New mRNA produces 200 times more protein: Hope for treatment of cancer and protein disorders

Capping circular mRNA in a new way

ICIT builds on the promise of circular mRNAs, a new generation of mRNA treatments known for their stability and reduced inflammatory effects compared to traditional linear mRNAs. Unlike linear mRNAs, circular mRNAs are less susceptible to enzymatic degradation because of their lack of terminal structures, offering a sustained translation process.

However, one significant challenge with circular mRNAs has been the inefficiency of their translation inside living organisms. Previous methods relied on long internal ribosome entry sites (IRES) for introducing the mRNA, which were difficult to optimize and often inefficient. Abe's team overcame this hurdle by introducing a cap structure into the circular mRNA itself. This internal cap structure triggers translation initiation, bypassing the need for IRES sequences, and significantly improves the efficiency of protein synthesis.

Precision therapy

Abe and his colleagues developed two designs. Among these, Cap-circRNA demonstrated superior performance, synthesizing up to 200 times more protein than commonly used circular mRNAs with IRES sequences. Importantly, this synthesis persisted for an extended period, even after traditional mRNA structures began to degrade. This stability and ability to selectively target cells make Cap-circRNA an ideal candidate for developing precision therapies.

"This technology is expected to revolutionize mRNA medicine, including antibody therapy, genome editing, and protein replacement therapy," Abe said. "Current mRNA is fundamentally unstable, requiring constant injections to be used for treatments such as protein replacement, a problem that our technique overcomes. Using this, we could treat diseases caused by abnormal protein synthesis, such as Duchenne muscular dystrophy."

Targeting cancer cells

The ICIT mechanism's ability to control protein translation at the single-cell level also offers a transformative approach to the treatment of cancers and other tissue-specific diseases. By targeting specific RNA markers that are highly expressed in diseased cells, such as those found in liver cancer, the mRNA can instruct protein synthesis only in target cells. This precision reduces the risk of off-target effects and side reactions, which are common challenges in current treatments. To test its efficacy, the team designed a circular RNA using ICIT to target HULC lncRNA, an RNA that is commonly found in liver cancer cells. HULC lncRNA's presence resulted in over a 50-fold increase in protein synthesis, highlighting ICIT-RNAs' ability to differentiate single cancer cells from normal cells.

"This breakthrough paves the way for developing mRNA drugs that selectively target diseased cells without adverse effects," Abe said. "Using a biomarker from cancer cells, we could design an mRNA that expresses a toxic protein only in cancer cells. Programmed cell death could then be induced by cytokines."

The study also suggests that similar translation control mechanisms might naturally occur in cells through the interaction of long non-coding RNAs and mRNAs. Understanding these processes may lead to new therapeutic approaches for a variety of diseases. Abe team's discovery marks a significant advancement in mRNA medicine, opening exciting possibilities for the future of personalized and precise healthcare.