A versatile framework for the design of ligand-dependent, transgene-specific transcription factors.

The ability to regulate transgene expression will be essential for the safety and efficacy of many gene therapies. Various ligand-dependent transcription factors, including steroid hormone receptors, have been modified to enable transgene-specific regulation. To minimize effects on cellular gene expression, chimeric steroid receptors have been constructed by replacing their native DNA binding domain (DBD) with a heterologous DBD, like that from the yeast transcription factor GAL4. This approach has limitations for human gene therapy, including the potential immunogenicity of the GAL4 domain and the inability to discriminate between different GAL4-linked transgenes in the same cell. To address this, we have constructed chimeric regulators containing the human estrogen receptor (ER) ligand binding domain (LBD) and a Cys(2)-His(2)-type zinc finger DBD. Cys(2)-His(2) zinc finger domains are common among human DNA binding proteins and can be engineered to selectively bind different DNA sequences. We demonstrate over 500-fold drug-dependent transgene induction with these chimeric regulators in vitro and the ability to regulate an adenovirus-delivered transgene in mice. Two chimeras containing different Cys(2)-His(2) domains displayed highly sequence-specific binding and regulation. Incorporating a point mutation in the ER LBD that ablates estrogen binding enables selective in vivo regulation with the clinically useful anti-estrogen tamoxifen. These Cys(2)-His(2)-ER LBD chimeras represent a versatile framework for creating transgene-specific regulators potentially useful for human gene therapy applications.

Medetomidine analogs as alpha 2-adrenergic ligands. 3. Synthesis and biological evaluation of a new series of medetomidine analogs and their potential binding interactions with alpha 2-adrenoceptors involving a "methyl pocket".

The synthesis and the biological evaluation of a new series of medetomidine analogs are reported. The substitution pattern at the phenyl ring of the tetralin analogs had a distinct influence on the alpha 2-adrenoceptor binding affinity. 4-Methylindan analog 6 was the most potent alpha 2-adrenoceptor binding ligand among these 4-substituted imidazoles, and its alpha 2-adrenoceptor selectivity was greater than the 5-methyl tetralin analog 4c. Ligand-pharmacophore and receptor modeling were combined to rationalize alpha 2-adrenoceptor binding data of the imidazole analogs in terms of ligand-receptor interactions. The structure-activity relationships that were apparent from this and previous studies were qualitatively rationalized by the binding site models of the alpha 2-adrenoceptor. The benzylic methyl group of medetomidine or the naphthyl analog 2a was superimposable with the alpha-methyl group of (-)-alpha-methylnorepinephrine and fit into the proposed "methyl pocket" of the alpha 2-adrenoceptor defined by the residues Leu110, Leu169, Phe391, and Thr395.

Iodinated analogs of trimetoquinol as highly potent and selective beta 2-adrenoceptor ligands.

A series of trimetoquinol (1, TMQ) analogs were designed and synthesized based on the lead compound 2, a diiodinated analog of trimetoquinol which exhibits improved selectivity for beta 2-versus beta 1-adrenoceptors (AR). To determine the influence of 1-benzyl substituents of trimetoquinol on beta 2-AR binding affinity and selectivity, we replaced and/or removed the 3'-, 4'-, and 5'-methoxy substituents of trimetoquinol. Replacement of the 4'-methoxy group of 2 with an amino (21c) or acetamido (15) moiety did not significantly alter beta 2-AR and thromboxane A2/prostaglandin H2 (TP) receptor affinity. Substitution with a 4'-hydroxy (18) or -iodo (21b) group did not significantly alter beta 2-AR affinity, but greatly reduced TP receptor affinity (380- and 1200-fold, respectively). Further, the beta 2-AR can accommodate larger substituents such as a benzamide at the 4'-position (26b). Other monoiodo derivatives (24, 26a) have similar or slightly lower affinity to both beta 2-AR and TP receptor compared to their diiodo analogs. Interestingly, removal of the 4'-substituent of 3',5'-diiodo analogs increased beta 2-AR affinity with little or no effect on beta 1-AR and TP binding. Thus, analog 21a displayed highly potent (pKi 9.52) and selective (beta 2/beta 1 = 600) binding affinity for beta 2-AR. On the other hand, trifluoromethyl substituents at the 3'- and 5'-positions (27) essentially abolished binding affinity at beta 2-AR and TP receptors. The differential binding effects of the aforementioned trimetoquinol modifications on the receptor systems may reflect differences in the binding pocket that interacts with the benzyl portion of trimetoquinol analogs. Thus, manipulation of the 1-benzyl moiety of trimetoquinol (1) has resulted in analogs that exhibit potent beta 2-AR binding affinity and significantly lower beta 1-AR and TP receptor affinities.