Binding of phosphorothioate oligonucleotides with RNase H1 can cause conformational changes in the protein and alter the interactions of RNase H1 with other proteins

Comparison of interaction between antimiR and microRNA versus HDO-antimiR and microRNA by molecular dynamics simulation

Recently, we found DNA/RNA heteroduplex oligonucleotide-based antimiR (HDO-antimiR) can more efficiently inhibit the target miRNA than conventional antimiR after its cellular uptake. But the mechanism of HDO-antimiR about the target-silencing is unknown. We here tried to elucidate the interaction mechanism of HDO-antimiR to miRNA using molecular dynamics (MD) simulation. When interaction of the conventional antimiR or HDO-antimiR and the target miRNA was simulated, they combined with each other in various forms. In the hydrogen bond analyses, base site of the antimiR formed hydrogen bond with miRNA. On the other hand, phosphate site of the HDO-antimiR formed hydrogen bond with miRNA. These results suggested that there were differences about the binding mechanisms between antimiR and HDO-antimiR to the target miRNA. In particular, there was a difference in the binding site between antimiR and HDO-antimiR. Additionally, it was found that guanine in the miRNA is mainly involved in the binding to the antimiR or HDO-antimiR. MD simulation method is useful in understanding the mechanism of oligonucleotide therapeutics.

The Combination of Mesyl-Phosphoramidate Inter-Nucleotide Linkages and 2'-O-Methyl in Selected Positions in the Antisense Oligonucleotide Enhances the Performance of RNaseH1 Active PS-ASOs

Antisense oligonucleotides (ASOs) that mediate RNA target degradation by RNase H1 are used as drugs to treat various diseases. Previously we found that introduction of a single 2'-O-methyl (2'-OMe) modification in position 2 of the central deoxynucleotide region of a gapmer phosphorothioate (PS) ASO, in which several residues at the termini are 2'-methoxyethyl, 2' constrained ethyl, or locked nucleic acid, dramatically reduced cytotoxicity with only modest effects on potency. More recently, we demonstrated that replacement of the PS linkage at position 2 or 3 in the gap with a mesyl-phosphoramidate (MsPA) linkage also significantly reduced toxicity without meaningful loss of potency and increased the elimination half-life of the ASOs. In this study, we evaluated the effects of the combination of MsPA linkages and 2'-OMe nucleotides on PS ASO performance. We found that two MsPA modifications at the 5' end of the gap or in the 3'-wing of a Gap 2'-OMe PS ASO substantially increased the activity of ASOs with OMe at position 2 of the gap without altering the safety profile. Such effects were observed with multiple sequences in cells and animals. Thus, the MsPA modification improves the RNase H1 cleavage rate of PS ASOs with a 2'-OMe in the gap, significantly reduces binding of proteins involved in cytotoxicity, and prolongs elimination half-lives.

NAT10 and DDX21 Proteins Interact with RNase H1 and Affect the Performance of Phosphorothioate Oligonucleotides

RNase H1-dependent phosphorothioate oligonucleotides (PS-ASOs) have been developed to treat various diseases through specific degradation of target RNAs. Although many factors or features of RNA and PS-ASOs have been demonstrated to affect antisense activity of PS-ASOs, little is known regarding the roles of RNase H1-associated proteins in PS-ASO performance. In this study, we report that two nucleolar proteins, NAT10 and DDX21, interact with RNase H1 and affect the potency and safety of PS-ASOs. The interactions of these two proteins with RNase H1 were determined using BioID proximity labeling in cells and confirmed biochemically. Reduction of NAT10 and DDX21 decreased PS-ASO activity in cells, and purified NAT10 and DDX21 proteins enhanced RNase H1 cleavage rates, indicating that these two proteins facilitate RNase H1 endoribonuclease activity. Consistently, reduction of these proteins increased the levels of R-loops, and impaired pre-rRNA processing. In addition, reduction of the two proteins increased the cytotoxicity of toxic PS-ASOs, and treatment of toxic PS-ASOs also altered the localization of these proteins. Together, this study shows for the first time that NAT10 and DDX21 interact with RNase H1 protein and enhance its enzymatic activity, contributing to the potency and safety of PS-ASOs.

Identification of nucleobase chemical modifications that reduce the hepatotoxicity of gapmer antisense oligonucleotides

Currently, gapmer antisense oligonucleotide (ASO) therapeutics are under clinical development for the treatment of various diseases, including previously intractable human disorders; however, they have the potential to induce hepatotoxicity. Although several groups have reported the reduced hepatotoxicity of gapmer ASOs following chemical modifications of sugar residues or internucleotide linkages, only few studies have described nucleobase modifications to reduce hepatotoxicity. In this study, we introduced single or multiple combinations of 17 nucleobase derivatives, including four novel derivatives, into hepatotoxic locked nucleic acid gapmer ASOs and examined their effects on hepatotoxicity. The results demonstrated successful identification of chemical modifications that strongly reduced the hepatotoxicity of gapmer ASOs. This approach expands the ability to design gapmer ASOs with optimal therapeutic profiles.

Synthesis of 4'-C-(aminoethyl)thymidine and 4'-C-[(N-methyl)aminoethyl]thymidine by a new synthetic route and evaluation of the properties of the DNAs containing the nucleoside analogs

A gapmer-type antisense oligonucleotide is an oligonucleotide therapeutic that targets pathogenic mRNA directly, and it is expected to be a next-generation therapeutic drug. In this study, we designed and synthesized 4'-C-[(N-methyl)aminoethyl]-thymidine (4'-MAE-T) as a novel nucleoside analog and compared its properties with those of 4'-C-aminoethyl-thymidine (4'-AE-T). Furthermore, we designed a new synthetic route for 4'-C-aminoethyl-modified nucleosides and accomplished the synthesis of 4'-AE-T via a novel pathway with high total yield. DNA containing 4'-MAE-T analogs decreased RNA affinity slightly more than unmodified DNA and DNA containing 4'-AE-T, but significantly improved nuclease resistance compared to unmodified DNA in a solution containing bovine serum. In addition, the impact of 4'-MAE-T on DNA stability was higher than that of 4'-AE-T. Also, DNA containing these analogs can activate Escherichia coli-derived RNase H. Thus, 4'-MAE-T has the potential to be used in gapmer-type antisense nucleic acids as a suitable candidate for the development of therapeutic antisense oligonucleotides.

Structural basis of dimerization and nucleic acid binding of human DBHS proteins NONO and PSPC1

The Drosophila behaviour/human splicing (DBHS) proteins are a family of RNA/DNA binding cofactors liable for a range of cellular processes. DBHS proteins include the non-POU domain-containing octamer-binding protein (NONO) and paraspeckle protein component 1 (PSPC1), proteins capable of forming combinatorial dimers. Here, we describe the crystal structures of the human NONO and PSPC1 homodimers, representing uncharacterized DBHS dimerization states. The structures reveal a set of conserved contacts and structural plasticity within the dimerization interface that provide a rationale for dimer selectivity between DBHS paralogues. In addition, solution X-ray scattering and accompanying biochemical experiments describe a mechanism of cooperative RNA recognition by the NONO homodimer. Nucleic acid binding is reliant on RRM1, and appears to be affected by the orientation of RRM1, influenced by a newly identified 'β-clasp' structure. Our structures shed light on the molecular determinants for DBHS homo- and heterodimerization and provide a basis for understanding how DBHS proteins cooperatively recognize a broad spectrum of RNA targets.

Addressing the Needs of Patients with Ultra-Rare Mutations One Patient at a Time: The n-Lorem Approach

Thanks to the advent of genomic sequencing and numerous personalized medicine initiatives in various medical centers, it is now known that there are many patients who have heretofore never been diagnosed who have mutations that are unique to them and them only and others that may be members of an extremely rare mutation (<30 patients in the world). Although each mutation may be unique it is now estimated that there are millions of these unique or vanishingly small patient groups. Patients with diseases caused by ultra-rare mutations present challenges to the health care system that are as unique as their mutation. n-Lorem was founded to take advantage of the antisense technology that we created at Ionis to discover and develop personalized antisense oligonucleotides (ASOs) one patient at a time and provide those experimental ASO treatments for free for life. In our first 18 months of operation, we have demonstrated this goal is achievable and worked with the FDA to develop guidance for ASO treatment of patients with ultra-rare diseases. In this article, I define the problem, discuss the ASO solution, and our progress at n-Lorem to date. I then focus on important steps that we have taken to assure that these complex risk/benefit judgments are made with high quality and that each patient receives the highest quality ASO possible. I then describe the processes we have created to assure that the opportunity to learn from each patient and our aggregate experience are maximized and shared with all stakeholders.

Nanoparticles-Based Oligonucleotides Delivery in Cancer: Role of Zebrafish as Animal Model

Oligonucleotide (ON) therapeutics are molecular target agents composed of chemically synthesized DNA or RNA molecules capable of inhibiting gene expression or protein function. How ON therapeutics can efficiently reach the inside of target cells remains a problem still to be solved in the majority of potential clinical applications. The chemical structure of ON compounds could affect their capability to pass through the plasma membrane. Other key factors are nuclease degradation in the extracellular space, renal clearance, reticulo-endothelial system, and at the target cell level, the endolysosomal system and the possible export via exocytosis. Several delivery platforms have been proposed to overcome these limits including the use of lipidic, polymeric, and inorganic nanoparticles, or hybrids between them. The possibility of evaluating the efficacy of the proposed therapeutic strategies in useful in vivo models is still a pivotal need, and the employment of zebrafish (ZF) models could expand the range of possibilities. In this review, we briefly describe the main ON therapeutics proposed for anticancer treatment, and the different strategies employed for their delivery to cancer cells. The principal features of ZF models and the pros and cons of their employment in the development of ON-based therapeutic strategies are also discussed.