Self-immolative nitrogen mustard prodrugs for suicide gene therapy

D Niculescu-Duvaz, I Niculescu-Duvaz… - Journal of medicinal …, 1998 - ACS Publications
D Niculescu-Duvaz, I Niculescu-Duvaz, F Friedlos, J Martin, R Spooner, L Davies, R Marais…
Journal of medicinal chemistry, 1998ACS Publications
Four new potential self-immolative prodrugs derived from phenol and aniline nitrogen
mustards, four model compounds derived from their corresponding fluoroethyl analogues
and two new self-immolative linkers were designed and synthesized for use in the suicide
gene therapy termed GDEPT (gene-directed enzyme prodrug therapy). The self-immolative
prodrugs were designed to be activated by the enzyme carboxypeptidase G2 (CPG2)
releasing an active drug by a 1, 6-elimination mechanism via an unstable intermediate …
Four new potential self-immolative prodrugs derived from phenol and aniline nitrogen mustards, four model compounds derived from their corresponding fluoroethyl analogues and two new self-immolative linkers were designed and synthesized for use in the suicide gene therapy termed GDEPT (gene-directed enzyme prodrug therapy). The self-immolative prodrugs were designed to be activated by the enzyme carboxypeptidase G2 (CPG2) releasing an active drug by a 1,6-elimination mechanism via an unstable intermediate. Thus, N-[(4-{[4-(bis{2-chloroethyl}amino)phenoxycarbonyloxy]methyl}phenyl)carbamoyl]-l-glutamic acid (23), N-[(4-{[4-(bis{2-chloroethyl}amino)phenoxycarbonyloxy]methyl}phenoxy)carbonyl]-l-glutamic acid (30), N-[(4-{[N-(4-{bis[2-chloroethyl]amino}phenyl)carbamoyloxy]methyl}phenoxy)carbonyl]-l-glutamic acid (37), and N-[(4-{[N-(4-{bis[2-chloroethyl]amino}phenyl)carbamoyloxy]methyl}phenyl)carbamoyl]-l-glutamic acid (40) were synthesized. They are bifunctional alkylating agents in which the activating effects of the phenolic hydroxyl or amino functions are masked through an oxycarbonyl or a carbamoyl bond to a benzylic spacer which is itself linked to a glutamic acid by an oxycarbonyl or a carbamoyl bond. The corresponding fluoroethyl compounds 25, 32, 42, and 44 were also synthesized. The rationale was to obtain model compounds with greatly reduced alkylating abilities that would be much less reactive with nucleophiles compared to the corresponding chloroethyl derivatives. This enabled studies of these model compounds as substrates for CPG2, without incurring the rapid and complicated decomposition pathways of the chloroethyl derivatives. The prodrugs were designed to be activated to their corresponding phenol and aniline nitrogen mustard drugs by CPG2 for use in GDEPT. The synthesis of the analogous novel parent drugs (21b, 51) is also described. A colorectal cell line was engineered to express CPG2 tethered to the outer cell surface. The phenylenediamine compounds were found to behave as prodrugs, yielding IC50 prodrug/IC50 drug ratios between 20- and 33-fold (for 37 and 40) and differentials of 12−14-fold between CPG2-expressing and control LacZ-expressing clones. The drugs released are up to 70-fold more potent than 4-[(2-chloroethyl)(2-mesyloxyethyl)amino]benzoic acid that results from the prodrug 4-[(2-chloroethyl)(2-mesyloxyethyl)amino]benzoyl-l-glutamic acid (CMDA) which has been used previously for GDEPT. These data demonstrate the viability of this strategy and indicate that self-immolative prodrugs can be synthesized to release potent mustard drugs selectively by cells expressing CPG2 tethered to the cell surface in GDEPT.
ACS Publications