Strategies to Inhibit Hepatitis B Virus at the Transcript Level
Abstract
:1. Introduction
2. Basic HBV Molecular Biology
3. Approved Drugs and Potential Therapeutic Options against Chronic Hepatitis B
4. Templates of Transcription: cccDNA and Integrants
5. Host and Viral Mediators of HBV Transcription
Substance | Property | Target | Clinical Status | IC50 HBV Transcription | Inventor | Reference |
---|---|---|---|---|---|---|
IFN-α | Cytokine | STAT1/2,histones | Approved | 180 μg/week 1500 IU/mL | Merck 2 | [110,111] |
rIL-6 | Cytokine | STAT3,HNF1α/4α | Preclinical | 20 ng/mL | n/a | [112,113] |
TGF-β | Cytokine | HNF4α,AID | Preclinical | 10 ng/mL | n/a | [114,115,116] |
Tazarotene(Tazorac) | Small molecule | RARβ/γ | Approved 3 | 20–75 nM | Allergan | [117] |
Tamibarotene(Am80) | Small molecule | RARα | Approved 3 | ≈1 nM | Nippon Shinyaku | [118] |
Isotretinoin(Accutane) | Small molecule | RAR/RXR | Approved 3 | 1.2 μM | Roche | [119] |
Bexarotene(Targretin) | Small molecule | RXRα | Approved 3 | 1–5 μM | Ligand Pharma | [120] |
GW4064 | Small molecule | FXRα | Preclinical | 0.2 μM | GSK | [121,122] |
EYP001 | Small molecule | FXR | Phase II | 1.25–2.5 μM | Enyo Pharma | [123] |
T0901317 | Small molecule | LXRα/β | Preclinical | 0.3–3 μM | Merck | [124] |
GW3965 | Small molecule | LXRα/β | Preclinical | 0.3–3 μM | GSK | [124] |
MLN4924 | Small molecule | NAE1 | Phase II/III 3 | 290 nM | Takeda | [125,126,127] |
Nitazoxanide | Small molecule | HBx-DDB1 | Approved 3 | 20 μM | Romark Lab. | [128,129] |
6. Strategies Targeting Viral Transcription
6.1. Cytokines
6.2. Retinoic Acid Receptor Agonists
6.3. Retinoid X Receptor Agonists
6.4. Farnesoid X Receptor Agonists
6.5. Liver X Receptor Agonists
6.6. Inhibitors Acting on the HBx-DDB1 Complex
7. Strategies to Degrade Existing Transcripts
7.1. Interferon Stimulated Genes (ISGs)
7.2. Terminal Nucleotidyltransferase
7.3. Innate Immune Agonists
7.4. shRNA and siRNA
7.5. Single-Stranded Oligonucleotides
7.6. MicroRNAs
8. Unanswered Questions
8.1. What Is the Next Step for the Development of Nuclear Receptor Agonists?
8.2. Does Preventing HBx-Dependent Transcription from cccDNA Lead to a Complete Repression?
8.3. Are Differences between mRNA from cccDNA, mRNA from Integrants, and Cellular mRNA Transcripts Relevant?
8.4. Can RNAi Strategies Achieve Sustained HBsAg Clearance?
9. Conclusions
Author Contributions
Funding
Institutional Review Board Statement
Informed Consent Statement
Acknowledgments
Conflicts of Interest
References
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Substance | Property | Target | Clinical Status | Effective Dose | Inventor | Reference |
---|---|---|---|---|---|---|
RG7834(Ro7020322) | Small molecule | TENT4A/B | Phase I | 2–6 nM | Roche | [153,154] |
DHQ-1 | Small molecule | Unclear | Preclinical | 100 nM | Blumberg Institute | [156] |
GS-9620(Vesatolimod) | Small molecule | TLR7 | Phase II | - 3 | Gilead | [157,158,159] |
GS-9688(Selgantolimod) | Small molecule | TLR8 | Phase II | - 3 | Gilead | [160,161,162] |
RG7854 | Small molecule | TLR7/8 | Phase I | n/a | Roche | Undisclosed |
SB 9200(Iranigivir) | Small molecule | RIG-I and NOD2 | Phase II | 30 mg/kg 4 | Spring Bank Pharma | [163] |
AB-452 | Undisclosed | HBV RNA | Phase I 1 | n/a | Arbutus Biopharm. | [164] |
HBVU6no.2 | shRNA | HBV S region | Preclinical | <5 μg 5 | n/a | [165] |
HBV765 | shRNA | HBV S region | Preclinical | 2 × 109 PFU 6 | n/a | [166,167] |
ALN-HBV(ALN-HBV01) | GalNAc-siRNA | n/a | Phase I 2 | n/a | Alnylam Pharma | [168] |
ARC-520 § | GalNAc-Chol-siRNA | HBV X region | Phase II 2 | <1 mg/kg 7 | Arrowhead Pharma | [169,170] |
ARB-1467(TKM HBV) | siRNA | S and X regions | Phase II | 0.4 mg/kg 8 | Arbutus Biopharma | [171] |
VIR-2218(ALN-HBV02) | GalNAc-siRNA | HBV X region | Phase I/II | n/a | Alnylam and VIR | EASL 2020 |
JNJ-3989(ARO-HBV) | siRNA pool | S and X regions | Phase II | <400mg/month | Arrowhead and Janssen | [172] |
AB-729 | GalNAc-siRNA | HBV RNA | Phase I | 6 nM | Arbutus Biopharma | [173] |
RG6346(DCR-HBVS) | GalXc-siRNA | n/a | Phase I/II | n/a | Dicerna Pharma and Roche | AASLD 2020 |
GSK3228836 (IONIS-HBVRx) | Antisense oligonucleotide | HBV X region | Phase II | n/a | IONIS Pharma and GSK | EASL 2020 |
GSK3389404 (IONIS-HBVLRx) | Antisense oligonucleotide | HBV X region | Phase II | n/a | IONIS Pharma and GSK | [174] |
LNA-Alexa | Oligonucleotide | pgRNA | Preclinical | 5 nM | n/a | [175] |
Ro7062931(LNA-SSO) | GalNAc-Oligonucleotide | HBV X region | Phase I | ≈1 μM | Roche | [168] |
Lunar-HBV | UNA oligomer | S and X regions | Preclinical | n/a | Arcturus and Janssen | AASLD 2016 |
miR-122 mimic | microRNA | HBV RNA | Preclinical | 40 nM | n/a | [176,177] |
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Qu, B.; Brown, R.J.P. Strategies to Inhibit Hepatitis B Virus at the Transcript Level. Viruses 2021, 13, 1327. https://doi.org/10.3390/v13071327
Qu B, Brown RJP. Strategies to Inhibit Hepatitis B Virus at the Transcript Level. Viruses. 2021; 13(7):1327. https://doi.org/10.3390/v13071327
Chicago/Turabian StyleQu, Bingqian, and Richard J. P. Brown. 2021. "Strategies to Inhibit Hepatitis B Virus at the Transcript Level" Viruses 13, no. 7: 1327. https://doi.org/10.3390/v13071327
APA StyleQu, B., & Brown, R. J. P. (2021). Strategies to Inhibit Hepatitis B Virus at the Transcript Level. Viruses, 13(7), 1327. https://doi.org/10.3390/v13071327