Triggering the Antitumor Activity of Acyclic Enediyne through Maleimide-Assisted Rearrangement and Cycloaromatization

Zhang, Mengsi; Li, Baojun; Chen, Huimin; Lü, Haojie; Ma, Hailong; Cheng, Xiaoyu; Wang, Wenbo; Wang, Yue; Ding, Yun; Hu, Aiguo

doi:10.1021/acs.joc.0c01124

Cited by 20 publications

(41 citation statements)

References 74 publications

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“…[12] Recently, we uncovered a new mechanism named as maleimide-assisted rearrangement and cycloaromatization (MARACA) to trigger the antitumor activity of acyclic enediynes through the facilitated tautomerization of enediyne to enyne-allene and the generation of radical species under physiological conditions. [13] We also found that the phenyl radical formed from MSC could underwent 5-endo ring closure to form a stable product, suggesting the presence of different pathways of the diradical intermediates beside hydrogen-abstracting reactions. Along the same line, we designed enediyne 1 with acid-labile protecting groups which could be converted to enyne-allene 2 and 3 in the present of trifluoroacetic acid (TFA) at 0°C (Scheme 1).…”

Section: Introductionmentioning

confidence: 69%

“…The reactants were chosen to be AI and BI in Figure 2 (similar to compound 2 and 3 albeit with the benzyl group at the maleimide moiety being replaced with methyl group to reduce calculation burden). The previous reports from our group and other groups had demonstrated that such a computational setup was suitable for enediyne systems [8f,13–14,20] . Unrestricted DFT method together with broken symmetry ansatz was employed in the structure optimizations of transition states in MSC and the resulted diradical products.…”

Section: Resultsmentioning

confidence: 99%

“…Our group has been dedicated to design and study maleimide‐based enediynes for antitumor applications [12] . Recently, we uncovered a new mechanism named as maleimide‐assisted rearrangement and cycloaromatization (MARACA) to trigger the antitumor activity of acyclic enediynes through the facilitated tautomerization of enediyne to enyne‐allene and the generation of radical species under physiological conditions [13] . We also found that the phenyl radical formed from MSC could underwent 5‐endo ring closure to form a stable product, suggesting the presence of different pathways of the diradical intermediates beside hydrogen‐abstracting reactions.…”

Section: Introductionmentioning

confidence: 97%

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Experimental and Computational Study on the Reaction Pathways of Diradical Intermediates Formed from Myers‐Saito Cyclization of Maleimide‐Based Enediynes

Lü

Zhang

et al. 2020

Asian J Org Chem

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Great efforts have been dedicated to studying the thermal-induced Myers-Saito cyclization (MSC) of enyneallene as the resulting diradicals hold significant potential in various fields, especially in antitumor applications. Besides abstracting hydrogen from DNA backbone and further inducing tumor cell death, the diradicals might react through multiple pathways and lose their efficiency in antitumor applications. The in-depth understanding of the reaction pattern of these highly reactive diradical intermediates will provide clear guidelines for the design of new enyne-allene with high antitumor potency. Herein, we report detailed studies to reveal the reaction mechanism of ketal-conjugated enediynes, which are hydrolyzed and tautomerized into enyne-allene structures in acidic condition and produce diradicals through MSC. Further 1,3-hydrogen atom transfer (HAT)/6-endo cyclization to yield pyran-type product or 5endo cyclization/1,4-HAT to yield furan-type product were confirmed and rationalized through computational studies. The proposed reaction pathways were further verified with deuterium labeling experiments. Based on these new findings, a new enediyne with asymmetric structure and tertbutyl group to block the HAT process was synthesized, which demonstrated much higher cytotoxicity against the HeLa cell line with a half inhibition concentration (IC 50 value) down to submicromolar level.

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Section: Introductionmentioning

confidence: 69%

Section: Resultsmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 97%

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Experimental and Computational Study on the Reaction Pathways of Diradical Intermediates Formed from Myers‐Saito Cyclization of Maleimide‐Based Enediynes

Lü

Zhang

et al. 2020

Asian J Org Chem

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“…Compound 3 has two phenylethynyl groups at the ortho positions of benzene. It is known that an enediyne moiety is capable of inducing Bergman‐type cyclization, 21,22 causing irreversible double‐stranded DNA scission, when the distance between two triple bonds is smaller than 3.4 Å. However, compound 3 , with a diyne structure, did not significantly inhibit E. coli growth; neither did compound 4 , with two phenylethynyl groups at the para positions, nor compound 5 , with no central benzene ring, significantly inhibited E. coli growth at all.…”

Section: Figurementioning

confidence: 98%

Discotic material hexakis(4‐carboxyphenylethynyl)benzene inhibits Escherichia coli growth via the glycolysis pathway

Chen

Hsu

et al. 2021

J Chinese Chemical Soc

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Discotic materials and nanoparticles are potential carriers of synthetic chemicals to increase the bioavailability. Several planar discotic compounds were prepared with C–C bond formation by the Sonagoshira reaction. Their toxicity was based on their inhibition of Escherichia coli growth as well as a simple proteomic analysis. The partial analogues of hexakis(4‐carboxyphenylethynyl)benzene structures did not inhibit E. coli growth significantly. The possible metabolic pathway of hexakis(4‐carboxyphenylethynyl)benzene (1) may involve the downregulation of glycolytic proteins detected with a proteomic analysis. Hexakis(4‐carboxyphenylethynyl)benzene is found not only useful in liquid crystals but may also have utility in the development of novel antibiotics.

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“…[27] Following this line, a new mechanism named as maleimide-assisted rearrangement and cycloaromatization (MARACA) to trigger the antitumor potency of enediynes was proposed recently. [28] Moreover, the interception pathways by intramolecular hydrogen atom transfer (HAT) with regard to highly reactive diradicals generated through MARACA have been uncovered, [29] which clearly indicated that the intramolecular HAT pathways to consume the diradical species have posed a challenge to further boost their biological activity unless the enediyne molecules are elaborately designed. On the other hand, because of the involvement of the essential MSC step in the MARACA mechanism, the dual reactivity of the intermediates from cycloaromatization is expected to show up.…”

Section: Introductionmentioning

confidence: 99%

Nucleophilic Addition to Diradicals Derived From Cycloaromatization of Maleimide‐Based Enediynes

Zhang

et al. 2021

Asian J Org Chem

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Diradical chemistry, typified by the cycloaromatization of enediynes or enyne-allenes, have been extensively explored due to the involved intriguing biological activity and unique mechanistic actions. Because of the essential Myers-Saito cycloaromatization involved in the maleimideassisted rearrangement and cycloaromatization (MARACA) mechanism disclosed in our recent work, the important object of diradical/zwitterion dichotomy and the reactivity of thermally induced σ,π-diradicals were investigated in this work through the combination of experimental and computational studies. Deuterium incorporation experiments demonstrated that the polar product was afforded from the MARACA strategy, in which the diradical and zwitterion reactivities from the cycloaromatization step could both lead to the closed-shell product via the subsequent nucleophilic addition reaction and protonation. Using the density functional theory calculations, the unusual reactivity of the heterosymmetric diradicals to closed-shell zwitterions was examined, and the addition of carbonyl moiety to α,3dehydrotoluene was allowed to occur via a nonplanar cyclic allene transition structure with a small barrier of 9.1 kcal/mol. The observed nonplanar geometry is essential for the necessarily symmetry-breaking action, resulted in the continuous transformation from open-shell diradical to closed-shell zwitterion species during the addition process.

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Triggering the Antitumor Activity of Acyclic Enediyne through Maleimide-Assisted Rearrangement and Cycloaromatization

Cited by 20 publications

References 74 publications

Experimental and Computational Study on the Reaction Pathways of Diradical Intermediates Formed from Myers‐Saito Cyclization of Maleimide‐Based Enediynes

Experimental and Computational Study on the Reaction Pathways of Diradical Intermediates Formed from Myers‐Saito Cyclization of Maleimide‐Based Enediynes

Discotic material hexakis(4‐carboxyphenylethynyl)benzene inhibits Escherichia coli growth via the glycolysis pathway

Nucleophilic Addition to Diradicals Derived From Cycloaromatization of Maleimide‐Based Enediynes

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