Retroviral Restriction Factors and Their Viral Targets: Restriction Strategies and Evolutionary Adaptations

Boso, Guney; Kozak, Christine A.

doi:10.3390/microorganisms8121965

Cited by 24 publications

(22 citation statements)

References 354 publications

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“…Viruses 2021, 13, 1864 2 of 19 The various laboratory strains and wild mouse subspecies differ in their susceptibility to MLVs, and to virus-induced disease, due to host factors that can inhibit virus replication at different stages of the virus life cycle, including entry, reverse transcription, transport to the nucleus, transcription, and budding [8]. Some of these factors have no known function other than virus restriction, while others serve important host functions that also facilitate virus replication but can have restrictive polymorphic variants.…”

Section: Introductionmentioning

confidence: 99%

Patterns of Coevolutionary Adaptations across Time and Space in Mouse Gammaretroviruses and Three Restrictive Host Factors

Boso

Lam

Bamunusinghe

et al. 2021

Viruses

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The classical laboratory mouse strains are genetic mosaics of three Mus musculus subspecies that occupy distinct regions of Eurasia. These strains and subspecies carry infectious and endogenous mouse leukemia viruses (MLVs) that can be pathogenic and mutagenic. MLVs evolved in concert with restrictive host factors with some under positive selection, including the XPR1 receptor for xenotropic/polytropic MLVs (X/P-MLVs) and the post-entry restriction factor Fv1. Since positive selection marks host-pathogen genetic conflicts, we examined MLVs for counter-adaptations at sites that interact with XPR1, Fv1, and the CAT1 receptor for ecotropic MLVs (E-MLVs). Results describe different co-adaptive evolutionary paths within the ranges occupied by these virus-infected subspecies. The interface of CAT1, and the otherwise variable E-MLV envelopes, is highly conserved; antiviral protection is afforded by the Fv4 restriction factor. XPR1 and X/P-MLVs variants show coordinate geographic distributions, with receptor critical sites in envelope, under positive selection but with little variation in envelope and XPR1 in mice carrying P-ERVs. The major Fv1 target in the viral capsid is under positive selection, and the distribution of Fv1 alleles is subspecies-correlated. These data document adaptive, spatial and temporal, co-evolutionary trajectories at the critical interfaces of MLVs and the host factors that restrict their replication.

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Section: Introductionmentioning

confidence: 99%

Patterns of Coevolutionary Adaptations across Time and Space in Mouse Gammaretroviruses and Three Restrictive Host Factors

Boso

Lam

Bamunusinghe

et al. 2021

Viruses

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“…Many RF suppress viral replication by directly targeting conserved essential steps of the viral cycle, including viral entry, uncoating, DNA integration, proviral genome transcription, and budding, thus exerting broad antiviral activity. In contrast, some RF inhibit viral pathogens more indirectly by affecting the stability, localization or activity of cellular factors or limiting the availability of cellular resources such as nucleotides needed in the viral replication cycle [ 51 , 52 ]. While each RF uses a distinct mechanism of inhibition, the virus has equally evolved complex strategies to neutralize their inhibitory effect.…”

Section: Cell Modelsmentioning

confidence: 99%

HTLV-1 Infection and Pathogenesis: New Insights from Cellular and Animal Models

Forlani

Shallak

Accolla

et al. 2021

IJMS

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Since the discovery of the human T-cell leukemia virus-1 (HTLV-1), cellular and animal models have provided invaluable contributions in the knowledge of viral infection, transmission and progression of HTLV-associated diseases. HTLV-1 is the causative agent of the aggressive adult T-cell leukemia/lymphoma and inflammatory diseases such as the HTLV-1 associated myelopathy/tropical spastic paraparesis (HAM/TSP). Cell models contribute to defining the role of HTLV proteins, as well as the mechanisms of cell-to-cell transmission of the virus. Otherwise, selected and engineered animal models are currently applied to recapitulate in vivo the HTLV-1 associated pathogenesis and to verify the effectiveness of viral therapy and host immune response. Here we review the current cell models for studying virus–host interaction, cellular restriction factors and cell pathway deregulation mediated by HTLV products. We recapitulate the most effective animal models applied to investigate the pathogenesis of HTLV-1-associated diseases such as transgenic and humanized mice, rabbit and monkey models. Finally, we summarize the studies on STLV and BLV, two closely related HTLV-1 viruses in animals. The most recent anticancer and HAM/TSP therapies are also discussed in view of the most reliable experimental models that may accelerate the translation from the experimental findings to effective therapies in infected patients.

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“…Specific IFN-induced cellular gene products are able to restrict different retroviruses, including FVs [ 121 , 122 , 130 , 131 , 132 , 133 , 134 , 135 , 136 , 137 , 138 , 139 , 140 , 141 , 142 ]. Similar to other retroviruses, TRIM5α targets the core of PFV, SFV, and FFV during early post-infection events in a species-dependent manner [ 135 , 139 , 143 ].…”

Section: Innate Immune Sensing Of Foamy Virusesmentioning

confidence: 99%

Foamy Viruses, Bet, and APOBEC3 Restriction

Vasudevan

Becker

Luedde

et al. 2021

Viruses

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Non-human primates (NHP) are an important source of viruses that can spillover to humans and, after adaptation, spread through the host population. Whereas HIV-1 and HTLV-1 emerged as retroviral pathogens in humans, a unique class of retroviruses called foamy viruses (FV) with zoonotic potential are occasionally detected in bushmeat hunters or zookeepers. Various FVs are endemic in numerous mammalian natural hosts, such as primates, felines, bovines, and equines, and other animals, but not in humans. They are apathogenic, and significant differences exist between the viral life cycles of FV and other retroviruses. Importantly, FVs replicate in the presence of many well-defined retroviral restriction factors such as TRIM5α, BST2 (Tetherin), MX2, and APOBEC3 (A3). While the interaction of A3s with HIV-1 is well studied, the escape mechanisms of FVs from restriction by A3 is much less explored. Here we review the current knowledge of FV biology, host restriction factors, and FV–host interactions with an emphasis on the consequences of FV regulatory protein Bet binding to A3s and outline crucial open questions for future studies.

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Retroviral Restriction Factors and Their Viral Targets: Restriction Strategies and Evolutionary Adaptations

Cited by 24 publications

References 354 publications

Patterns of Coevolutionary Adaptations across Time and Space in Mouse Gammaretroviruses and Three Restrictive Host Factors

Patterns of Coevolutionary Adaptations across Time and Space in Mouse Gammaretroviruses and Three Restrictive Host Factors

HTLV-1 Infection and Pathogenesis: New Insights from Cellular and Animal Models

Foamy Viruses, Bet, and APOBEC3 Restriction

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