The HIV-1 Pathogenicity Factor Nef Interferes with Maturation of Stimulatory T-lymphocyte Contacts by Modulation of N-Wasp Activity

Haller, Claudia; Rauch, Susanne; Michel, Nico; Hannemann, Sebastian; Lehmann, Maik J.; Keppler, Oliver T.; Fackler, Oliver T.

doi:10.1074/jbc.m513802200

Cited by 90 publications

(158 citation statements)

References 55 publications

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“…At this time point, control cells displayed hallmarks of early T cell activation, including cell spreading and formation of circumferential F-actin rings, both of which were potently inhibited by the presence of Nef, as reported earlier (Fig. 1A) (37)(38)(39)48). Coexpression of the TCR z-chain fused to GFP (TCR.GFP) in these cells revealed the formation of numerous MCs at cell-cover glass stimulatory contacts that were distributed across the entire cell diameter, including its periphery (see schematic in Supplemental Fig.…”

Section: Early Tcr MC Formation Is Undisturbed In the Presence Of Nefsupporting

confidence: 53%

“…T cell spreading and actin ring assay T cell activation using anti-CD3ε-coated stimulatory surfaces for TCRmediated cell spreading was essentially carried out as described (37,45). Briefly, microscope cover glasses (Marienfeld) were placed on a parafilmcoated petri dish and incubated with a 0.01% poly-lysine (Sigma-Aldrich) solution at room temperature for 10 min.…”

Section: Analysis Of Expression Levelsmentioning

confidence: 99%

“…Subsequently, cells were fixed for 20 min (Jurkat T lymphocytes) or 90 min (infected PBL) by adding TBS-3% paraformaldehyde. After permeabilization with TBS-0.1% Triton X-100 for 1-5 min, the cells were blocked with TBS-1% BSA for 30 min and stained, as previously described (37). Cover glasses were mounted in LinMount (Linaris).…”

Section: Analysis Of Expression Levelsmentioning

confidence: 99%

“…Two days after transfection, culture supernatants were harvested and the HIV-1 p24 Ag concentration was determined by a p24 Ag ELISA. Isolation, activation, and HIV-1 infection of PBL were carried out, as described (37). A total of 1000 ng p24 was used to spin-infect 5 3 10 6 Jurkat cells or PBLs.…”

Section: Hiv-1 Production and Infectionmentioning

confidence: 99%

“…In contrast, HIV-1 Nef severely impairs the formation and organization of IS structures between Nef-expressing T lymphocytes and APCs by reducing the frequency of IS formation, blocking Factin polarization at cell-cell contacts, and inducing mislocalization of the TCR itself as well as its effector kinase Lck (28,(35)(36)(37)(38)(39). These morphological alterations at the IS were accompanied by interference with early TCR signaling such as induction of tyrosine phosphorylation (36,37,39). We recently reported that Nef achieves enhanced T cell activation responses despite this disruption of early signaling events by the assembly of active signaling complexes at the trans Golgi network (TGN) (40).…”

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confidence: 99%

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HIV-1 Nef Limits Communication between Linker of Activated T Cells and SLP-76 To Reduce Formation of SLP-76–Signaling Microclusters following TCR Stimulation

Abraham

Bankhead

Pan

et al. 2012

The Journal of Immunology

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Signal initiation by engagement of the TCR triggers actin rearrangements, receptor clustering, and dynamic organization of signaling complexes to elicit and sustain downstream signaling. Nef, a pathogenicity factor of HIV, disrupts early TCR signaling in target T cells. To define the mechanism underlying this Nef-mediated signal disruption, we employed quantitative single-cell microscopy following surface-mediated TCR stimulation that allows for dynamic visualization of distinct signaling complexes as microclusters (MCs). Despite marked inhibition of actin remodeling and cell spreading, the induction of MCs containing TCR-CD3 or ZAP70 was not affected significantly by Nef. However, Nef potently inhibited the subsequent formation of MCs positive for the signaling adaptor Src homology-2 domain-containing leukocyte protein of 76 kDa (SLP-76) to reduce MC density in Nef-expressing and HIV-1–infected T cells. Further analyses suggested that Nef prevents formation of SLP-76 MCs at the level of the upstream adaptor protein, linker of activated T cells (LAT), that couples ZAP70 to SLP-76. Nef did not disrupt pre-existing MCs positive for LAT. However, the presence of the viral protein prevented de novo recruitment of active LAT into MCs due to retargeting of LAT to an intracellular compartment. These modulations in MC formation and composition depended on Nef’s ability to simultaneously disrupt both actin remodeling and subcellular localization of TCR-proximal machinery. Nef thus employs a dual mechanism to disturb early TCR signaling by limiting the communication between LAT and SLP-76 and preventing the dynamic formation of SLP-76–signaling MCs.

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Section: Early Tcr MC Formation Is Undisturbed In the Presence Of Nefsupporting

confidence: 53%

Section: Analysis Of Expression Levelsmentioning

confidence: 99%

Section: Analysis Of Expression Levelsmentioning

confidence: 99%

Section: Hiv-1 Production and Infectionmentioning

confidence: 99%

mentioning

confidence: 99%

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HIV-1 Nef Limits Communication between Linker of Activated T Cells and SLP-76 To Reduce Formation of SLP-76–Signaling Microclusters following TCR Stimulation

Abraham

Bankhead

Pan

et al. 2012

The Journal of Immunology

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Viruses, lipid rafts and signal transduction

Rauch

Fackler

2007

Signal Transduction

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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 ...

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Targeting Cellular Cofactors in HIV Therapy

Dürr

Keppler

Christ

et al. 2014

Topics in Medicinal Chemistry

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Besides viral proteins cellular factors play a key role in the replication of the human immunodeficiency virus HIV-1. The outcome of virus replication is determined by the balance between the activity of a number of cellular dependency factors and restriction factors. Whereas the first are essential cofactors for diverse steps in the viral replication cycle, the latter counteract virus replication by sensing particular viral components as non-self, often as mediators of the innate immune system. Cellular cofactors include receptors for HIV-1 entry, LEDGF as cofactor for the viral integrase, the RNA helicase DDX3 involved in the nuclear export of unspliced viral RNAs, and diverse cellular kinases that promote viral replication. Cellular restriction factors are often antagonized by HIV-1 accessory proteins in order to counteract their restrictive function on viral replication. Although cellular cofactors in the HIV field are understood as factors promoting viral replication, we add a subchapter on the most important restriction factors (Trim5α, APOBEC3G, SAMHD1, and tetherin/BST-2). Today highly active antiretroviral therapy (HAART) mostly targets HIV proteins like reverse transcriptase, protease, or integrase to specifically interfere with virus replication. However, the identification of cellular cofactors and the increasing knowledge on their mode of action at R. Dürr and U. Dietrich (*) Georg-Speyer-Haus, Institute for Tumor Biology and Experimental Therapy, Paul-Ehrlich-Str. 42-44, 60596 Frankfurt, Germany e-mail: duerr@gsh.uni-frankfurt.de; ursula.dietrich@gsh.uni-frankfurt.de O. Keppler Institute of Medical Virology, Goethe University, Frankfurt, Germany e-mail: oliver.keppler@kgu.de F. Christ Laboratory for Molecular Virology and Gene Therapy, K.U. Leuven, Leuven, Belgium e-mail: frauke.christ@med.kuleuven.be E. Crespan, A. Garbelli, and G. Maga Institute of Molecular Genetics, IGM-CNR, Pavia, Italy e-mail: emmanuelecrespan@gmail.com; agarbelli@gmail.com; maga@igm.cnr.it defined steps in the HIV-1 replication cycle have opened new avenues towards the development of HIV-1 inhibitors. Here we summarize the most important cellular factors involved in HIV-1 replication along with therapeutic approaches developed to target them, preferentially without harming their normal cellular function.

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The HIV-1 Pathogenicity Factor Nef Interferes with Maturation of Stimulatory T-lymphocyte Contacts by Modulation of N-Wasp Activity

Cited by 90 publications

References 55 publications

HIV-1 Nef Limits Communication between Linker of Activated T Cells and SLP-76 To Reduce Formation of SLP-76–Signaling Microclusters following TCR Stimulation

HIV-1 Nef Limits Communication between Linker of Activated T Cells and SLP-76 To Reduce Formation of SLP-76–Signaling Microclusters following TCR Stimulation

Viruses, lipid rafts and signal transduction

Targeting Cellular Cofactors in HIV Therapy

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