by Stefanie Seltmann, Berlin Institute of Health
Imaging mass spectrometry analysis of murine critical-size femur fractures treated with in vitro engineered human stromal cell–derived cartilage discs. (A to D) Segmentation maps were generated from the mass-to-charge (m/z) value spectra of whole tissue sections of BMSC-derived (A and B) and ATSC-derived (C and D) transplant groups using an unsupervised bisecting k-means algorithm. Segments with different colors represent distinct proteomic clusters across the whole tissue sections. The first two proteome clusters distinguish between bone (yellow) and muscle tissue (blue). In the bone region, segmentation clustering identified two additional segments in the BMSC group (B) and three segments in the ATSC group (C). The third proteomic cluster (yellow) of the ATSC group corresponds to the fracture region and was not detected in the BMSC group. Additional segmentation of the fracture region revealed two distinct clusters in the BMSC group (B insert magnified as indicated) but only one cluster in the ATSC group (C insert magnified as indicated). (E) Using a bottom-up liquid chromatography–tandem mass spectrometry approach, several m/z values were assigned to COL1A1-specific peptides. The peptide mass spectra show the absolute intensity of indicated m/z values in the fracture (black line) and total bone region (gray line). The blue shading indicates COL1A1 peptide (m/z = 2055) that is highly conserved between human and mice, whereas the yellow shading indicates a human-unique COL1A1 peptide (m/z = 2057). (F) Movat’s 5C staining of the complete mouse femur containing the BMSC-derived cartilage disc transplant in fracture area, magnified in (L). (G) The highly conserved COL1A1 peptide (m/z = 2055) (total = human + mouse; colored green) was distributed throughout the bone of the BMSC group. (H) The human-specific COL1A1 peptide (m/z = 2057; colored red) shows a high intensity distribution exclusively in the fracture region. (I) Merge of the total and the human-specific COL1A1 peptide. (J) Merging the intensity distribution of the human-specific COL1A1 peptide (m/z = 2057) with Movat’s 5C staining shows that it is colocalized only with the area of remaining hard callus. (K) Magnification of Movat’s 5C staining of the same fracture region shown in (F), and (L) the corresponding merge with intensity distribution of the human-specific COL1A1 peptide (m/z = 2057). n = 4 biological replicates per group. Credit: Science Translational Medicine (2023). DOI: 10.1126/scitranslmed.abm7477
Bone is the second most commonly transplanted tissue after blood, with about two million bone transplants performed worldwide each year—but often with only moderate therapeutic success. Cell-based therapies could provide an alternative approach to transplantation.
Together with colleagues from Paracelsus Medical Private University (PMU) Salzburg, researchers at the Berlin Institute of Health at Charité (BIH) have now demonstrated that human progenitor cells can regenerate large bone defects and form new mineralized tissue. The researchers have published the findings from their work in the journal Science Translational Medicine.
Although most bone fractures heal completely without scarring, particularly large bone defects caused by severe trauma, infection or tumor surgery often do not heal naturally and require bone transplantation. Bone is the second most commonly transplanted tissue after blood, with about two million bone transplants performed worldwide each year.
However, the availability of grafts is limited and their regenerative capacity is often low. Cell-based therapies offer a promising alternative. Tissue engineered in vitro from progenitor cells such as multipotent stromal cells (MSCs) could replace standard bone graft treatments.
Together with colleagues from Paracelsus Medical Private University (PMU) Salzburg, researchers at the Berlin Institute of Health at Charité (BIH) have now shown that this method works. A crucial factor is that these stromal cells can be obtained from various tissues, such as adipose tissue, skin tissue and bone marrow.
Stromal cell origin plays a key role in regenerative capacity
Multipotent stromal cells (MSCs) are the progenitor cells in various connective tissues that can differentiate into different cell types like fat, cartilage and bone cells. However, contrary to previous assumptions, the source of stromal cells has a decisive impact on their bone regeneration potential. Unlike cells from white adipose tissue, the umbilical cord or skin tissue, only MSCs from bone marrow have the ability to form functional cartilage.
This is due to a so-called epigenetic signature that determines which genes can be accessed during cell differentiation and in which order they are activated.
“This hypertrophic cartilage produced in vitro is an important intermediate for the formation of mineralized bone tissue. We were able to show that transplantation of vital human cartilage disks into mice with large (non-healing) bone defects leads to complete healing,” says Dr. Geissler, a group leader at the BIH Center for Regenerative Therapies who is one of the study’s senior authors.
“In the animal, the transplanted human cells in the cartilage disks also form the original bone tissue, which is replaced by mouse-derived cells only at the end of complete healing.”
New epigenetic mechanism regulates bone healing
In their study, the researchers describe a novel epigenetic mechanism that not only underlies the stromal cells’ regenerative potential but also regulates bone healing. This involves a complex network of so-called enhancers—amplifiers of gene expression—in the cells’ DNA. This enhancer network is particularly accessible and active in these cells, thus determining the course and success of tissue regeneration. The researchers call this network the “enhancer landscape.”
“Our study makes an important contribution to the selection of suitable cells for effective treatment of difficult-to-heal bone fractures. The knowledge gained here about such tissue-specific enhancer signatures may also contribute to the improvement of other cell-based therapies,” says Prof. Dirk Strunk, director of the Institute of Experimental and Clinical Cell Therapy at PMU Salzburg and co-senior author of the study.
The path to clinical trials
Further development steps are necessary to translate this new approach into a reliable therapeutic option for large bone defects in orthopedics and trauma surgery. For instance, the researchers led by Sven Geissler and Dirk Strunk now want to conduct tests to see how cartilage disks can be produced automatically from stromal cells and whether exogenous donor cells are also suitable for the therapy.
Patients would otherwise have to wait up to five weeks after having their own cells harvested before the cartilage disks could be produced and implanted. However, there is ample cause for optimism, given the test results achieved so far.
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