Katherine L. Seley-Radtke

1-[2-(2-Benzoyl- and 2-benzylphenoxy)ethyl]uracils as potent anti-HIV-1 agents

Abstract Non-nucleoside reverse transcriptase inhibitors (NNRTI) are key components in highly active antiretroviral therapy for treating HIV-1. Herein we present the synthesis for a series of N1-alkylated uracil derivatives bearing ω-(2-benzyl- and 2-benzoylphenoxy)alkyl substituents as novel NNRTIs. These compounds displayed anti-HIV activity similar to that of nevirapine and several of them exhibited activity against the K103N/Y181C RT mutant HIV-1 strain. Further evaluation revealed that the inhibitors were active against most nevirapine-resistant mono- and di-substituted RTs with the exception of the V106A RT. Thus, the candidate compounds can be regarded as potential lead compounds against the wild-type virus and drug-resistant forms.

Antiproliferative activities of halogenated thieno[3,2-d]pyrimidines

The in vitro evaluation of thieno[3,2-d]pyrimidines identified halogenated compounds 1 and 2 with antiproliferative activity against three different cancer cell lines. A structure activity relationship study indicated the necessity of the chlorine at the C4-position for biological activity. The two most active compounds 1 and 2 were found to induce apoptosis in the leukemia L1210 cell line. Additionally, the compounds were screened against a variety of other microbial targets and as a result, selective activity against several fungi was also observed. The synthesis and preliminary biological results are reported herein.

N1,N3-disubstituted uracils as nonnucleoside inhibitors of HIV-1 reverse transcriptase.

Abstract A series of phenyloxyethyl and cinnamyl derivatives of substituted uracils were synthesized and found to exhibit potent activity against HIV-RT and HIV replication in cell culture. In general, the cinnamyl derivatives proved superior to the phenyloxyethyl derivatives, however 1-[2-(4-methylphenoxy)ethyl]-3-(3,5-dimethylbenzyl)uracil (19) exhibited the highest activity (EC50 =0.27μM) thus confirming that the 3-benzyluracil fragment in the NNRTI structure can be regarded as a functional analogue of the benzophenone pharmacophore typically found in NNRTIs.

NMR Studies Reveal an Unexpected Binding Site for a Redox Inhibitor of AP Endonuclease 1

AP endonuclease 1 (APE1) is a multifaceted protein with essential roles in DNA repair and transcriptional regulation. APE1 (ref-1) activates many transcription factors (TF), including AP-1 and NF-κB. While the mechanism of APE1 redox activity remains unknown, it may involve reduction of an oxidized Cys in the TF DNA-binding domain. Several small molecules inhibit APE1-mediated TF activation, including the quinone derivative E3330. It has been proposed some inhibitors bind near C65, a residue suggested to be important for TF activation, but the binding site has not been determined for any inhibitor. Remarkably, NMR and molecular docking studies here reveal E3330 binds in the DNA repair active site of APE1, far removed from C65. Accordingly, AP endonuclease activity is substantially inhibited by E3330 (100 μM), suggesting that E3330 may not selectively inhibit APE1 redox activity in cells, in contrast with previous proposals. A naphthoquinone analogue of E3330, RN7-60, binds a site removed from both C65 and the repair active site. While a detailed understanding of how these inhibitors work requires further studies into the mechanism of redox activity, our results do not support proposals that E3330 binds selectively (and slowly) to locally unfolded APE1 or that E3330 promotes formation of disulfide bonds in APE1. Rather, we suggest E3330 may suppress a conformational change needed for redox activity, disrupt productive APE1-TF binding, or block the proposed redox chaperone activity of APE1. Our results provide the first structural information for any APE1 redox inhibitor and could facilitate development of improved inhibitors for research and perhaps clinical purposes.

1-Benzyl derivatives of 5-(arylamino)uracils as anti-HIV-1 and anti-EBV agents

Pyrimidine analogs have long found use over a broad chemotherapeutic spectrum. In an effort to further explore the antiviral potential of several uracil derivatives previously synthesized in our laboratories, a series of benzylated pyrimidines were designed and synthesized. Introduction of the benzyl residue onto the 5-phenylaminouracil scaffold was carried out using 2,4-bis(trimethylsilyloxy)pyrimidine with the corresponding benzyl bromides. Similarly, 1-benzyl-5-(benzylamino)- and 1-benzyl-5-(phenethylamino)uracils were obtained via amination of 1-benzyl-5-bromouracils with benzylamine or phenylethylamine. The results of the broad screen antiviral studies revealed that compounds 5 and 11 exhibit promising inhibitory activity against HIV-1 in CEM-SS culture. A 50% protective effect was observed at concentrations of 11.9 and 9.5 μМ, respectively. Moreover, compounds 8 and 3 exhibited good inhibitory effects against EBV in АKАТА cell culture with EC₅₀ values of 2.3 and 12 μM, respectively. The synthesis and biological studies are detailed herein.

Design, synthesis and evaluation of a series of acyclic fleximer nucleoside analogues with anti-coronavirus activity

Abstract A series of doubly flexible nucleoside analogues were designed based on the acyclic sugar scaffold of acyclovir and the flex-base moiety found in the fleximers. The target compounds were evaluated for their antiviral potential and found to inhibit several coronaviruses. Significantly, compound 2 displayed selective antiviral activity (CC50 >3× EC50) towards human coronavirus (HCoV)-NL63 and Middle East respiratory syndrome-coronavirus, but not severe acute respiratory syndrome-coronavirus. In the case of HCoV-NL63 the activity was highly promising with an EC50 <10μM and a CC50 >100μM. As such, these doubly flexible nucleoside analogues are viewed as a novel new class of drug candidates with potential for potent inhibition of coronaviruses.

A Computational Study of Expanded Heterocyclic Nucleosides in DNA

Abstract The first molecular dynamics study of a series of heterospacer-expanded tricyclic bases in DNA using modified force field parameters in AMBER is detailed. The expanded purine nucleoside monomers have been designed to probe the effects of a heteroaromatic spacer ring on the structure, function, and dynamics of the DNA helix. The heterobase scaffold has been expanded with a furan, pyrrole, or thiophene spacer ring. This structural modification increases the polarizability of the bases and provides an additional hydrogen bond donor with the amine hydrogen of the pyrrole ring or hydrogen bond acceptor with the furan or thiophene ring free electron pairs. The polarizability of the expanded bases were determined by AM1 calculations and the results of the MD simulations of 20-mers predict that the modified curvature of the expanded base leads to a much larger major groove, while the effect on the minor groove is negligible. Overall, the structure resembles A-DNA. MD simulations of 10-mers suggest that the balance between base pairing vs. base stacking and intercalation can be shifted towards the latter due to the increased surface area and polarizability of the expanded bases.

“Reverse” Carbocyclic Fleximers: Synthesis of a New Class of Adenosine Deaminase Inhibitors

A series of flexible carbocyclic pyrimidine nucleosides has been designed and synthesized. In contrast to previously reported “fleximers” from our laboratory, these analogues have the connectivity of the heterocyclic base system “reversed”, where the pyrimidine ring is attached to the sugar moiety, rather than the five membered imidazole ring. As was previously seen with the ribose fleximers, their inherent flexibility should allow them to adjust to enzyme binding site mutations, as well as increase the affinity for atypical enzymes. Preliminary biological screening has revealed surprising inhibition of adenosine deaminase, despite their lack of resemblance to adenosine.

Synthesis and anti-HCMV activity of 1-[ω-(phenoxy)alkyl]uracil derivatives and analogues thereof

Abstract HCMV infection represents a life-threatening condition for immunocompromised patients and newborn infants and novel anti-HCMV agents are clearly needed. In this regard, a series of 1-[ω-(phenoxy)alkyl]uracil derivatives were synthesized and examined for antiviral properties. Compounds 17, 20, 24 and 28 were found to exhibit highly specific and promising inhibitory activity against HCMV replication in HEL cell cultures with EC50 values within 5.5–12μM range. Further studies should be undertaken to elucidate the mechanism of action of these compounds and the structure–activity relationship for the linker region.

Synthetic Strategies Toward Carbocyclic Purine-Pyrimidine Hybrid Nucleosides

The blending of key structural features from the purine and pyrimidine nucleobase scaffolds gives rise to a new class of hybrid nucleosides. The purine-pyrimidine hybrid nucleosides can be viewed as either N-3 ribosylated purines or 5,6-disubstituted pyrimidines, thus recognition by both purine- and pyrimidine-metabolizing enzymes is possible. Given the increasing reports of the development of resistance in many enzymatic systems, a drug that could be recognized by more than one enzyme could prove highly advantageous in overcoming resistance mechanisms related to binding site mutations. In that regard, the design, synthesis and results of preliminary biological activity for a series of carbocyclic uracil derivatives with either a fused imidazole or thiazole ring are presented herein.