mRNA therapeutics is the delivery of messenger RNA (mRNA) molecules into the body, which the cellular machinery can use to make specific proteins. The field is rapidly advancing, especially because mRNA vaccines proved successful against COVID-19. However, the delivery of these engineered mRNAs to a specific organ has proved challenging. Now, a team at Tokyo Medical and Dental University (TMDU) has shown that coating the engineered mRNAs with a molecule called polyethylene glycol, or PEG, allows their delivery selectively to the spleen.

 

To understand this achievement, let's first discuss how mRNA therapeutics has worked until now. Engineered mRNAs have been packaged into structures called "polyplexes" for delivery into the body. The polyplex structures allow mRNAs to remain stable while outside cells and to be released in a controlled manner once inside cells. Once inside, the mRNAs are used by cellular machinery to produce proteins that are naturally dysfunctional or absent. Without modification, the polyplexes tend to accumulate in the lungs, as after injection into the blood they rapidly stick to each other and surrounding proteins and cells and become lodged in the lung's blood vessels. Treating polyplexes with PEG, a process called "PEGylation," prevents them from sticking together. The team at TMDU has developed a new method of PEGylation, where the mRNAs are hybridized to PEG molecules before the polyplexes are formed. Using this method, almost all the PEG strands mixed into the reaction become bound to the polyplexes, allowing much greater control over the final amount of PEG on the polyplex surface.

 

Using a mouse model, the team found that the quantities and lengths of the PEG molecules significantly affected how well the mRNA therapy worked. A small number of short PEG molecules prevented accumulation of the engineered mRNAs in the lungs, facilitating effective delivery to the spleen. This approach has demonstrated utility in mRNA vaccines. The novel method allows fine tuning of the amount of PEGylation of mRNA polyplexes. mRNA technology has wide-ranging potential for treating many diseases that have previously been considered incurable, as well as for the development of novel cancer treatments and vaccines.