Overcoming Delivery Challenges in Gene Editing
Modern genome editing techniques, including CRISPR systems, hold great potential for treating genetic diseases. However, delivering these molecular tools reliably to their target cells remains a significant challenge.
“Previous viral and non-viral delivery systems such as adeno-associated viruses (AAVs), lipid nanoparticles (LNPs), and other virus-like particles (VLPs), have been valuable but face limitations,” says Dr. Dong-Jiunn Jeffery Truong, last author of the study and group leader at the Institute for Synthetic Biomedicine at Helmholtz Munich. “Challenges include the increased persistence of gene editors potentially causing immune reactions, or simply their limited efficiency. ENVLPE directly addresses these issues while its modular design maintains compatibility with future gene-editing advancements.”
ENVLPE is based on modified, non-infectious virus-derived shells. These act as carriers for molecular gene editors such as base or prime editors – specialized CRISPR tools that can chemically change single DNA bases in the genome and remove or insert new DNA sequences. ENVLPE's design solves the logistics challenge of previous methods during the production of the VLPs by hijacking the intracellular transport mechanism so that all components come together at the right time and place.
Prior methods often included partially assembled, non-functional gene editors, reducing delivery effectiveness. “ENVLPE now not only ensures the packaging of fully assembled gene editors but also contains an extra molecular shield that protects the most vulnerable part of the editor from degradation during transport,” explains Truong. “This allows the genetic tools to be safely delivered into target cells where the intended DNA edit can take place.”
Restoring Vision: Gene Editing in Action
In close collaboration with a team led by Prof. Krzysztof Palczewski, a professor of ophthalmology at UC Irvine, the scientists tested the ENVLPE system in a mouse model of inherited blindness. “The mice carry a disabling mutation in the Rpe65 gene, which is essential for producing light-sensitive molecules in the retina, and therefore are fully blind and unresponsive to light,” explains Samuel W. Du, a co-author and MD/PhD candidate at UC Irvine. After injecting ENVLPE into the subretinal space (the area between the retinal pigment epithelium and photoreceptors) to correct the mutation, the animals began to respond to light stimuli again. “The extent of restoration was astounding,” says Julian Geilenkeuser, co-first author of the study and a doctoral researcher at the Institute for Synthetic Biomedicine. “It showed us that our particles have real therapeutic potential in a living animal.”
Compared to established systems, ENVLPE achieved significantly better results: a competing system required more than 10 times the dose to reach similar effects. “Our goal was to build a tool that is both useful for researchers and suitable for real-world applications,” says Niklas Armbrust, also co-first author and a doctoral researcher at the Institute for Synthetic Biomedicine. “We resolved critical bottlenecks and achieved a much more efficient packaging by the delivery agents.”
Advancing Cancer Therapy with Universal T Cells
ENVLPE could also open up new possibilities for adoptive T cell therapies, where immune cells taken from the patient are genetically modified in the lab so that they can specifically recognize and attack tumor cells. In collaboration with Dr. Andrea Schmidts’ laboratory at TUM University Hospital, ENVLPE facilitated the targeted removal of specific surface molecules that could trigger an immune response when the cells are administered to a recipient different from the donor. This could lead to the development of so-called “universal” T cells that do not need to be customized for individual patients, making treatments more accessible and cost-effective.
These innovations address critical challenges in both in vivo gene therapies for genetically inherited diseases and ex vivo cell therapies for cancer, paving the way for important translational advancements. “The highly modular ENVLPE system brings us substantially closer to on-demand and precise genetic modifications of complex cellular models,” says Prof. Gil Westmeyer, Director of the Institute for Synthetic Biomedicine and Professor for Neurobiological Engineering at TUM and co-senior author of the study. “It is an example of how synthetic biology can help drive medical innovation.”
Moving Toward Clinical Use
Having now achieved highly efficient delivery of the most common gene-editing tools, the team now seeks to use the diversity found in nature, along with the recent advancements in AI-assisted protein design, to increase targeting precision by restricting the delivery of these tools to specific cell or tissue types only. To move ENVLPE toward clinical application, the research team is pursuing follow-up funding from translational grants and partnerships in the pharmaceutical industry. The goal is to optimize the technology for various therapeutic applications and ultimately make it available to patients.
Info Box: What is ENVLPE?
ENVLPE stands for “Engineered Nucleocytosolic Vehicles for Loading of Programmable Editors.” These are non-infectious virus-like particles that can efficiently transport gene-editing tools such as base or prime editors into target cells. ENVLPE overcomes two major limitations of earlier systems: the instability of the guide RNA payload and inefficient packaging of only functional gene editors within the production cells. By adjusting intracellular transport mechanisms, the researchers significantly increased the system’s efficiency and safety.
About the Researchers
Dr. Dong-Jiunn Jeffery Truong, group leader at the Institute for Synthetic Biomedicine at Helmholtz Munich
Prof. Gil Westmeyer, Director of the Institute for Synthetic Biomedicine at Helmholtz Munich and Professor for Neurobiological Engineering at TUM
About Helmholtz Munich
Helmholtz Munich is a leading biomedical research center. Its mission is to develop breakthrough solutions for better health in a rapidly changing world. Interdisciplinary research teams focus on environmentally triggered diseases, especially the therapy and prevention of diabetes, obesity, allergies, and chronic lung diseases. With the power of artificial intelligence and bioengineering, researchers accelerate the translation to patients. Helmholtz Munich has around 2,500 employees and is headquartered in Munich/Neuherberg. It is a member of the Helmholtz Association, with more than 43,000 employees and 18 research centers the largest scientific organization in Germany. More about Helmholtz Munich (Helmholtz Zentrum München Deutsches Forschungszentrum für Gesundheit und Umwelt GmbH): www.helmholtz-munich.de/en
Journal
Cell