Title: Ferric ion-specific sequestering agents. 7. Synthesis, iron-exchange kinetics, and stability constants of N-substituted, sulfonated catechoylamide analogs of enterobactin

For treatment of chronic iron overload (as occurs in Cooley's anemia), ferric ion sequestering agents with specific properties are necessary. Two analogues of enterobactin [a microbial chelating agent with the greatest stability constant known for an Fe(III) complex] are reported which exhibit: i) hydrolytic stability; ii) water solubility; iii) N-substitution to block peptidase hydrolysis. The first compound, N,N',N"- trimethyl-N,N',N"-tris(2,3-dihydroxysulfobenzoyl)1,3,5-triaminomethyl- benzene, [Me₃MECAMS, 6] was prepared from the amide of trimesloyl chloride (1) and MeNH₂. The resulting amide was reduced to the triamine (3) and converted in three steps to the final product 6 in 6% overall yield. The proton-dependent formation constant (log K*) for the reaction: Fe³⁺ + H₃L^6- = FeL^6- + 3H⁺ is 4.87, which gives an equilibrium concentration of [Fe³⁺] at pH 7.4 of 2 x 10^-27 M for 10^-5 M L (6) and 10^-6 M total Fe³⁺. The estimated formation constant (log β₁₁₀) is 40. At low pH the FeL^6- complex undergoes a series of three, one-proton reactions which probably gives a tris-salicylate complex formed by the carbonyl and ortho-catechol oxygen of the 2,3-dihydroxybenzoyl units (the same reaction that occurs with ferric enterobactin). After six hours in the presence of 6 mM ascorbate, Me₃MECAMS (6.0 mM) removed 3.7% of the ferric ion initially sequestered by the iron storage protein, ferritin. The human iron transport protein transferrin gives up iron to Me₃MECAMS with a pseudo first-order rate constant of 1.9 x 10^-3min^-1 (ligand concentration 2 X 10^-4 M). This rate is comparable to that of enterobactin and other catechoyl amide sequestering agents, and greatly exceeds that of desferrioxamine B (Desferal®), the current drug of choice in treating iron overload. Two related compounds have been prepared in which the catechol ring is attached to the amide nitrogen through a methylene group, with amide formation with an acetyl group. In N,N',N"-triacetyl-N,N' ,N"-tris(2,3-dihydroxysulfobenzoyl)-N,N',N"-triaminomethylbenzene [NAcMECAMS, 111... and its unsulfonated precursor, the amide linkage of the catechoyl amides such as Me₃MECAMS (6) has been shifted from an endo position relative to the benzene and catechol rings to an exo position in which the amide carbonyl is not conjugated with the catechol ring and cannot form a stable chelate ring in conjunction with a catechol oxygen. The preparation of 11 and 10 proceeded from the previously described precursor of TRIMCAM, 7, borane reduction to the triamine 8, and amide formation with acetyl chloride to 9, followed by deprotection of the catechol oxygens with BBr₃/CH₂Cl₂ to give 10. Sulfonation of 10 to NAcMECAMS, 11, is carried out in fuming sulfuric acid. In comparison with Me₃MECAMS, the protonation of NAcMECAMS (11) proceeds by an initial two-proton step in contrast to the one-proton reactions typical of the catechoyl amides, which can form a salicylate mode of coordination involving the amide carbonyl group. In addition, as a result of the removal of the carbonyl group from conjugation with the catechol ring, the acidity of NAcMECAMS (11) is less than Me₃MECAMS (6). While the estimated log β₁₁₀ is approximately the same as for Me₃MECAMS (40), the effective formation constant (log K*) and pM.(- log [Fe_aq³⁺]) values are lower (4.0 and 25.0, respectively).