Specific and distinct determinants mediate membrane binding and lipid raft incorporation of HIV-1SF2 Nef

Giese, Simone I.; Woerz, Ilka; Homann, Stefanie; Tibroni, Nadine; Geyer, Matthias; Fackler, Oliver T.

doi:10.1016/j.virol.2006.07.003

Cited by 64 publications

(92 citation statements)

References 71 publications

Supporting

Mentioning

Contrasting

Unclassified

Order By: Relevance

“…The role of membrane rafts in the assembly and budding of enveloped viruses has been investigated for influenza virus [59,63,[150][151][152][153][154][155][156][157][158][159][160], HIV-1 [63,[161][162][163][164][165][166][167][168][169][170][171][172][173], HTLV-1 [174], measles virus (Paramyxoviridae) [63,175,176], Sendai virus [Paramyxoviridae] [177,178], Newcastle disease virus (NDV; Paramyxoviridae) [179,180], RSV [147,148,[181][182][183][184], HSV [185,186], murine cytomegalovirus (MCMV; Herpesviridae) [187], Ebola virus [70,188], Marburg virus [70], and vesicular stomatitis virus (VSV; Rhabdoviridae) …”

Section: Role Of Membrane Rafts In Virus Genome Replication Assemblymentioning

confidence: 99%

“…Nef also binds to both the plasma membrane and viral structural proteins and participates directly in formation of the budding scaffold, leading to incorporation of Nef into virions, concomitantly with viral structural proteins [162,163,166]. The N-terminus of Nef determines the differential membrane avidities and selective incorporation into a specific membrane raft for surface membranes or for subcellular membranes [170]. Moreover, Nef modulates the lipid composition of virions and host cell membrane rafts through activation of lipid kinases such as PI3K [171].…”

Section: Role Of Membrane Rafts In Virus Genome Replication Assemblymentioning

confidence: 99%

See 1 more Smart Citation

Role of Membrane Rafts in Viral Infection

Takahashi¹,

Suzuki²

2009

TODJ

View full text Add to dashboard Cite

Membrane rafts are small (10-200 nm), heterogeneous, highly dynamic, sterol-and sphingolipid-enriched domains that compartmentalize cellular processes. Many studies have established that membrane rafts play an important role in the process of virus infection cycle and virus-associated diseases. It is well known that many viral components or virus receptors are concentrated in the lipid microdomains. Viruses are divided into four main classes, nonenveloped RNA virus, enveloped RNA virus, nonenveloped DNA virus, and enveloped DNA virus. General virus infection cycle is also classified into two sections, the early stage (entry) and the late stage (assembly and budding of virion). Caveola-dependent endocytosis has been investigated mostly by analysis of cell entry of the SV40 representative of polyomaviruses. Thus, the study of membrane rafts has been partially advanced by virological researches. Membrane rafts also act as a scaffold of many cellular signal transductions. Involvement of membrane rafts in many virus-associated diseases is often responsible for up-or down-regulation of cellular signal transductions. What is the role of membrane rafts in virus replications? Viruses do not necessarily require and probably utilize membrane rafts for more efficiency in virus entry, viral genome replication, high-infective virion production, and cellular signaling activation toward advantageous virus replication. In this review, we described the involvement of membrane rafts in the virus life cycle and virus-associated diseases.

show abstract

Section: Role Of Membrane Rafts In Virus Genome Replication Assemblymentioning

confidence: 99%

Section: Role Of Membrane Rafts In Virus Genome Replication Assemblymentioning

confidence: 99%

Role of Membrane Rafts in Viral Infection

Takahashi¹,

Suzuki²

2009

TODJ

View full text Add to dashboard Cite

show abstract

“…Based on biochemical and microscopic evidence, a subpopulation of membrane-associated Nef is incorporated into lipid microdomains in cell lines but also primary resting T lymphocytes [105][106][107]. This raft association depends on Nef's myristoylation and is specifically mediated by a di-lysine motif at the Nef N-terminus [107,108]. The use of experimental enrichment of raft association (by virtue of an additional palmitoylation) or abrogation of its raft incorporation (by mutating the di-lysine motif) revealed that raft-association is dispensable for the receptor transport activities of Nef [108,109].…”

Section: Hiv Nef: Remixing Raft Compositionmentioning

confidence: 99%

“…This raft association depends on Nef's myristoylation and is specifically mediated by a di-lysine motif at the Nef N-terminus [107,108]. The use of experimental enrichment of raft association (by virtue of an additional palmitoylation) or abrogation of its raft incorporation (by mutating the di-lysine motif) revealed that raft-association is dispensable for the receptor transport activities of Nef [108,109]. In contrast, signal transduction properties of Nef appear to be governed by the raft-associated Nef subpopulation.…”

Section: Hiv Nef: Remixing Raft Compositionmentioning

confidence: 99%

“…Nef associates with a highly active subpopulation of cellular Pak2, a function that is well conserved among different Nef variants and that might correlate with some of its pathological properties [118][119][120]. This association of Nef with Pak2 kinase activity strictly depends on Nef's raft association and the integrity of these microdomains [106,108,121]. Combined imaging and flotation analysis suggested that this effect is mediated by recruiting the involved TCR machinery, including the Rac and Cdc42 GTPases as well as the Pak2 and Lck kinases into plasma membrane lipid raft domains [106,122].…”

Section: Hiv Nef: Remixing Raft Compositionmentioning

confidence: 99%

See 1 more Smart Citation

Viruses, lipid rafts and signal transduction

Rauch

Fackler

2007

Signal Transduction

Self Cite

View full text Add to dashboard Cite

Lipid rafts are defined as highly dynamic microdomains in cellular membranes that are enriched in sphingolipids, cholesterol and raft-targeted proteins. This particular lipid and protein composition is thought to facilitate protein-protein interactions to create microdomains with distinct biological properties. Lipid rafts have been implicated in central cellular processes such as signal transduction and protein trafficking. This review focuses on strategies used by three viral pathogens (measles virus, Epstein-Barr virus and human immunodeficiency virus) to manipulate their target cells by altering the signal transduction properties of such cellular microdomains in the infected host. Lipid raft characteristicsLipid raft microdomains are believed to provide a compartimentalisation of cellular membranes to regulate e. g. transport and signalling processes [1,2]. One prerequisite for the formation of such raft microdomains is the structure of the involved lipid species: sphingolipids possess long, largely saturated, and therefore not kinked, acyl chains which can become highly condensed by cholesterol. This effect is achieved either by complex formation between cholesterol and sphingolipids [3] or due to the hydrophobic properties of cholesterol that intercalates between the long acyl chains in order to shield from the aqueous surrounding [4,5]. The physical characteristics resulting from this interaction can be demonstrated in model membranes, simplified in vitro systems consisting of hydrated lipid bilayers. Depending on temperature, lipids undergo phase transitions from solid ordered (S o ) phase, which is hallmarked by rigid acyl side chains and restricted lipid mobility, to liquid disordered (L d ) state which leads to a increased lateral mobility. The presence of cholesterol allows the existence of a third state: the liquid ordered phase (L o ) featuring highly ordered acyl chains as well as increased lateral mobility compared to the S o state. Since L d and L o states can coexist in artificial membranes [6,7], it has been proposed that lipid rafts are equivalent to the L o state in model membranes, while the surrounding membrane is comparable to the L d phase [5,8].A multitude of studies assessed the characteristics of lipid rafts in a cellular context. It is believed that lipid rafts are small aggregates on cellular membranes [9]. Current studies estimate the size of lipid rafts to 5-20 nm which implies that a single raft can only comprise a small number of proteins [5,9]. The classical, much disputed, raft model assumed the existence of fixed lipid entities in the plasma membrane that can per se aggregate and sort proteins by in-or exclusion. Based on more recent findings, it is now believed that lipid rafts are submicroscopic, highly dynamic structures that are nucleated and/or stabilised by specifically interacting proteins and, as a result of that, can form larger signalling domains with defined raft lipid environment [5,10,11]. Such raft core resident proteins require specific targeting signals such ...

show abstract

HIV‐1 Nef is carried on the surface of extracellular vesicles

Vanpouille,

Brichacek,

Pushkarsky

et al. 2024

J of Extracellular Vesicle

View full text Add to dashboard Cite

Extracellular vesicles (EVs) serve as pivotal mediators of intercellular communication in both health and disease, delivering biologically active molecules from vesicle‐producing cells to recipient cells. In the context of HIV infection, EVs have been shown to carry the viral protein Nef, a key pathogenic factor associated with HIV‐related co‐morbidities. Despite this recognition, the specific localisation of Nef within the vesicles has remained elusive. This study addresses this critical knowledge gap by investigating Nef‐containing EVs. Less than 1% of the total released Nef was associated with EVs; most Nef existed as free protein released by damaged cells. Nevertheless, activity of EV‐associated Nef in downregulating the major cholesterol transporter ABCA1, a critical aspect linked to the pathogenic effects of Nef, was comparable to that of free Nef present in the supernatant. Through a series of biochemical and microscopic assays, we demonstrate that the majority of EV‐associated Nef molecules are localised on the external surface of the vesicles. This distinctive distribution prompts the consideration of Nef‐containing EVs as potential targets for immunotherapeutic interventions aimed at preventing or treating HIV‐associated co‐morbidities. In conclusion, our results shed light on the localisation and functional activity of Nef within EVs, providing valuable insights for the development of targeted immunotherapies to mitigate the impact of HIV‐associated co‐morbidities.

show abstract

Specific and distinct determinants mediate membrane binding and lipid raft incorporation of HIV-1SF2 Nef

Cited by 64 publications

References 71 publications

Role of Membrane Rafts in Viral Infection

Role of Membrane Rafts in Viral Infection

Viruses, lipid rafts and signal transduction

HIV‐1 Nef is carried on the surface of extracellular vesicles

Contact Info

Product

Resources

About