Perspectives on Non-BLT Humanized Mouse Models for Studying HIV Pathogenesis and Therapy
Abstract
:1. Introduction
Generation | Strain | Genetic Manipulation | Original References or JAX a Stock Numbers |
---|---|---|---|
Current | NSG | Il2Rγ KO (complete) on NOD/SCID background | [14] |
NOG | Il2Rγ KO (truncated) on NOD/SCID background | [15] | |
NOJ | Jak3 KO on NOD/SCID background | [9] | |
NRG | Rag1 and Il2Rγ KO on NOD background | [16] | |
DKO/BRG | Rag2 and Il2Rγ KO on BALB/c background | [17] | |
Next | NSG-A2/HHD | HLA-A2 and human β2-microglobulin Tg on NSG background | [18] |
NSG-DR4 | HLA-DR4 Tg on NSG background | 029295 | |
NSG-Ab0DR4 | HLA-DR4 Tg and mouse MHC-II KO on NSG background | 031566 | |
DRAG | HLA-DR4 Tg on NRG background | [19] | |
DRAGA | HLA-A2 Tg on DRAG background | [20] | |
BRGS | NOD Sirpa backcrossed to BRG background | [21,22] | |
BRGST | mouse Tslp Tg on BRGS background | [23] | |
NSG-SGM3 | human SCF, GM-CSF, and IL3 Tg on NSG background | [24] | |
NSG-Quad | human M-CSF Tg on NSG-SGM3 background | [7] | |
MISTRG | human M-CSF, SCF, GM-CSF, IL3, thrombopoietin, and SIRPA KI on DKO background | [25] | |
SGR-15 | human IL15 and SIRPA KI on DKO background | [26] | |
NSG hIL-7xhIL-15 | human IL7 and IL15 KI on NSG background | [27] | |
NSG-Tg(huIL6) | human IL6 Tg on NSG background | [7] | |
NOG-hIL-34 | human IL34 Tg on NOG background | [28] |
2. Immunological Characteristics of Non-BLT Humanized Mice
3. Current Approaches to Overcoming Limitations of Non-BLT Humanized Mice
3.1. Modification of HSC Transplantation
3.2. Supplementation of Human Cytokines
3.3. Transgenic or Knock-in Mice
4. Dynamics of Plasma Viral Load in HIV-Challenged Humanized Mice
4.1. From Eclipse to Burst Phase
4.2. After Burst Phase
5. Pathology in the Early Stage of HIV Infection
5.1. Characteristics of CD4+ T-Cell Death
5.2. Immune Activation
6. Pathology in the Gastrointestinal Tissues
7. Pathology in the CNS
8. Consideration of Suitable Mouse Models for Long-Term Analysis of HIV Infection
8.1. Broadly Cross-Reactive Neutralizing Antibodies
8.2. Gene Therapy
8.3. In Vivo Latency
9. Concluding Remarks
Author Contributions
Funding
Institutional Review Board Statement
Informed Consent Statement
Data Availability Statement
Acknowledgments
Conflicts of Interest
References
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Category (Section No.) | Major Findings | Mouse Strain | Source of HSC | HIV-1 Strain (Tropism) | References |
---|---|---|---|---|---|
Target cells of infection (4.1) | The central memory and/or effector memory subsets of CD4+ T cells are preferentially infected with HIV-1. | NOG | CB | JRCSF (R5) | [42] |
NOJ | CB | NL-AD8-D (R5) | [38] | ||
Kinetics of plasma VL (4.2) | Higher level of plasma VL of R5 HIV-1 compared to X4 HIV-1. | DKO | FL | BaL (R5), NL4-3 (X4), NLENG1-IRES (X4) | [72,73] |
BALB/c-Rag1−/−γc−/− | FL | BaL (R5), NL4-3 (X4) | [68] | ||
NOJ | CB | NL-AD8-D (R5), NL-E (X4) | [77] | ||
Depletion of CD8+ T cells enhances plasma VL. | NSG | CB | ADA (R5) | [101] | |
Blockage of PD-1 pathway decreases plasma VL and restores CD4+ T-cell counts. | DKO | FL | BaL (R5) | [102] | |
Vpu contributes to the efficient virus spread. Cell-to-cell contact with infected cells occurs in the spleen independently of Vpu. | NOG | FL | AD8 (R5), AD8Dvpu (R5) | [79] | |
Cell death (5.1) | HIV-1-infected Treg cells undergo apoptosis. | DKO | FL | R3A (dual) | [114] |
The loss of Treg cells increases the slope of HIV-1 growth. | NOG | FL | JRCSF (R5) | [112] | |
Non-apoptotic CD4+ T-cell death, including pyroptosis and necroptosis, are induced during the early phase of HIV-1 infection. | NOJ | CB | NL-AD8 (R5), NL-AD8-D (R5), NL4-3 (X4), NL-E (X4) | [111] | |
Innate immune activation (5.2) | pDC depletion leads to the absence of plasma IFN-I and the enhanced plasma HIV-1 during the early infection phase. | DKO or NRG | FL | R3A (dual) | [113] |
Blocking of the IFN-I pathway during the chronic/persistent infection phase without cART treatment enhances plasma VL. | |||||
Gastrointestinal tissues (6) | Tfh cells in the mucosal tissues are highly permissive to HIV-1. | DRAG | CB | US-1 (R5), BaL (R5) | [69] |
CNS (7) | Macrophages can sustain HIV-1 replication in the absence of T cells in vivo. Human myeloid cells accumulate in the brain following HIV-1 infection. | NOD-SCID | FL or CB | ADA (R5), CHO40 (R5), CHO40-4013 env (R5) | [150] |
Introduction of human IL-34 induces significant numbers of microglial cells and is capable of robust HIV-1 infection in the brain. | NOG-IL-34 | CB | ADA (R5) | [28] | |
Antibody therapy (8.1) | The SF12 bNAb suppresses plasma VL and exerts strong selective pressure on HIV-1. | NRG | CB | YU2 (R5) | [169] |
The 1-18 bNAb suppresses plasma VL and restricts HIV-1 escape. | NRG | CB | YU2 (R5) | [170] | |
The PGDM1400 bNAb provides protection against HIV-1 challenge. | NSG | CB | JRCSF (R5) | [173] | |
FcR-mediated immune responses contribute to the clearance of HIV-1-infected cells. | NRG | FL | YU2 (R5) | [171] | |
YU2 and its derivatives (R5) | [172] | ||||
Gene therapy (8.2) | Humanized mice reconstituted with soluble CD4 gene-transduced HSCs reduce plasma VL over time. | NSG | CB | BaL (R5) | [176] |
Humanized mice reconstituted with HSCs expressing microRNAs against CCR5 decrease plasma VL over months. | CB | YU2 (R5), JRCSF (R5) | [177] | ||
Humanized mice reconstituted with PGT128 bNAb genes-transduced HSCs decrease plasma VL. | FL | BaL (R5) | [178] | ||
Latency (8.3) | Latent infection models are achieved by treatment with cART or the combined administration of CCR5-targeting drugs. | NSG | FL | BaL (R5) | [162] |
CB | [75] | ||||
Using reporter HIV-1 enables to sensitively detect latent virus, which is enriched in PD-1+ and TIGIT+ CD4+ T cells. | NSG | FL | NL4-3-HA (X4) | [161] | |
Longitudinal non-invasive bioluminescent imaging of HIV-1 infection dynamics using nanoluciferase-expressing reporter HIV-1 can sensitively detect infected cells following cART withdrawal. | NSG | FL | Q23.BG505.Nluc* (R5) | [163] | |
Latent HIV-1 in infected monocytes but not in CD4+ T cells is reactivated by a bromodomain inhibitor. | NRG | FL | JRCSF (R5) | [160] | |
The elimination of latent HIV is achievable by a combination of the CRISPER-Cas9 system and long-active slow-effective release ART. | NSG | FL | NL4-3 (X4) | [159] |
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Terahara, K.; Iwabuchi, R.; Tsunetsugu-Yokota, Y. Perspectives on Non-BLT Humanized Mouse Models for Studying HIV Pathogenesis and Therapy. Viruses 2021, 13, 776. https://doi.org/10.3390/v13050776
Terahara K, Iwabuchi R, Tsunetsugu-Yokota Y. Perspectives on Non-BLT Humanized Mouse Models for Studying HIV Pathogenesis and Therapy. Viruses. 2021; 13(5):776. https://doi.org/10.3390/v13050776
Chicago/Turabian StyleTerahara, Kazutaka, Ryutaro Iwabuchi, and Yasuko Tsunetsugu-Yokota. 2021. "Perspectives on Non-BLT Humanized Mouse Models for Studying HIV Pathogenesis and Therapy" Viruses 13, no. 5: 776. https://doi.org/10.3390/v13050776