Successful T cell engineering with gene scissors

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Successful T cell engineering with gene scissors

  There are two forms of T cell therapy: either a recipient receives cells from a donor, or the recipient's own T cells are removed, genetically reprogrammed in a laboratory and unleashed against an infection or tumor in the body. While the first method has proven to be successful in clinical models, reprogramming T cells is still beset with problems.
 
  Modifying T cell receptors
 
  The team led by Professor Dirk Busch, Director of the Institute for Medical Microbiology, Immunology and Hygiene at the TUM, has generated modified T cells for the first time that are very similar to their natural counterparts and could solve some of those problems. To do so, they utilized the new CRISPR-Cas9 gene scissors, which can be used to snip out and replace targeted segments of the genome.
 
  Both the conventional methods and the new method target the key homing instrument of T cells, known as the T cell receptor. The receptor, residing on the cell's surface, recognizes specific antigens associated with pathogens or tumor cells, which the T cell is then able to attack. Each receptor is made up of two molecular chains that are linked together. The genetic information for the chains can be genetically modified to produce new receptors that are able to recognize any desired antigen. In this way, it is possible to reprogram T cells.
 
  Targeted exchange using the CRISPR-Cas9 gene scissors
 
  The problem with conventional methods is that the genetic information for the new receptors is randomly inserted into the genome. This means that T cells are produced with both new and old receptors or with receptors having one old and one new chain. As a result, the cells do not function as effectively as physiological T cells and are also controlled differently. Moreover, there is a danger that the mixed chains could trigger dangerous side effects (Graft-versus-Host Disease, GvHD).
 
  "Using the CRISPR method, we've been able to completely replace the natural receptors with new ones, because we're able to insert them into the very same location in the genome. In addition, we've replaced the information for both chains so that there are no longer any mixed receptors," explains Kilian Schober, who is a lead author of the new study along with his colleague Thomas Müller.
 
  Near-natural properties
 
  Thomas Müller explains the advantages of the modified T cells: "They're much more similar to physiological T cells, yet they can be changed flexibly. They're controlled like physiological cells and have the same structure, but are capable of being genetically modified." The scientists have demonstrated in a cell culture model that T cells modified in this way behave nearly exactly like their natural counterparts.
 
  "Another advantage is that the new method allows multiple T cells to be modified simultaneously so that they're able to recognize different targets and can be used in combination. This is especially interesting for cancer therapy, because tumors are highly heterogeneous," Dirk Busch adds. In the future, the team plans to investigate the new cells and their properties in preclinical mouse models, an important step in preparing for clinical trials with humans.
 
  Story Source:
 
  Materials provided by Technical University of Munich (TUM). Note: Content may be edited for style and length.
 
  Journal Reference:
 

  Kilian Schober, Thomas R. Müller, Füsun Gökmen, Simon Grassmann, Manuel Effenberger, Mateusz Poltorak, Christian Stemberger, Kathrin Schumann, Theodore L. Roth, Alexander Marson, Dirk H. Busch. Orthotopic replacement of T-cell receptor α- and β-chains with preservation of near-physiological T-cell function. Nature Biomedical Engineering, 2019; DOI: 10.1038/s41551-019-0409-0


Ubigene Biosciences is co-founded by biological academics and elites from China, the United States, and France. We are located in Guangzhou Science City, which serves as a global center for high technology and innovation. Ubigene Biosciences has 1000㎡ office areas and laboratories, involving genome editing, cell biology technology, and zebrafish research. We provide products and services for plasmids, viruses, cells, and zebrafish. We aim to provide customers with better gene-editing tools for cell or animal research.

We developed CRISPR-U™ and CRISPR-B™ (based on CRISPR/Cas9 technology) which is more efficient than general CRISPR/Cas9 in double-strand breaking, CRISPR-U™ and CRISPR-B™ can greatly improve the efficiency of homologous recombination, easily achieve knockout (KO), point mutation (PM) and knockin (KI) in vitro and in vivo. 

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