwok T, Zabler D, Urman S, et al. Helicobacter exploits integrin for type IV secretion and kinase activation. Nature 2007;449:862-6. [Crossref] [PubMed]
41. Kansau I, Berger C, Hospital M, et al. Zipper-like internalization of Dr-positive Escherichia coli by epithelial cells is preceded by an adhesin-induced mobilization of raft-associated molecules in the initial step of adhesion. Infect Immun 2004;72:3733-42. [Crossref] [PubMed]
42. Hutton ML, Kaparakis-Liaskos M, Turner L, et al. Helicobacter pylori exploits cholesterol-rich microdomains for induction of NF-kappaB-dependent responses and peptidoglycan delivery in epithelial cells. Infect Immun 2010;78:4523-31. [Crossref] [PubMed]
43. Lin HJ, Hsu FY, Chen WW, et al. Helicobacter pylori Activates HMGB1 Expression and Recruits RAGE into Lipid Rafts to Promote Inflammation in Gastric Epithelial Cells. Front Immunol 2016;7:341. [Crossref] [PubMed]
44. Blouin CM, Hamon Y, Gonnord P, et al. Glycosylation-Dependent IFN-Γr Partitioning in Lipid and Actin Nanodomains Is Critical for JAK Activation. Cell 2016;166:920-34. [Crossref] [PubMed]
45. Trampenau C, Müller KD. Affinity of Helicobacter pylori to cholesterol and other steroids. Microbes Infect 2003;5:13-7. [Crossref] [PubMed]
46. Haque M, Hirai Y, Yokota K, et al. Lipid profile of Helicobacter spp.: presence of cholesteryl glucoside as a characteristic feature. J Bacteriol 1996;178:2065-70. [Crossref] [PubMed]
47. Testerman TL, McGee DJ, Mobley HL. Helicobacter pylori growth and urease detection in the chemically defined medium Ham’s F-12 nutrient mixture. J Clin Microbiol 2001;39:3842-50. [Crossref] [PubMed]
48. Wunder C, Churin Y, Winau F, et al. Cholesterol glucosylation promotes immune evasion by Helicobacter pylori. Nat Med 2006;12:1030-8. [Crossref] [PubMed]
49. Morey P, Pfannkuch L, Pang E, et al. Helicobacter pylori Depletes Cholesterol in Gastric Glands to Prevent Interferon Gamma Signaling and Escape the Inflammatory Response. Gastroenterology 2018;154:1391-404.e9. [Crossref] [PubMed]
50. Kobayashi J, Kawakubo M, Fujii C, et al. Cholestenone functions as an antibiotic against Helicobacter pylori by inhibiting biosynthesis of the cell wall component CGL. Proc Natl Acad Sci U S A 2021;118:e2016469118. [Crossref] [PubMed]
51. Kawakubo M, Ito Y, Okimura Y, et al. Natural antibiotic function of a human gastric mucin against Helicobacter pylori infection. Science 2004;305:1003-6. [Crossref] [PubMed]
52. Jan HM, Chen YC, Yang TC, et al. Cholesteryl α-D-glucoside 6-acyltransferase enhances the adhesion of Helicobacter pylori to gastric epithelium. Commun Biol 2020;3:120. [Crossref] [PubMed]
53. McGee DJ, George AE, Trainor EA, et al. Cholesterol enhances Helicobacter pylori resistance to antibiotics and LL-37. Antimicrob Agents Chemother 2011;55:2897-904. [Crossref] [PubMed]
54. Qaria MA, Kumar N, Hussain A, et al. Roles of Cholesteryl-α-Glucoside Transferase and Cholesteryl Glucosides in Maintenance of Helicobacter pylori Morphology, Cell Wall Integrity, and Resistance to Antibiotics. MBio 2018;9:01523-18. [Crossref] [PubMed]
55. Sviridov D, Mukhamedova N, Miller YI. Lipid rafts as a therapeutic target. J Lipid Res 2020;61:687-95. [Crossref] [PubMed]

(English Language Editor: J. Jones)