Single-cell glycolytic activity regulates membrane tension and HIV-1 fusion

Coomer, Charles A.; Carlón-Andrés, Irene; Iliopoulou, Maro; Dustin, Michael L.; Compeer, Ewoud B.; Compton, Alex A.; Padilla‐Parra, Sergi

doi:10.1371/journal.ppat.1008359

Cited by 32 publications

(26 citation statements)

References 77 publications

(109 reference statements)

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“…For a detailed review on imaging HIV entry, uncoating, and nuclear entry, the reader could refer to the manuscript by Francis and Melikyan [39]. Instead, fluorescent imaging approaches have used the lipophilic dye DiD to localise HIV virions and resolve different entry steps [40][41][42][43][44][45][46]. When combined with a second intraviral marker (e.g., the Viral Protein R (Vpr) labelled with EGFP), the fluorescence signal from membrane dyes may be employed to report on viral envelope fusion with cell membranes [40,42].…”

Section: Imaging Lipids During Hiv Entrymentioning

confidence: 99%

“…In the case of plasma membrane entry, the membrane signal is diluted in the immense volume of cell membranes upon fusion, as opposed to the intraviral marker that stays trapped in the core and is finally released to the cytosol [41,42]. On the other hand, during endosomal entry, the membrane dye is not diluted due to the small volume of endosomes, but the intraviral marker signal disappears after capsid release to the cytosol [42,46]. More precisely, DiD fluorescence signal lost reports on hemifusion, i.e., the merger of the external leaflets of both membranes [43].…”

Section: Imaging Lipids During Hiv Entrymentioning

confidence: 99%

“…Some commercial setups are readily implementing fluorescence lifetime imaging microscopy (FLIM) for spatially-resolved measurement of the fluorescence lifetime of fluorescent tags. Lifetime can provide additional information about the structure or environment of a fluorescent molecule and has successfully been employed in the HIV [44,46] and membrane biophysics [20] research fields. Not only established microscopy techniques are being refined, but also new ones are being developed.…”

Section: Future Directionsmentioning

confidence: 99%

“…Advances in fluorescent dye design and synthesis are also providing new tools to unravel the mysteries of virus infection. With respect to new dyes, the reporting of unprecedented biophysical properties provides quantitative information about cell membranes [20], and has already been exploited in the study of HIV entry [46]. In the case of the small-sized HIV virions, exchangeable dyes constitute an interesting alternative to traditional membrane dyes, since they can circumvent photobleaching.…”

Section: Future Directionsmentioning

confidence: 99%

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Fluorescence Microscopy of the HIV-1 Envelope

Carravilla

Nieva

Eggeling

2020

Viruses

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Human immunodeficiency virus (HIV) infection constitutes a major health and social issue worldwide. HIV infects cells by fusing its envelope with the target cell plasma membrane. This process is mediated by the viral Env glycoprotein and depends on the envelope lipid composition. Fluorescent microscopy has been employed to investigate the envelope properties, and the processes of viral assembly and fusion, but the application of this technique to the study of HIV is still limited by a number of factors, such as the small size of HIV virions or the difficulty to label the envelope components. Here, we review fluorescence imaging studies of the envelope lipids and proteins, focusing on labelling strategies and model systems.

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Section: Imaging Lipids During Hiv Entrymentioning

confidence: 99%

Section: Imaging Lipids During Hiv Entrymentioning

confidence: 99%

Section: Future Directionsmentioning

confidence: 99%

Section: Future Directionsmentioning

confidence: 99%

See 2 more Smart Citations

Fluorescence Microscopy of the HIV-1 Envelope

Carravilla

Nieva

Eggeling

2020

Viruses

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“…To connect transcriptional downregulation of glycolytic enzymes with metabolic profiling, we first used a recently developed FRET-based biosensor system in living TZM-bl cells infected with HIV-1 (San Martín et al, 2013). We combined this reporter system with labelled HIV-1 Gag to measure the stability of the glycolysis surrogate marker, lactate, at a single cell resolution using Fluorescence Lifetime Microscopy (FLIM) (Coomer et al, 2020) (Figure 2A). Data showed a significant decrease of lactate levels in cells infected with HIV-1JR-FL 3 dpi, as compared to No Env infected cells.…”

Section: Decreased Glycolytic Metabolism During Productive and Latentmentioning

confidence: 99%

Glycolysis downregulation is a hallmark of HIV-1 latency and sensitizes infected cells to oxidative stress

Shytaj

Procopio

Tarek

et al. 2020

Preprint

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HIV-1 infects lymphoid and myeloid cells, which can harbor a latent proviral reservoir responsible for maintaining lifelong infection. Glycolytic metabolism has been identified as a determinant of susceptibility to HIV-1 infection, but its role in the development and maintenance of HIV-1 latency has not been elucidated. By combining transcriptomic, proteomic and metabolomic analysis, we here show that transition to latent HIV-1 infection downregulates glycolysis, while viral reactivation by conventional stimuli reverts this effect. Decreased glycolytic output in latently infected cells is associated with downregulation of NAD+/NADH. Consequently, infected cells rely on the parallel pentose phosphate pathway and its main product, the antioxidant NADPH, fueling antioxidant pathways maintaining HIV-1 latency. Of note, blocking NADPH downstream effectors, thioredoxin and glutathione, favors HIV-1 reactivation from latency in lymphoid and myeloid cellular models. This provides a “shock and kill effect” decreasing proviral DNA in cells from people-living-with-HIV/AIDS. Overall, our data show that downmodulation of glycolysis is a metabolic signature of HIV-1 latency that can be exploited to target latently infected cells with eradication strategies.

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Mathematical model for force and energy of virion-cell interactions during full engulfment in HIV: Impact of virion maturation and host cell morphology

Kruse

Abdalrahman

Selhorst

et al. 2023

Biomech Model Mechanobiol

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Viral endocytosis involves elastic cell deformation, driven by chemical adhesion energy, and depends on physical interactions between the virion and cell membrane. These interactions are not easy to quantify experimentally. Hence, this study aimed to develop a mathematical model of the interactions of HIV particles with host cells and explore the effects of mechanical and morphological parameters during full virion engulfment. The invagination force and engulfment energy were described as viscoelastic and linear-elastic functions of radius and elastic modulus of virion and cell, ligand-receptor energy density and engulfment depth. The influence of changes in the virion-cell contact geometry representing different immune cells and ultrastructural membrane features and the decrease in virion radius and shedding of gp120 proteins during maturation on invagination force and engulfment energy was investigated. A low invagination force and high ligand-receptor energy are associated with high virion entry ability. The required invagination force was the same for immune cells of different sizes but lower for a local convex geometry of the cell membrane at the virion length scale. This suggests that localized membrane features of immune cells play a role in viral entry ability. The available engulfment energy decreased during virion maturation, indicating the involvement of additional biological or biochemical changes in viral entry. The developed mathematical model offers potential for the mechanobiological assessment of the invagination of enveloped viruses towards improving the prevention and treatment of viral infections.

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Single-cell glycolytic activity regulates membrane tension and HIV-1 fusion

Cited by 32 publications

References 77 publications

Fluorescence Microscopy of the HIV-1 Envelope

Fluorescence Microscopy of the HIV-1 Envelope

Glycolysis downregulation is a hallmark of HIV-1 latency and sensitizes infected cells to oxidative stress

Mathematical model for force and energy of virion-cell interactions during full engulfment in HIV: Impact of virion maturation and host cell morphology

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