In a major leap forward for synthetic biology, scientists have used RNA origami to engineer artificial cytoskeletons—key structural components of cells. This cutting-edge technique may soon allow researchers to construct fully synthetic cells, opening doors to new treatments, sustainable biomanufacturing, and even life-like machines.
The groundbreaking study was recently published in the journal Nature Nanotechnology, where researchers detailed how RNA molecules were folded into precise shapes that mimic the cytoskeletal filaments found in natural cells.
RNA origami is a process that uses the natural folding properties of RNA molecules to create specific three-dimensional structures. Inspired by the Japanese art of paper folding, RNA origami relies on the base-pairing rules of nucleotides—adenine, cytosine, guanine, and uracil—to design intricate nanostructures.
Unlike DNA origami, which has been more widely studied, RNA origami offers advantages due to RNA’s ability to both store genetic information and act as a catalyst. Its versatility makes it ideal for building dynamic structures inside cells.
Learn more about the basics of RNA origami and its role in synthetic biology.
The cytoskeleton is essential for cell shape, movement, and internal organization. In natural cells, the cytoskeleton is composed of protein filaments like actin and microtubules. To create fully synthetic cells—cells not derived from living organisms—scientists must replicate this internal structure.
The research team designed RNA origami filaments that could mimic the role of the cytoskeleton. When inserted into synthetic cell-like compartments (also known as liposomes), these RNA-based structures formed networks that supported the shape and mechanical stability of the artificial cells.
According to lead researcher Dr. Ebbe Andersen from Aarhus University, “This work marks a foundational step toward building artificial cells from scratch.”
Synthetic biology aims to create life-like systems using designed molecules, not living organisms. Building a fully synthetic cell requires multiple parts: a membrane, genetic code, energy systems, and a structural scaffold—like the cytoskeleton.
RNA origami offers a powerful platform for assembling this scaffold. The new technique allows for customizable, biodegradable, and functional internal structures.
Scientists envision using synthetic cells in a variety of fields, including:
Read about related innovations in synthetic biology and artificial life.
The research team used computer models to design RNA sequences that would fold into helical filament shapes. These sequences were synthesized in the lab and introduced into liposomes—small spherical compartments that mimic cell membranes.
Once inside the liposomes, the RNA structures self-assembled into a scaffold. High-resolution microscopy confirmed that these artificial filaments resembled actin filaments in natural cells, and they helped maintain the shape and volume of the synthetic compartments.
One striking result: synthetic cells with RNA origami scaffolds were more stable and resistant to deformation than those without.
While promising, the work is still in its early stages. One major challenge is achieving precise control over RNA folding inside dynamic environments like synthetic cells. RNA is also more chemically fragile than DNA or proteins, so enhancing its stability is a critical step.
Still, the research offers an exciting path forward. “We’re trying to understand what the minimal requirements are to build a life-like system,” said co-author Dr. Rebecca Schulman of Johns Hopkins University. “RNA origami gives us an unprecedented level of control.”
For more context, visit this overview on cytoskeletal engineering in synthetic systems.
This breakthrough brings scientists closer to building synthetic life forms. Such systems could be used to study diseases, test drugs, and manufacture products without relying on living organisms. However, as with all synthetic biology innovations, ethical and safety questions remain.
Who will regulate the use of synthetic cells? Could they evolve or escape lab settings? How will we ensure they don’t harm natural ecosystems?
Experts emphasize the need for thoughtful regulation and public dialogue as the technology advances.
The use of RNA origami to construct artificial cytoskeletons marks a pivotal achievement in synthetic biology. It not only showcases the ingenuity of molecular engineering but also sets the stage for the eventual creation of fully synthetic cells.
This research is a critical step toward building programmable life-like systems that could transform medicine, industry, and environmental science. As Dr. Andersen notes, “The future of biology may not be about understanding life—but building it.”
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