Caleb A. Bates scite author profile

Small molecules that reconstitute the binding mode(s) of a protein and in doing so elicit a programmed functional response offer considerable advantages in the control of complex biological processes. The development challenges of such molecules are significant, however. Many protein-protein interactions require multiple points of contact over relatively large surface areas. More significantly, several binding modes can be superimposed upon a single sequence within a protein, and a true small molecule replacement must be pre-programmed for such multi-modal binding. This is the case for the transcriptional activation domain or TAD of transcriptional activators as these mofifs utilize a poorly characterized multi-partner binding profile in order to stimulate gene expression. Here we describe a unique class of small molecules that exhibit both function and a binding profile analogous to natural transcriptional activation domains. Of particular note, the small molecules are the first reported to bind to the KIX domain within the CREB binding protein (CBP) at a site that is utilized by natural activators. Further, a comparison of functional and non-functional small molecules indicates that an interaction with CBP is a key contributor to transcriptional activity. Taken together, the evidence suggests that the small molecule TADs mimic both the function and mechanism of their natural counterparts and thus present a framework for the broader development of small molecule transcriptional switches.Transcriptional activators are essential for high fidelity transcription, responsible for seeking out particular genes and up-regulating them to precise levels in a signal-responsive fashion.(1,2) Indeed, the altered transcription patterns observed in disease states can often be attributed to malfunctioning and/or mis-regulated transcriptional activators.(3-6) Alterations in the function of the tumor suppressor p53, for example, are found in >50% of all human cancers; (7,8) similarly, constitutively active NF-κB, an activator that regulates genes responsible for apoptosis, inflammatory response, and proliferation, is observed in inflammatory disorders and most cancers.(9,10) There is thus tremendous interest in the development of activator artificial transcription factors (activator ATFs), nonnatural molecules programmed to perform the same function as endogenous activators, as both mechanistic tools and as transcription-targeted therapeutic agents. (2,(11)(12)(13)(14) The architecture of activator ATFs is analogous to that of their natural counterparts in that they minimally consist of a DNA binding domain (DBD) that confers gene-targeting specificity and a transcriptional activation domain (TAD) that controls *Corresponding author, amapp@umich.edu.. The challenges associated with small molecule TAD discovery are due in large part to the scarcity of molecular-level details regarding natural TAD function. The largest and most well studied class of activators is the amphipathic class, characterized by interspersed polar a...

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Over-expression, Purification, and Characterization of Recombinant Human Arylamine N-Acetyltransferase 1

Wang

Vath

Kawamura

et al. 2005

Protein J

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Human arylamine N-acetyltransferase 1 (NAT1) has been overexpressed in E. coli as a mutant dihydrofolic acid reductase (DHFR) fusion protein with a thrombin sensitive linker. An initial DEAE anion-exchange chromatography resulted in partial purification of the fusion protein. The fusion protein was cleaved with thrombin, and human rNAT1 was purified with a second DEAE column. A total of 8 mg of human rNAT1 from 2 1 of cell culture was purified to homogeneity with this methodology. Arylamine substrate specificities were determined for human rNATI and hamster rNAT2. With both NATs, the second order rate constants (k(cat)/ Kmb) for p-aminobenzoic acid (PABA) and 2-aminofluorene (2-AF) were several thousand-fold higher than those for procainamide (PA), consistent with the expected substrate specificities of the enzymes. However, p-aminosalicylic acid (PAS), previously reported to be a human NAT1 and hamster NAT2 selective substrate, exhibits 20-fold higher specificity for hamster rNAT2 (k(cat)/Kmb 3410 microM(-1) s(-1)) than for human rNAT1 (k(cat)/Kmb 169.4 microM(-1) s(-1)). p-aminobenzoyl-glutamic acid (pABglu) was acetylated 10-fold more efficiently by human rNAT1 than by hamster rNAT2. Inhibition studies of human rNAT1 and hamster rNAT2 revealed that folic acid and methotrexate (MTX) are competitive inhibitors of both the unacetylated and acetylated forms of the enzymes, with K(I) values in 50 - 300 micro range. Dihydrofolic acid (DHF) was a much poorer inhibitor of human rNAT1 than of hamster rNAT2. The combined results demonstrate that human rNAT1 and hamster rNAT2 have similar but distinct kinetic properties with certain substrates, and suggest that folic acid, at least in the non-polyglutamate form, may not have an effect on human NAT1 activity in vivo.

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Transcriptional tools: Small molecules for modulating CBP KIX‐dependent transcriptional activators

2010

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Previously it was demonstrated that amphipathic isoxazolidines are able to functionally replace the transcriptional activation domains of endogenous transcriptional activators. In addition, in vitro binding studies suggested that a key binding partner of these molecules is the Creb Binding Protein (CBP), more specifically the KIX domain with this protein. Here we show that CBP and the KIX domain play an essential role in the ability of isoxazolidine transcriptional activation domains to activate transcription in cells. Consistent with this model, isoxazolidines are able to function as competitive inhibitors of the activators MLL and Jun, both of which utilize a binding interaction with KIX to up-regulate transcription. Further, modification of the N2 side chain produced two analogs with enhanced potency against Jun-mediated transcription, although increased cytotoxicity was also observed. Collectively these small KIX-binding molecules will be useful tools for dissecting the role of the KIX domain in a variety of pathological processes.

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Caleb A. Bates

Amphipathic Small Molecules Mimic the Binding Mode and Function of Endogenous Transcription Factors

Over-expression, Purification, and Characterization of Recombinant Human Arylamine N-Acetyltransferase 1

Transcriptional tools: Small molecules for modulating CBP KIX‐dependent transcriptional activators

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