Very High Expression of MGMT(P140K) Paradoxically Impairs Proliferation, In Vivo Selection and Protection of Transduced Hematopoietic Stem Cells.

The drug resistance gene MGMT(P140K) mutant has been extensively studied as a means to protect/select hematopoietic stem cells (HSC) following treatment with O⁶-alkylating agents such as temozolomide (TMZ) in tandem with the inhibitor of endogenous MGMT, O⁶-benzylguanine (6BG). Since the repair of O⁶-alkyl adducts by MGMT is stoichiometric, it has been suggested that higher levels of MGMT(P140K) will confer better protection upon HSC. To test this hypothesis, we developed a panel of SIN γ-retroviral vectors which express low to very high levels of MGMT(P140K) via different internal promoters. The MGMT activity in bone marrow cells (BMC) transduced with a viral LTR-derived promoter, SF(MGMT), was approximately 7-fold higher than in cells transduced with either cellular promoters PGK(MGMT) or EFS(MGMT) which were in turn >300-fold higher than in control transduced cells (CON). Mice transplanted with transduced BMC were treated with 6BG (30mg/kg) and TMZ (80mg/kg) on 3 consecutive days starting 7 weeks post-transplant. Surprisingly, we found that selection/protection was not evident in mice engrafted with SF(MGMT) transduced BMC, while robust long term in vivo selection/protection was observed in mice transduced with PGK(MGMT) and EFS(MGMT) BMC (Table 1). We next sought to explore the mechanism of these findings. 2 hours after 6BG/TMZ treatment, BMC harvested from SF-, PGK- and EFS(MGMT) groups showed equivalent repair of the O⁶-alkylguanine lesion. Thus, lower MGMT expression is adequate for O⁶-alkylguanine lesion repair, and the lack of selection by SF(MGMT) is not related to defective repair. In the absence of chemoselection, we found a modest but statistically significant decrease in the in vivo reconstitution of SF(MGMT)-transduced BMC compared to EFS- or PGK- transduced BMC in a competitive repopulation assay, while secondary recipients showed a more pronounced engraftment defect (18- and 32-fold lower engraftment of SF(MGMT) vs EFS(MGMT), (p<0.05) or PGK(MGMT), (p<0.01) respectively). To further examine this repopulation defect, 32D cells were transduced with SF(MGMT) and

1. demonstrated a growth defect in vitro (Table 2),

2. have >40% reduced colony forming ability (p<0.01) and

3. show >30% reduced ³H thymidine uptake (p<0.01), but do not demonstrate an elevated rate of apoptosis.