Recent approaches of regenerative reproductive medicine investigate the decellularized extracellular matrix to develop a transplantable engineered ovary (TEO). However, a full proteomic analysis is not usually performed after the decellularization process to evaluate the preservation of the extracellular matrix (ECM). In this study, the ECM of the bovine ovarian cortex was analyzed before and after decellularization using mass spectrometry and bioinformatics. A total of 155 matrisome proteins were identified in the native ECM of the bovine ovarian cortex, with 145 matrisome proteins detected in the decellularized ECM. After decellularization, only 10 matrisome proteins were lost, and notably, none belonged to the category of reproductive biological processes. Histology and histochemistry analyses were employed to assess the general morphology of both native and decellularized ECM, allowing for the identification of the most abundant ECM proteins. Moreover, our study highlighted collagen type VI alpha 3 and heparan sulfate proteoglycan 2 as the most abundant components in the bovine ovarian ECM, mirroring the composition observed in the human ovary. These findings enhance our understanding of the composition of both native and decellularized ECM, with the potential implications for the development of a TEO. SignificanceThe significance of the present study lies on the possibility of advancing towards developing a bioengineered ovary, which is the ultimate strategy to regain fertility in women. The results demonstrate that the decellularized extracellular matrix of the bovine ovary maintains the protein composition of the native matrisome, using a recently described decellularization protocol. The decellularized matrix may serve as scaffolding for seeding ovarian stromal cells and follicles to create a bioengineered ovary, and as closer its composition is to the native matrix the better. Also, comparing the bovine ovarian matrisome, which was described for the first time here, with the human ovarian matrisome, we could see a great similarity, suggesting that the bovine ovary decellularized matrix may serve as a model for developing a human bioengineered ovary.
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