kazuyuki kumagai

Antisense oligonucleotides (ASOs) are nucleic acid therapeutics that regulate gene expression through sequence-specific hybridization with target RNA. Under physiological conditions, many target RNAs adopt higher-order structures, which can strongly influence ASO accessibility and binding behavior. Although UV melting analysis is widely used to evaluate the thermal stability of ASO/RNA duplexes, this approach does not adequately account for the structural features of target RNAs. In this study, we investigated the utility of surface plasmon resonance (SPR) analysis as an in vitro method to evaluate ASO binding while considering RNA structural constraints. Multiple ASOs were designed to target PRF84, an 84-nucleotide RNA motif that induces −1 programmed ribosomal frameshifting in HIV-1 gag-pol expression. SPR analyses were performed to compare ASO interactions with complementary RNA fragments and with structurally folded PRF84. The results demonstrated that identical ASOs exhibited distinct binding behaviors depending on whether the target was a complementary RNA or PRF84, indicating that RNA structure significantly affects ASO binding. These findings suggest that SPR analysis enables the evaluation of ASO–RNA interactions taking structure into account, and may be a useful alternative approach to conventional UV melting analysis-based ASO screening.

Abstract Eukaryotic translation initiation factor 3 (eIF3) is a multi-subunit complex that promotes ribosome recruitment and messenger RNA (mRNA) selection. Here, we show that its eIF3g subunit, along with the binding partner eIF3i, mediates transcript-specific translation under mild heat stress through direct RNA binding. First, SELEX experiments identified a short GUCG-centered motif preferentially recognized by eIF3g, suggesting a sequence-specific binding preference. Next, ribosome profiling of yeast eIF3i mutant revealed that mRNAs containing GUCG motifs in their 5′ coding regions exhibit elevated ribosome occupancy in a manner dependent on eIF3g/eIF3i module. A subset of SELEX-identified motifs, collectively termed the GUCG box, was found enriched in the 5′-terminal coding region of the regulated mRNAs. Reporter assays confirmed that these 5′-terminal coding regions are sufficient to drive heat-induced translation. Mutational analyses and biolayer interferometry demonstrated that disruption of the GUCG motif impairs eIF3g binding and diminishes translational induction. Moreover, GUCG motifs are periodically distributed across coding sequences and enriched near start codons, consistent with their role in stabilizing initiating ribosomes. Overall, this study establishes the GUCG box as a bona fide eIF3g-binding motif and validates its functional importance in vivo. These findings provide new insight into how eIF3 mediates stress-adaptive translation through sequence-specific RNA recognition.

The viral infectivity factor (Vif) of human immunodeficiency virus 1 forms a complex with host proteins, designated as Vif-CBFβ-ELOB-ELOC-CUL5 (VβBCC), initiating the ubiquitination and subsequent proteasomal degradation of the human antiviral protein APOBEC3G (A3G), thereby negating its antiviral function. Whilst recent cryo-electron microscopy (cryo-EM) studies have implicated RNA molecules in the Vif-A3G interaction that leads to A3G ubiquitination, our findings indicated that the VβBCC complex can also directly impede A3G-mediated DNA deamination, bypassing the proteasomal degradation pathway. Employing the Systematic Evolution of Ligands by EXponential enrichment (SELEX) method, we have identified RNA aptamers with high affinity for the VβBCC complex. These aptamers not only bind to the VβBCC complex but also reinstate A3G’s DNA deamination activity by inhibiting the complex’s function. Moreover, we delineated the sequences and secondary structures of these aptamers, providing insights into the mechanistic aspects of A3G inhibition by the VβBCC complex. Analysis using selected aptamers will enhance our understanding of the inhibition of A3G by the VβBCC complex, offering potential avenues for therapeutic intervention.

RNA aptamers are nucleic acids that are obtained using the systematic evolution of ligands by exponential enrichment (SELEX) method. When using conventional selection methods to immobilize target proteins on matrix beads using protein tags, sequences are obtained that bind not only to the target proteins but also to the protein tags and matrix beads. In this study, we performed SELEX using β-1,3-glucan recognition protein (GRP)-tags and curdlan beads to immobilize the acute myeloid leukaemia 1 (AML1) Runt domain (RD) and analysed the enrichment of aptamers using high-throughput sequencing. Comparison of aptamer enrichment using the GRP-tag and His-tag suggested that aptamers were enriched using the GRP-tag as well as using the His-tag. Furthermore, surface plasmon resonance analysis revealed that the aptamer did not bind to the GRP-tag and that the conjugation of the GRP-tag to RD weakened the interaction between the aptamer and RD. The GRP-tag could have acted as a competitor to reduce weakly bound RNAs. Therefore, the affinity system of the GRP-tagged proteins and curdlan beads is suitable for obtaining specific aptamers using SELEX.