Background

Trafficking of hematopoietic stem/progenitor cells (HSPCs) to and from their bone marrow (BM) niche is pivotal for engraftment and mobilization during clinical transplantation, where both processes are controlled by highly orchestrated molecular programs. We previously identified the tetraspanin CD9 as a downstream effector of the SDF-1/CXCR4 axis driving migration, adhesion and homing of human CD34+ HSPCs, but its consequential impact on stem cell engraftment and mobilization as well as the underlying mechanisms remains unknown.

Methods

Umbilical cord blood (UCB) CD34+ cells were exposed to a CD9 neutralizing antibody ALB6 prior to infusion into sublethally irradiated NOD/SCID mice, with overall engraftment and lineage output assessed by enumerating human CD45+ (pan-leukocytes), CD19+ (B-lymphoid), CD33+ (myeloid) and CD34+ (stem/progenitors) cells in the recipient BM at 8 weeks post-transplantation. CD9 expression on engrafted HSPCs was characterized by flow cytometry and compared to those before transplantation or after G-CSF mobilization. The oscillation pattern was then validated on HSPCs in pairwise BM, peripheral blood (PB) and G-CSF-mobilized peripheral blood (MPB) samples from healthy donors. Activity of integrin VLA-4 (an established binding partner of CD9) was evaluated on BM-residing and mobilized HSPCs by VCAM-1 binding assay.

Results

A short exposure of UCB CD34+ cells to the CD9 neutralizing antibody markedly inhibited their BM engraftment by 64.2% ( P=0.003), reflected by the general decline in human CD45+ cell population. There was no bias in lymphoid/myeloid lineage outputs, suggesting CD9-mediated engraftment is not restricted to specific subsets of hematopoietic precursors.

CD9 expression was drastically elevated on engrafted CD34+ cells in the BM from 9.6% to 91.4% ( P<0.001) compared to pre-transplantation. In contrast, CD9 expression was significantly downregulated on BM CD34+ cells from 73.4% to 33.5% ( P<0.001) upon G-CSF mobilization, with the decline observed in both primitive stem cells (CD34+CD38-) and committed progenitors (CD34+CD38+), indicating that the oscillation of CD9 is highly associated with HSPC trafficking.

Concordantly, pairwise analysis of steady-state HSPCs in BM and PB from healthy donors revealed higher CD9 level in BM-residing CD34+ cells than the PB-circulating portion (46.1% vs. 26.5%, P=0.004; n=13). In addition, a significantly higher CD9 expression was observed on BM CD34+ cells (47.7%; n=16) than those in MPB (32.3%, n=25; P=0.003). CD9 expression on MPB CD34+ cells was enhanced upon SDF-1 exposure ( P=0.006), revealing a dynamic regulation.

In normal BM, CD9+ HSPCs exhibited elevated VLA-4 activities with preferential binding to soluble VCAM-1 compared to the CD9- counterpart (51.4% vs. 25.9%, P<0.001; n=10). Superiority in VCAM-1 binding capacity was also witnessed in BM-residing CD34+ cells compared to MPB (37.7% vs. 4.1%, P=0.014), implicating that the influence of CD9 on HSPC trafficking may due to the alteration of integrin activities and downstream adhesive properties.

Conclusion

This study describes the dynamic regulation of CD9 during entry and exit of HSPCs to and from their BM niche via modulation of integrin activities. The findings extend our understandings on HSPC trafficking that could potentially lead to new strategies to enhance clinical stem cell transplantation and mobilization.

No relevant conflicts of interest to declare.

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