Locked Nucleic Acid Research Articles

6589 Antisense Oligonucleotides for Reducing ACTH Secretion in a Model of Cushing's Disease

Abstract Disclosure: M.S. Varughese: None. H. Eltumi: None. E.H. Kemp: None. J.D. Newell-Price: None. Antisense Oligonucleotides for Reducing ACTH Secretion in a Model of Cushing’s Disease Background: Cushing’s disease (CD) is a multi-system disorder with high morbidity and mortality characterised by pathologically raised serum cortisol due excess expression of proopiomelanocortin (Pomc) and overproduction of ACTH by a pituitary corticotroph adenoma. Trans-sphenoidal adenomectomy is the treatment of choice, but there is a 30% recurrence rate over time. Advances in medical therapy are needed. Antisense oligonucleotides (ASOs) can silence mRNA translation by specific base-pairing. Locked nucleic acid (LNA) and 2’-O-methyl (OMe) ribose terminals make ASOs more effective by improving affinity and resistance to nuclease degradation. Aims: To investigate the effectiveness of LNA- and OMe-modified anti-Pomc ASOs at reducing ACTH secretion from murine adrenotropic tumour (AtT20) cells. To analyse the nuclease resistance of Pomc ASOs and their ability to drive an immune response. Methods: Two ASOs (ASO2 and ASO3) were designed against Pomc with phosphorothioate backbones modified with either LNA or OMe ribose terminals. These were used in lipofectamine-mediated cell transfections of AtT20 cells and ACTH in the culture medium measured by immunoassay. ASO stability was assessed by nuclease degradation assays and immunogenicity by cytokine ELISAs. Results: When compared with untreated AtT20 cells, LNA- and OMe-modified Pomc ASOs at 1 nM significantly suppressed ACTH secretion for up to 120 h and 96 h, respectively (n = 4; Unpaired t tests, all P values < 0.05). In contrast, control treatments, including scrambled and mismatched ASOs, did not cause a significant reduction. For comparison, 1 nM of ASO2-OMe, ASO2-LNA, ASO3-OMe and ASO3-LNA lowered ACTH at 24 h by 62%, 71%, 63% and 79%, respectively. Modified Pomc ASOs showed 14-31% degradation over a 120-min incubation period with 3’- and 5’-exonucleases, whilst equivalent unmodified Pomc ASOs were completely degraded. No secretion of IFN-α, IFN-β, TNF-α, IL-6 or IL-1β was detected following transfection of AtT20 cells with Pomc ASOs. Conclusions:Pomc ASOs caused significant reduction of ACTH secretion from AtT-20 cells. LNA-modified Pomc ASOs were more effective than those with OMe modifications, with neither stimulating a detectable immune response. These ASOs hold promise as a systemic therapy for Cushing’s disease. Presentation: 6/3/2024

Biosensor development for diabetes diagnosis: Determining relevant miRNA using a newly developed N-annulated perylene fluorescent dye

MicroRNAs (miRNAs) have emerged as essential biomarkers for disease diagnosis, and several techniques are available to determine type 2 diabetes (T2D) relevant miRNAs. However, detecting circulating miRNAs can be challenging due to their small size, low abundance, and high sequence similarity, often requiring sensitive detection approaches combined with additional amplification processes. Laser-induced fluorescence (LIF) is a classic analytical method suitable for sensitively detecting trace amounts of nucleotide acid. Duplex-specific nuclease (DSN)-mediated amplification recently gained attention due to its catalytic activity based on target recycling, demonstrating a promising approach for miRNA amplification. This work developed a novel N-annulated perylene fluorescent dye to create a biosensor to analyze the miRNA (miR-223) relevant to T2D. The amine-reactive fluorescent dye assists the amidation reaction for nucleotide labeling, giving the oligonucleotide probe a high fluorescence quantum yield and sufficient water solubility. By combining the locked nucleic acid (LNA) modified oligonucleotide fluorescent probe to enhance the stability of LNA/RNA hybrids, thereby improving the DSN-mediated target miR-223 recycling for signal amplification, the proposed biosensor can highly selectively determine miR-223 with a limit of detection (LOD, S/N = 3) of 9.5 pM. When applied to real-world samples, the biosensor demonstrated its potential to distinguish between T2D patients and healthy controls.

BRCA1 levels and DNA-damage response are controlled by the competitive binding of circHIPK3 or FMRP to the BRCA1 mRNA.

Circular RNAs (circRNAs) are covalently closed RNA molecules widely expressed in eukaryotes and deregulated in several pathologies, including cancer. Many studies point to their activity as microRNAs (miRNAs) and protein sponges; however, we propose a function based on circRNA-mRNA interaction to regulate mRNA fate. We show that the widely tumor-associated circHIPK3 directly interacts invivo with the BRCA1 mRNA through the back-splicing region in human cancer cells. This interaction increases BRCA1 translation by competing for the binding of the fragile-X mental retardation 1 protein (FMRP) protein, which we identified as a BRCA1 translational repressor. CircHIPK3 depletion or disruption of the circRNA-mRNA interaction decreases BRCA1 protein levels and increases DNA damage, sensitizing several cancer cells to DNA-damage-inducing agents and rendering them susceptible to synthetic lethality. Additionally, blocking FMRP interaction with BRCA1 mRNA with locked nucleic acid (LNA) restores physiological protein levels in BRCA1 hemizygous breast cancer cells, underscoring the importance of this circRNA-mRNA interaction in regulating DNA-damage response.

A novel platform for mutation detection in colorectal cancer using a PNA-LNA molecular switch

Detection of KRAS mutation in colorectal cancer (CRC) is important in the prediction of response to target therapy. The study aims to develop a novel mutation detection platform called the “PNA-LNA molecular switch” for the detection of KRAS mutation in CRC. We employed the enhanced binding specificity of peptide nucleic acid (PNA) and locked nucleic acid (LNA) in conjunction with a loop-mediated isothermal amplification (LAMP) approach to identify the mutation status of KRAS oncogene codon 12 (c.35G>T/G12V and c.35G>A/G12D) using synthetic oligonucleotides and colon cancer cell lines (Caco-2 and SW480). This method specifically blocked the amplification of the wild-type sequences while substantially amplifying the mutated ones, which was visualized by both colorimetric and fluorescence assays. We then checked the mutation profile of KRAS codon 12 in the DNA derived from tumor tissue samples (number of samples, n = 30) and circulating tumor cells (n = 24) from CRC patients. Finally, we validated the results by comparing them with the data obtained from DNA sequencing of colon tumors (n = 21) of the same CRC patients. This method showed excellent sensitivity (1 DNA copy/μl), reproducibility [relative standard deviation (%RSD) < 5%, for n = 3], and linear dynamic range (1 ag/μl-10 pg/μl, R2 = 0.94). This platform is significantly faster, relatively cheaper, has superior sensitivity and specificity, and does not require any high-end equipment. To conclude, this method has the potential to be translated into clinical settings for the detection of mutations in diverse diseases and conditions.

Pervasive heteroplasmy in an invasive ambrosia beetle (Scolytinae) in southern California.

Heteroplasmy, the presence of multiple mitochondrial genotypes (mitotypes) within an individual, has long been thought to be a rare aberrance that is quickly removed by selection or drift. However, heteroplasmy is being reported in natural populations of eukaryotes with increasing frequency, in part due to improved diagnostic methods. Here, we report a seemingly stable heteroplasmic state in California populations of the polyphagous shothole borer (PSHB), Euwallacea fornicatus; an invasive ambrosia beetle that is causing significant tree dieback. We develop and validate a qPCR assay utilizing locked nucleic acid probes to detect different mitotypes, and qualitatively assess heteroplasmy in individual PSHB. We prove the utility of this assay by: (1) mitotyping field-collected PSHB, documenting the prevalence of heteroplasmy across its range in California; and, (2) measuring relative titers of each mitotype across multiple generations of heteroplasmic laboratory colonies to assess the stability of transmission through the maternal germline. We show that our findings are unlikely to be explained by the existence of NUMTs by next generation sequencing of contiguous sections of mitochondrial DNA, where each of the observed heteroplasmic sites are found within fully functional coding regions of mtDNA. Subsequently, we find heteroplasmic individuals are common in Californian field populations, and that heteroplasmy persists for at least 10 generations in experimental colonies. We also looked for evidence of the common occurrence of paternal leakage, but found none. In light of our results, we discuss competing hypotheses as to how heteroplasmy may have arisen, and continues to perpetuate, in Californian PSHB populations.

PEI/MMNs@LNA-542 nanoparticles alleviate ICU-acquired weakness through targeted autophagy inhibition and mitochondrial protection.

Intensive care unit-acquired weakness (ICU-AW) is prevalent in critical care, with limited treatment options. Certain microRNAs, like miR-542, are highly expressed in ICU-AW patients. This study investigates the regulatory role and mechanisms of miR-542 in ICU-AW and explores the clinical potential of miR-542 inhibitors. ICU-AW models were established in C57BL/6 mice through cecal ligation and puncture (CLP) and in mouse C2C12 myoblasts through TNF-α treatment. In vivo experiments demonstrated decreased muscle strength, muscle fiber atrophy, widened intercellular spaces, and increased miR-542-3p/5p expression in ICU-AW mice model. In vitro experiments indicated suppressed ATG5, ATG7 and LC3II/I, elevated MDA and ROS levels, decreased SOD levels, and reduced MMP in the model group. Similar to animal experiments, the expression of miR-542-3p/5p was upregulated. Gel electrophoresis explored the binding of polyethyleneimine/mesoporous silica nanoparticles (PEI/MMNs) to locked nucleic acid (LNA) miR-542 inhibitor (LNA-542). PEI/MMNs@LNA-542 with positive charge (3.03 ± 0.363 mV) and narrow size (206.94 ± 6.19 nm) were characterized. Immunofluorescence indicated significant internalization with no apparent cytotoxicity. Biological activity, examined through intraperitoneal injection, showed that PEI/MMNs@LNA-542 alleviated muscle strength decline, restored fiber damage, and recovered mitochondrial injury in mice. In conclusion, PEI/MMNs nanoparticles effectively delivered LNA-542, targeting ATG5 to inhibit autophagy and alleviate mitochondrial damage, thereby improving ICU-AW.

Unraveling DNA Triplex Assembly: Mass Spectrometric Investigation of Modified Triplex Forming Oligonucleotides for Enhanced Gene Targeting.

Deoxyribonucleic acid triplexes have potential roles in a range of biological processes involving gene and transcriptional regulation. A major challenge in exploiting the formation of these higher-order structures to target genes in vivo is their low stability, which is dependent on many factors including the length and composition of bases in the sequence. Here, different DNA base modifications have been explored, primarily using native mass spectrometry, in efforts to enable stronger binding between the triplex forming oligonucleotide (TFO) and duplex target sites. These modifications can also be used to overcome pyrimidine interruptions in the duplex sequence in promoter regions of genomes, to expand triplex target sequences for antigene therapies. Using model sequences with a single pyrimidine interruption, triplex forming oligonucleotides containing locked nucleic acid base modifications were shown to have a higher triplex binding propensity than DNA-only and dSpacer-containing TFOs. However, the triplex forming ability of these systems was limited by the competitive formation of multiple higher order assemblies. Triplex forming sequences that correspond to specific gene targets from the Pseudomonas aeruginosa genome were also investigated, with LNA-containing TFOs the only variant able to form triplex using these sequences. This work indicates the advantages of utilizing synthetically modified TFOs to form triplex assemblies in vivo for potential therapeutic applications and highlights the advantages of native mass spectrometry for the study of their formation.

MicroLOCK: Highly stable microgel biosensor using locked nucleic acids as bioreceptors for sensitive and selective detection of let-7a

Chemically modified oligonucleotides can solve biosensing issues for the development of capture probes, antisense, CRISPR/Cas, and siRNA, by enhancing their duplex-forming ability, their stability against enzymatic degradation, and their specificity for targets with high sequence similarity as microRNA families. However, the use of modified oligonucleotides such as locked nucleic acids (LNA) for biosensors is still limited by hurdles in design and from performances on the material interface. Here we developed a fluorogenic biosensor for non-coding RNAs, represented by polymeric PEG microgels conjugated with molecular beacons (MB) modified with locked nucleic acids (MicroLOCK). By 3D modeling and computational analysis, we designed molecular beacons (MB) inserting spot-on LNAs for high specificity among targets with high sequence similarity (95%). MicroLOCK can reversibly detect microRNA targets in a tiny amount of biological sample (2μL) at 25°C with a higher sensitivity (LOD 1.3fM) without any reverse transcription or amplification. MicroLOCK can hybridize the target with fast kinetic (about 30min), high duplex stability without interferences from the polymer interface, showing high signal-to-noise ratio (up to S/N=7.3). MicroLOCK also demonstrated excellent resistance to highly nuclease-rich environments, in real samples. These findings represent a great breakthrough for using the LNA in developing low-cost biosensing approaches and can be applied not only for nucleic acids and protein detection but also for real-time imaging and quantitative assessment of gene targeting both in vitro and in vivo.

Rapid and Cost‐Effective Platypus eDNA Detection in Waterways Using Loop‐Mediated Isothermal Amplification Assay: Advancing Conservation Efforts

ABSTRACTFreshwater ecosystems, home to a remarkable diversity of species, are facing severe threats from human activities such as climate change, habitat degradation, over‐extraction of water for irrigation, and pollution. The platypus, an iconic species in freshwater ecosystems around Australia, is threatened by all these activities, both singly and in combination. The scale and complexity of these intersecting and reinforcing threats makes cost‐effective monitoring tools essential to better understand how platypus populations are responding. In this study, we optimized a loop‐mediated isothermal amplification (LAMP) assay for the rapid and cost‐effective detection of platypus DNA in environmental water samples, offering an attractive alternative to quantitative polymerase chain reaction (qPCR). We improved a water filtration protocol for in‐field use, employing suitable filter membranes for processing large volumes of water, thereby maximizing DNA recovery from dilute samples. The limit of detection for the platypus LAMP (Plat‐LAMP) assay was determined to be 12.4 copies/μL using a standard plasmid positive reference and 7 × 10−6 ng/μL when applied to DNA extracted from platypus tissue, with improved sensitivity achieved through the incorporation of locked nucleic acid primers. In comparative testing against qPCR, the Plat‐LAMP assay exhibited greater sensitivity in detecting platypus DNA in known positive water samples collected from platypus habitat at Healesville Sanctuary. Furthermore, the Plat‐LAMP assay demonstrated 100% specificity when performed on water samples collected from non‐platypus habitats. In field testing across waterways in Victoria and New South Wales, the Plat‐LAMP assay detected platypus in 36.96% of samples, compared to 54.35% of samples using qPCR. These findings underscore the Plat‐LAMP assay's potential as a faster and more cost‐effective complementary method to qPCR, rendering it suitable for point‐of‐application water testing. The ability to conduct eDNA surveys without the need for cold‐chain logistics would significantly assist conservation organizations and water managers map platypus distributions and facilitate conservation efforts around Australia.

Wild-type Blocking PCR Combined with Sanger Sequencing for Detection of Low-frequency Somatic Mutation.

When monitoring minimal residual disease (MRD) after tumor treatment, there are higher requirements of the lower limit of detection than when detecting for drug resistance mutations and circulating tumor cell mutations during therapy. Traditional Sanger sequencing has 5%-20% wild-type mutation detection, so its limit of detection cannot meet the corresponding requirements. The wild-type blocking technologies that have been reported to overcome this include blocker displacement amplification (BDA), non-extendable locked nucleic acid (LNA), hot-spot-specific probes (HSSP), etc. These technologies use specific oligonucleotide sequences to block wild-type or recognize wild-type and then combine this with other methods to prevent wild-type amplification and amplify mutant amplification, leading to characteristics like high sensitivity, flexibility, and convenience. This protocol uses BDA, a wild-type blocking PCR combined with Sanger sequencing, to optimize the detection of RHOA G17V low-frequency somatic mutations, and the detection sensitivity can reach 0.5%, which can provide a basis for MRD monitoring of angioimmunoblastic T-cell lymphoma.

Accessing Therapeutically-Relevant Multifunctional Antisense Oligonucleotide Conjugates Using Native Chemical Ligation.

Antisense oligonucleotide (ASO) therapies hold significant promise in the realm of molecular medicine. By precisely targeting RNA molecules, ASOs offer an approach to modulate gene expression and protein production, making them valuable tools for treating a wide range of genetic and acquired diseases. As the precise intracellular targeting and delivery of ASOs is challenging, strategies for preparing ASO-ligand conjugates are in exceedingly high demand. This work leverages the utility of native chemical ligation to conjugate ASOs with therapeutically relevant chemical modifications including locked nucleic acids and phosphorothioate backbone modifications to peptides and sugars via a stable amide linkage. A suite of post-ligation functionalizations through modification of the cysteine ligation handle are highlighted, including chemoselective radical desulfurization, lipidation, and alkylation with a range of valuable handles (e.g. alkyne, biotin, and radionuclide chelating ligands), affording multifunctional constructs for further applications in biology and medicine. Application of the methodology to a clinically-relevant triantennary-GalNAc ASO conjugate and validation of its binding and functional activity underpins the applicability of the technique to oligonucleotide-based therapeutics.

Towards combining backbone and sugar constraint in 3'-3' bis-phosphonate tethered 2'-4' bridged LNA oligonucleotide trimers.

Therapeutic oligonucleotides are chemically modified to enhance their drug-like properties - including binding affinity for target RNA. Many nucleic acid analogs that enhance RNA binding affinity constrain the furanose sugar in an RNA-like sugar pucker. The improvements in binding affinity result primarily from increased off-rates with minimal effects on on-rates for hybridization. To identify alternate chemical modification strategies that can modulate on- and off-rates for oligonucleotide hybridization, we hypothesized that extending conformational restraint across multiple nucleotides could modulate hybridization kinetics by restricting rotational freedom of the sugar-phosphate backbone. As part of that effort, we recently reported that using hydrocarbon tethers to bridge adjacent phosphodiester linkages as phosphonate tethered bridges can pre-organize nucleic acids in conformations conducive for Watson-Crick base-pairing and modulate hybridization kinetics. In this report, we describe the synthesis of locked nucleic acid (LNA) trimers linked through alkylphosphonate tethers which restrict conformation of the furanose sugar in addition to restricting conformational mobility of the sugar-phosphate backbone across three nucleotide units.

Levels of Exon-Skipping Are Not Artificially Overestimated Because of the Increased Affinity of Tricyclo-DNA-Modified Antisense Oligonucleotides to the Target DMD Exon.

Antisense oligonucleotides (ASO) are very promising drugs for numerous diseases including neuromuscular disorders such as Duchenne muscular dystrophy (DMD). Several ASO drugs have already been approved by the US Food and Drug Administration for DMD and global efforts are still ongoing to improve further their potency, notably by developing new delivery systems or alternative chemistries. In this context, a recent study investigated the potential of different chemically modified ASO to induce exon-skipping in mouse models of DMD. Importantly, the authors reported a strong discrepancy between exon-skipping and protein restoration levels, which was mainly owing to the high affinity of locked nucleic acid (LNA) modifications to the target RNA, thereby interfering with the amplification of the unskipped product and resulting in artificial overamplification of the exon-skipped product. These findings urged us to verify whether a similar phenomenon could occur with tricyclo-DNA (tcDNA)-ASO that also display high-affinity properties to the target RNA. We thus ran a series of control experiments and demonstrate here that exon-skipping levels are not overestimated owing to an interference of tcDNA-ASO with the unskipped product in contrast to what was observed with LNA-containing ASO.

Characterization of the TLR9-Activating Potential of LNA-Modified Antisense Oligonucleotides.

Early characterization of the immunostimulatory potential of therapeutic antisense oligonucleotides (ASOs) is crucial. At present, little is known about the toll-like receptor 9 (TLR9)-mediated immunostimulatory potential of third-generation locked nucleic acid (LNA)-modified ASOs. In this study, we have systematically investigated the TLR9-activating potential of LNA-modified oligonucleotides using different mouse and human cell culture systems. Although it has been reported that LNA modifications as well as cytosine methylation of 5'-cytosine-phosphate-guanine-3' (CpG) motifs can reduce TLR9 stimulation by phosphorothioate (PTO)-modified oligonucleotides, we identified CpG-containing LNA gapmers with substantial TLR9-stimulatory activity. We further identified immunostimulatory LNA gapmers without CpG motifs. Unexpectedly, methylation of cytosines only within the CpG motif did not necessarily reduce but could even increase TLR9 activation. In contrast, systematic methylation of all cytosines reduced or even abrogated TLR9 activation in most cases. Context dependently, the introduction of LNA-modifications into the flanks could either increase or decrease TLR9 stimulation. Overall, our results indicate that TLR9-dependent immunostimulatory potential is an individual feature of an oligonucleotide and needs to be investigated on a case-by-case basis.

CDC's Laboratory Activities to Support Newborn Screening for Spinal Muscular Atrophy.

Spinal muscular atrophy (SMA) was added to the HHS Secretary's Recommended Uniform Screening Panel for newborn screening (NBS) in 2018, enabling early diagnosis and treatment of impacted infants to prevent irreversible motor neuron damage. In anticipation of supporting SMA newborn screening, scientists at the U.S. Centers for Disease Control and Prevention (CDC) have worked towards building resources for public health laboratories in four phases since 2013. In Phase 1, CDC established a real-time PCR assay, which uses a locked nucleic acid probe to attain the needed specificity, to detect SMN1 exon 7. In Phase 2, we developed quality assurance dried blood spot materials made with transduced lymphoblast cell lines established from de-identified SMA patients, carriers, and unaffected donors. In 2021, CDC implemented Phase 3, a proficiency testing program, that now supports 115 NBS labs around the world. We are currently completing Phase 4, which includes the implementation of an external SMA quality control material program. Also, during this time, CDC has provided individual technical assistance to NBS programs and bench training to NBS scientists during our annual molecular workshop. These CDC-led activities have contributed to the rapid and full implementation of SMA screening in all 50 U.S. states as of February 2024.

Unraveling the noncoding RNA landscape in glioblastoma: from pathogenesis to precision therapeutics.

Glioblastoma (GBM) is an aggressive type IV brain tumor that originates from astrocytes and has a poor prognosis. Despite intensive research, survival rates have not significantly improved. Noncoding RNAs (ncRNAs) are emerging as critical regulators of carcinogenesis, progression, and increased treatment resistance in GBM cells. They influence angiogenesis, migration, epithelial-to-mesenchymal transition, and invasion in GBM cells. ncRNAs, such as long ncRNAs (lncRNAs), microRNAs (miRNAs), and circular RNAs (circRNAs), are commonly dysregulated in GBM. miRNAs, such as miR-21, miR-133a, and miR-27a-3p, are oncogenes that increase cell proliferation, metastasis, and migration by targeting TGFBR1 and BTG2. In contrast, lncRNAs, such as HOXD-AS2 and LINC00511, are oncogenes that increase the migration, invasion, and proliferation of cells. CircRNAs, such as circ0001730, circENTPD7, and circFOXO3, are oncogenes responsible for cell growth, angiogenesis, and viability. Developing novel therapeutic strategies targeting ncRNAs, cell migration, and angiogenesis is a promising approach for GBM. By targeting these dysregulated ncRNAs, we can potentially restore a healthy balance in gene expression and influence disease progression. ncRNAs abound within GBM, demonstrating significant roles in governing the growth and behavior of these tumors. They may also be useful as biomarkers or targets for therapy. The use of morpholino oligonucleotides (MOs) suppressing the oncogene expression of HOTAIR, BCYRN1, and cyrano, antisense oligonucleotides (ASOs) suppressing the expression of ncRNAs such as MALAT1 and miR-10b, locked nucleic acids (LNAs) suppressing miR-21, and peptide nucleic acids (PNAs) suppressing the expression of miR-155 inhibited the PI3K pathway, tumor growth, angiogenesis, proliferation, migration, and invasion. Targeting oncogenic ncRNAs with RNA-interfering strategies such as MOs, ASOs, LNAs, CRISPR-Cas9 gene editing, and PNA approaches may represent a promising therapeutic strategy for GBM. This review emphasizes the critical role of ncRNAs in GBM pathogenesis, as well as the potential for new therapeutic strategies targeting these pathways to improve the prognosis and quality of life for GBM patients.

The West Nile virus genome harbors essential riboregulatory elements with conserved and host-specific functional roles

West Nile virus (WNV) is an arthropod-borne, positive-sense RNA virus that poses an increasing global threat due to warming climates and lack of effective therapeutics. Like other enzootic viruses, little is known about how host context affects the structure of the full-length RNA genome. Here, we report a complete secondary structure of the entire WNV genome within infected mammalian and arthropod cell lines. Our analysis affords structural insights into multiple, conserved aspects of flaviviral biology. We show that the WNV genome folds with minimal host dependence, and we prioritize well-folded regions for functional validation using structural homology between hosts as a guide. Using structure-disrupting, antisense locked nucleic acids, we then demonstrate that the WNV genome contains riboregulatory structures with conserved and host-specific functional roles. These results reveal promising RNA drug targets within flaviviral genomes, and they highlight the therapeutic potential of ASO-LNAs as both WNV-specific and pan-flaviviral therapeutic agents.

Novel synthesis and evaluation of oligonucleotides containing (S)-5′-C-aminopropyl-modified thymidine analogs for RNase H-dependent antisense therapy

Various chemical modifications have been investigated to improve the therapeutic properties of antisense oligonucleotides. In this study, we synthesized and evaluated two novel thymidine analogs: (S)-5′-C-aminopropyl-2′-O-aminoethyl thymidine and (S)-5′-C-aminopropyl-2′-O-methoxyethyl thymidine. Although both of these novel analogs exhibited robust resistance to nuclease degradation, the (S)-5′-C-aminopropyl-2′-O-methoxyethyl modification demonstrated superior thermal stability when applied to a TC-repeat model sequence. Conversely, the (S)-5′-C-aminopropyl-2′-O-aminoethyl modification was found to influence the secondary structure of DNA/RNA duplexes, resulting in thermal destabilization. Furthermore, a series of (S)-5′-C-aminopropyl-2′-O-methoxyethyl-modified KRAS-targeting locked nucleic acid (LNA) gapmers, termed KR-A gapmers, were prepared and subjected to in vitro testing. The results indicated that the (S)-5′-C-aminopropyl-2′-O-methoxyethyl modification could serve as a viable alternative to LNA, maintaining sufficient antisense activity.

LINC01432 binds to CELF2 in newly diagnosed multiple myeloma promoting short progression-free survival to standard therapy.

Multiple Myeloma (MM) is a highly prevalent and incurable form of cancer that arises from malignant plasma cells, with over 35,000 new cases diagnosed annually in the United States. While there are a growing number of approved therapies, MM remains incurable and nearly all patients will relapse and exhaust all available treatment options. Mechanisms for disease progression are unclear and in particular, little is known regarding the role of long non-coding RNAs (lncRNA) in mediating disease progression and response to treatment. In this study, we used transcriptome sequencing to compare newly diagnosed MM patients who had short progression-free survival (PFS) to standard first-line treatment (PFS < 24 months) to patients who had prolonged PFS (PFS > 24 months). We identified 157 differentially upregulated lncRNAs with short PFS and focused our efforts on characterizing the most upregulated lncRNA, LINC01432. We investigated LINC01432 overexpression and CRISPR/Cas9 knockdown in MM cell lines to show that LINC01432 overexpression significantly increases cell viability and reduces apoptosis, while knockdown significantly reduces viability and increases apoptosis, supporting the clinical relevance of this lncRNA. Next, we used individual-nucleotide resolution cross-linking immunoprecipitation with RT-qPCR to show that LINC01432 directly interacts with the RNA binding protein, CELF2. Lastly, we showed that LINC01432-targeted locked nucleic acid antisense oligonucleotides reduce viability and increases apoptosis. In summary, this fundamental study identified lncRNAs associated with short PFS to standard NDMM treatment and further characterized LINC01432, which inhibits apoptosis.

Antisense oligonucleotides and their technical suitability to nebulization

In vivo studies investigating the inhalative efficacy of biotherapeutics, such as nucleic acids, usually do not perform an aerosolization step, rather the solution is directly administered into the lungs e.g. intratracheally. In addition, there is currently very little information on the behavior of nucleic acid solutions when subjected to the physical stress of the nebulization process.In this study, the aim was to assess the technical suitability of Locked Nucleic Acids (LNAs), as a model antisense oligonucleotide, towards nebulization using two commercially available nebulizers. A jet nebulizer (Pari LC Plus) and a vibrating mesh nebulizer (Aerogen Solo) were employed and solutions of five different LNAs investigated in terms of their physical and chemical stability to nebulization and the quality of the generated aerosols. The aerosol properties of the Aerogen Solo were mainly influenced by the viscosity of the solutions with the output rate and the droplet size decreasing with increasing viscosity. The Pari LC Plus was less susceptible to viscosity and overall the droplet size was smaller. The LNAs tolerated both nebulization processes and the integrity of the molecules was shown. Chemical stability of the molecules from the Aerogen Solo was confirmed, whereas aerosol generation with the Pari LC Plus jet nebulizer led to a slight increase of phosphodiester groups in a fully phosphorothiolated backbone of the LNAs. Overall, it could be shown that nebulization of different LNAs is possible and inhalation can therefore be considered a potential route of administration.