Antisense Oligonucleotides

Phosphorothioate. This modification was among the few that is considered first-generation. PS-ASOs are nuclease resistant and, therefore, have longer plasma half lives compared to all-native DNA ASOs. In addition, they retain negative backbone charges, which facilitates PS-ASO entry into the cell. Interestingly, PS appears to have a bigger impact on transport and entry into the cell than it does on nuclease resistance.

However, PS-ASOs are not completely protected from nucleases, have reduced hybridization to target mRNAs (see the Binding Affinity section), and must be continually administered in large quantities to maintain modulation. In addition, PS can interact with proteins in vivo and therefore lead to negative side effects, including immune system activity.

Methyl RNA. This modification was among the few that are considered second-generation. When combined with PS in ASOs, 2'-OMe-RNA has been found to improve upon the benefits of PS alone (i.e. increased nuclease resistance, plasma half life, and tissue uptake).

Immunostimulation

Bacterial DNA contains a much higher frequency of CpG (cytosine-phosphodiester bond-guanine) dinucleotides lacking methylation than does vertebrate DNA. This is primarily because CpG dinucleotides are underrepresented in the vertebrate genome and 80% of them are labeled with methyl groups. Since the CpG motif in bacteria triggers activation of B cells, NK cells, monocytes, and cytokines whereas the vertebrate CpG motif does not, this is likely at least one of the ways that the immune system recognizes a bacterial infection. ASOs containing unmethylated CpG (CpsG: cytosine-phosphorothioate bond-guanine is even more potent) motifs stimulate the immune system in a manner similar to that of bacterial DNA and may have been responsible for some reported effects from early antisense studies.

To avoid immunostimulation, design ASOs lacking CpG / CpsG motifs, if possible, or least those lacking the following extended motif, which produces the strongest immune response:

• purine-purine-CpG-pyrimidine-pyridmidine

Given that this may be difficult to avoid due to the complementary nature of the target site selection sequence, the next best step is to replace the cytosine in CpG / CpsG with 5’-methylcytosine (Table 2), which has been shown to decrease immunostimulation significantly.

Sequence Length

Optimum lengths are usually from 12 to 28 bases. Sequences shorter than 12 bases increase the probability of off-target hybridization, while sequences longer than 25 bases increase the chance of reduced cellular uptake.

Self Complementarity

The ASO should be checked for secondary structure and oligonucleotide dimer formation as either one might interfere with hybridization to the target site sequence. If possible, design the ASO to have the weakest secondary structure possible as well as no dimer formation. Our oligonucleotide sequence calculator OligoEvaluator™ allows for quick determination of these self-forming structures.

G-Quartet Structures

ASOs containing stretches of two or more C or G nucleotides are able to form unusual structures, which may produce undesirable, off-target effects. The most common and studied are stretches of G bases, which can lead to the formation of G-quartets. These quartets have been shown to bind to proteins, including transcription factors, which may mimic and therefore interfere with antisense activity.

To avoid formation of these quartets, design ASOs lacking these polyG stretches, if possible. Again, given that this may not be feasible, the next best step is to replace the guanine with 7-deaza-dG (Table 3), which will block quartet formation.

Functional Motifs

A statistical analysis of PS-ASO experiments found that the following motifs:

• CCAC
• TCCC
• ACTC
• GCCA
• CTCT

correlate with enhanced antisense efficiency, whereas these motifs:

• GGGG
• ACTG
• AAA
• TAA

diminish antisense activity. It has been found that RNase H activity is sequence independent; Therefore, it is believed that the enhancing motifs lead to increased thermodynamic stability of the mRNA:ASO heteroduplex through the preponderance of GC Watson-Crick base pairing.

Binding Affinity

As already discussed, it is critically important to identify a site within the target mRNA that is free of folds as well as to ensure that the ASO also has no deleterious self complementarity. However, these considerations alone are not enough to ensure proper hybridization. Various factors, such as PS can reduce ASO binding affinity for the target site, which in turn minimizes antisense effectiveness.

Third-generation ASO modifications have been found not only to be nuclease resistant but also to improve binding affinity. Locked Nucleic Acid^® (Table 4), with its constrained ring structure, is particularly useful for improving ASO binding affinity and effectiveness (melting temperature change per monomer addition varies from +3 to +11 °C compared to native DNA only).

The Construct

To give insight into ASO sequences, examples of several antisense drugs (often the primary purpose of pursuing antisense research) that have been approved or are in clinical trials are provided here. These drugs are examples of (or are expected to be in the case of those in clinical trials) all of the desired outcomes when it comes to antisense: good design, an available delivery mechanism, and effective modulation. The same outcomes are critical to the success of research experiments (our ASOs are for in vitro and in vivo animal RUO [Research Use Only]).

First generation. In 1998, Fomivirsen (brand name Vitravene) was the first approved antisense drug. It was used to treat cytomegalovirus retinitis (CMV) in immunocompromised patients, including those with AIDS. The drug was delivered by intravitreal injection. The 21mer ASO with all PS internucleotide linkages has the following sequence:

• G*C*G*T*T*T*G*C*T*C*T*T*C*T*T*C*T*T*G*C*G

○ * = PS

and works by inhibiting translation of transcribed mRNA from the CMV gene UL123. It was eventually withdrawn from the market because the development of HAART (highly active antiretroviral therapy) to treat HIV reduced the number of CMV cases by 75% and therefore led to poor sales.

Since PS-only ASOs are not completely protected from nucleases, have reduced hybridization to target mRNAs, must be continually administered in large quantities to maintain modulation, and can interact with proteins, which may lead to negative side effects, first-generation constructs have largely been abandoned in R&D pipelines.

Second generation. In 2013, Mipomersen (brand name Kynamro^®) became the second approved antisense drug. It is used to treat familial hypercholesterolemia, a hereditary disorder. The drug is delivered by subcutaneous injection. The 20mer ASO with all PS internucleotide linkages has the following sequence:

• G*mC*mC*mU*mC*A*G*T*mC*T*G*mC*T*T*mC*G*mC*A*mC*mC

○ Underline = 2'-O-MOE-RNA (MOE is 2-methoxyethyl)

○ m = methyl, i.e. 5-Me-dC & 5-Me-U

○ * = PS

and works by inhibiting translation of apolipoprotein B-100 mRNA²³. There is a risk of severe liver damage, so the drug has to be part of a risk management plan.

Second-generation antisense molecules, such as Mipomersen, are designed with the 5-10-5 gapmer configuration. This can be seen in the sequence above: 5' and 3' wings of 5 bases (modified with a nuclease-resistant / enhanced-binding-affinity sugar modification) and a central gap of 10 standard deoxyribonucleotides (no sugar modification) that allows for RNase H binding.

In this particular case, the wings consist of 2'-O-MOE-RNA (MOE is 2-methoxyethyl), a non-standard sugar modification. However, we might be able to add this to your construct, so please send a request to dnaoligos@sial.com for feasibility.

Third generation. As of 2017, Miravirsen (SPC3649) is in Phase II clinical trials. It is being tested as a treatment for hepatitis C (HCV). The drug is delivered by subcutaneous injection. The 15mer ASO with all PS internucleotide linkages has the following sequence:

• C*C*A*T*T*G*T*C*A*C*A*C*T*C*C

○ Underline = LNA

○ * = PS

and works by hybridizing to human miRNA, miR-122. This prevents miR-122 from bringing argonaute to the 5'-UTR region of the HCV RNA, where it normally binds and therefore protects against nuclease degradation. Therefore, Miravirsen allows for destruction of the viral RNA.

Though Miravirsen is not a traditional ASO as it targets miRNA and therefore only indirectly leads to degradation of mRNA, it is one of the best examples of a third-generation construct containing LNA, hence it is included here.

Target Check

The final non-modified ASO sequence should be put through a BLAST search to ensure that any off-target hybridization — preferrably none — will not interfere with antisense activity or lead to unacceptable toxicity.

Quality Considerations

For in vivo animal experiments, we recommend ASOs undergo in-vivo-grade purification with a salt exchange (replaces toxic ammonium ions from the phosphoramidite synthesis chemistry with physiological sodium ions), endotoxin testing (ensures that pyrogens are present below an acceptable ceiling), and filtration (reduces the number of contaminating CFU below an acceptable ceiling). Our iScale Oligos™ product is larger quantities of material for in vivo projects that can be ordered with this purification and all of these additional services.

Delivery & Toxicity

Though beyond the scope of this article, there are several excellent review papers that discuss various delivery mechanisms as well as potential toxicities.

Conclusion

When you have designed an ASO that you want to try in an experiment, we are ready to synthesize it for you (our ASOs are for in vitro and in vivo animal RUO [Research Use Only]). If additional help is needed, especially regarding the feasibility of manufacturing ASOs with non-standard modifications, please send a request to dnaoligos@sial.com.

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