Identification of G-quadruplex DNA sequences in SARS-CoV2

Targeting Two-Tetrad RNA G-Quadruplex in the SARS-CoV-2 RNA Genome Using Tetraphenylethene Derivatives for Antiviral Therapy

Targeting the specific RNA conformations that are crucial for SARS-CoV-2 replication is a viable antiviral approach. The SARS-CoV-2 genome contains GG repeats capable of forming unstable two-tetrad G-quadruplex (GQ) structures, which exist as a mix of conformations, including hairpin (Hp), intra-, and intermolecular GQs. RGQ-1, originating from the nucleocapsid gene's ORF, adopts a dynamic equilibrium of conformations, including intramolecular hairpin and G-quadruplex (Hp-GQ) structures, as confirmed by CD analysis. In this study, tetraphenylethene (TPE) derivatives were developed to target the Hp-GQ conformational equilibrium of RGQ-1. EMSA, fluorescence spectroscopy, and ITC assays confirmed that two TPE derivatives, TPE-MePy and TPE-Allyl Py, bind to RGQ-1. CD thermal melting experiments indicate that RGQ-1 is stabilized by 8.56 and 12.54 °C in the presence of TPE-MePy and TPE-Allyl Py, respectively. Additionally, luciferase assays demonstrated that TPE derivatives suppressed luciferase activity by 2.2-fold and 3.6-fold, respectively, shifting the HpGQ equilibrium toward the GQ conformation, as suggested by CD spectroscopy. Treatment of SARS-CoV-2-infected A549 cells with TPE derivatives reduced the levels of viral RNA, spikes, and nucleocapsid proteins. To explore their antiviral mechanism, preinfection and postinfection treatments were tested, revealing that the TPE derivatives specifically suppressed the postentry stages of viral replication without affecting viral entry. These findings highlight the therapeutic potential of TPE derivatives in inhibiting key gene expressions critical for SARS-CoV-2 replication.

Therapeutic Challenges in COVID-19

SARS-CoV2 is a novel respiratory coronavirus and, understanding its molecular mechanism is a prerequisite to developing effective treatment for COVID-19. This RNA genome-carrying virus has a protein coat with spikes (S) that attaches to the ACE2 receptor at the cell surface of human cells. Several repurposed drugs are used to treat COVID-19 patients that are proven to be largely unsuccessful or have limited success in reducing mortalities. Several vaccines are in use to reduce the viral load to prevent developing symptoms. Major challenges to their efficacy include the inability of antibody molecules to enter cells but remain effective in the bloodstream to kill the virus. The efficacy of vaccines also depends on their neutralizing ability to constantly evolve new virus strains due to novel mutations and evolutionary survival dynamics. Taken together, SARS-CoV2 antibody vaccines may not be very effective and other approaches based on genetic, genomic, and protein interactome could be fruitful to identify therapeutic targets to reduce disease-related mortalities.

Can G-quadruplex become a promising target in HBV therapy?

The chronic infection with hepatitis B virus (HBV) is an important health problem that affects millions of people worldwide. Current therapies for HBV always suffer from a poor response rate, common side effects, and the need for lifelong treatment. Novel therapeutic targets are expected. Interestingly, non-canonical structures of nucleic acids play crucial roles in the regulation of gene expression. Especially the formation of G-quadruplexes (G4s) in G-rich strands has been demonstrated to affect many bioprocesses including replication, transcription, and translation, showing great potential as targets in anticancer and antiviral therapies. In this review, we summarize recent antiviral studies about G4s and discuss the potential roles of G4 structures in antiviral therapy for HBV.

Insights into the Small Molecule Targeting of Biologically Relevant G-Quadruplexes: An Overview of NMR and Crystal Structures

G-quadruplexes turned out to be important targets for the development of novel targeted anticancer/antiviral therapies. More than 3000 G-quadruplex small-molecule ligands have been described, with most of them exerting anticancer/antiviral activity by inducing telomeric damage and/or altering oncogene or viral gene expression in cancer cells and viruses, respectively. For some ligands, in-depth NMR and/or crystallographic studies were performed, providing detailed knowledge on their interactions with diverse G-quadruplex targets. Here, the PDB-deposited NMR and crystal structures of the complexes between telomeric, oncogenic or viral G-quadruplexes and small-molecule ligands, of both organic and metal-organic nature, have been summarized and described based on the G-quadruplex target, from telomeric DNA and RNA G-quadruplexes to DNA oncogenic G-quadruplexes, and finally to RNA viral G-quadruplexes. An overview of the structural details of these complexes is here provided to guide the design of novel ligands targeting more efficiently and selectively cancer- and virus-related G-quadruplex structures.