Proteomic analysis of the human amniotic mesenchymal stromal cell secretome by integrated approaches via filter-aided sample preparation

Abstract

The immunomodulatory, anti-inflammatory and regenerative properties of the human amniotic mesenchymal stromal cells (hAMSCs) secretome are acknowledged but the understanding of the specific bioactive components remains incomplete. To address these limitations, the present investigation aimed to profile the proteins and peptides content of the hAMSC secretome through sample pretreatment and fractionation on 10 kDa molecular cut-off FASP (Filter Aided Sample Preparation) device and LC-MS analysis. The filter retained protein fraction underwent trypsin digestion, while the unretained was collected unchanged for intact small proteins and peptides analysis. This combined approach (C-FASP) collects in a single step two complementary fractions, advantageously saving sample volume and time of analysis. The bottom-up analysis of the C-FASP proteins fraction >10 kDa confirmed our previous findings, establishing a set of proteins consistently characterizing the hAMSC secretome. The analysis of the fraction <10 kDa, never been investigated to our knowledge, identified peptide fragments of thymosin beta 4 and beta 10, collagen alpha 1 chains I and III, alpha-enolase, and glyceraldehyde-3-phosphate dehydrogenase, involved in wound healing, anti-inflammatory response, tissue repair and regeneration, key biological activities of the secretome. C-FASP provided a comprehensive molecular profile of the hAMSC secretome offering new insights for enhanced therapeutic applications in regenerative medicine.

Significance

In this investigation we originally present the comprehensive proteomic investigation of the human amniotic mesenchymal stromal cell secretome by combining the analysis of the proteome and of the peptidome following sample pretreatment and fractionation by Filter Aided Sample Preparation (FASP) with 10 kDa molecular cut-off in coupling with LC-MS analysis. The proteome fraction retained by FASP filter was analyzed after enzymatic digestion, while the unretained fraction, below 10 kDa molecular mass, was analyzed unchanged in its intact form. This dual approach provides novel insights, previously unexplored, into the molecular components potentially responsible for the immunomodulatory and anti-inflammatory properties of the hAMSC secretome. These findings could significantly enhance the therapeutic potential of hAMSCs in regenerative medicine.