Tumours unexpectedly inspire the treatment of diabetic foot ulcers (DFUs). Scientists have discovered a way to train healthy immune cells to acquire the skills of some tumour cells – but for a good purpose – to accelerate diabetic wound healing. This remarkably promising finding, recently published in EMBO Molecular Medicine , a flagship journal under European Molecular Biology Organization, may open up a brand new avenue for regenerative medicine.
Diabetes affects over 100 million people worldwide, and its most severe complication, DFUs, causes an amputation every 30 seconds on average. One of the fundamental reasons behind the non-healing status of DFUs, compared with common cutaneous wounds, is the dysfunction of a mixed group of immune cells called macrophages. These cells change their functions to coordinate wound healing in different stages but fail to do so under diabetic pathology. Previous attempts to rectify the macrophages have proven suboptimal.
The collaborative team, led by Professor Chunming Wang at the University of Macau and Professor Lei Dong at Nanjing University, are inspired by tumour-associated macrophages (TAMs), which play essential roles in driving tumour development by secreting factors that promote blood vessel formation and inhibit immune attack, realising that such features perfectly fulfil the requirements for diabetic wound healing. They boldly hypothesised that TAMs could ‘pass on’ these features to non-tumour macrophages through co-culture, in a way that TAMs influence other cells in cancer growth.
They design and optimise protocols to verify this hypothesis, finding that normal macrophages derived from mouse bone marrow can gain a new set of pro-regenerative functions after co-culture with TAMs. When transferred to the wound bed in diabetic mice, these cells potently induce cell proliferation, resolve inflammation and orchestrate vasculature in the typically non-healing wounds. Further, gene analytical tools, one of which is named single-cell RNA sequencing, reveal some surprising findings. These TAMs-educated macrophages (TAMEMs) are distinct from known phenotypes (typically simplified as M1 or M2 in biological terminology). In short , these cells exhibit unique skills after training that appropriately fulfil the demands of diabetic wounds.
The team made a further stride by trying to dissect the secret of TAM’s power – e.g. identify the multiple factors that equip normal macrophages with these reparative capabilities. Eventually, they reconstitute a nine-factor cocktail and test its efficacy on – this time, human – monocytes, leading to a desirable outcome. Furthermore, this test totally abandons any tumour-derived components (including TAMs), representing the imminent translational potential for a clinical trial.
Professor Lijian Hui, an expert from the Shanghai Institute of Biochemistry and Cell Biology, China, highly appraises the creativity and translational potential of this work. According to Hui, this work is very creative in recapitulating the characteristics of TAMs for diabetic wound healing. It is also significant to set a good example of elucidating the mechanisms of actions of therapeutic cells (TAMEMs, in this case), which is often overlooked in developing cell therapy approaches. Hui expects the team to further their work in understanding the variances and heterogeneity of the engineered macrophages, tackling the challenges in quality control and accelerating the preclinical tests.
Full-text link: https://www.embopress.org/doi/full/10.15252/emmm.202216671
Article: Tumor-associated macrophages-educated reparative macrophages promote diabetic wound healing, Mu et al., 2022, EMBO Mol Med (2022), e16671
EMBO Molecular Medicine
Experimental study
Animals
Tumor-associated macrophages-educated reparative macrophages promote diabetic wound healing
1-Jan-2023
No conflict of interest