structure, did not induce G1 cell cycle arrest. These reports led us to hypothesize that
α1-AR antagonists with a phenylpiperazine-based structure may suppress the prolif-
eration of cancer cells and stromal cells by inducing G1 cell cycle arrest.
In studies evaluating the mechanisms of growth inhibition by phenylpiperazine
derivatives, including naftopidil, Ishii and Sugimura demonstrated that naftopidil
can bind directly to tubulins and that three phenylpiperazine derivatives, i.e.,
naftopidil, RS100329, and BMY7378, inhibit the polymerization of tubulin; indeed,
the
phenylpiperazine-based
structure
of
these
derivatives
shows
tubulin
polymerization-inhibitory activity (Ishii and Sugimura 2015). These findings sug-
gest that the chemical structures of α1-AR antagonists contribute to differences in the
growth inhibitory mechanisms of these compounds.
In a comparison of the growth inhibitory effects of the three phenylpiperazine
derivatives, researchers have shown that the characteristics of the compound
strongly depend on the substituent group. Our studies of DR suggest that the existing
tubulin-binding drug naftopidil may exert a broad-spectrum cellular cytotoxicity in
various cell types. For example, naftopidil inhibits the proliferation of cancer cells,
such as PCa cells, RCC cells, and colon adenocarcinoma cells, as well as stromal
cells, such as fibroblasts, CAFs, and vascular endothelial cells. Therefore, modifica-
tion of the substituent group on naftopidil may facilitate the design and synthesis of
novel tubulin-binding drugs.
After we reported that the phenylpiperazine derivative naftopidil could act as a
tubulin-binding drug (Ishii and Sugimura 2015), several groups designed and
synthesized new phenylpiperazine derivatives having antiproliferative effects (Guo
et al. 2015; Prinz et al. 2017; Demirci et al. 2019). Particularly, Prinz et al. focused
on the phenylpiperazine-based structure and developed a new tubulin polymeriza-
tion inhibitor (Prinz et al. 2017). Thus, developing potent naftopidil-based anticancer
drugs without compromising safety in patients with PCa is possible.
8.4
Concluding Remarks
Clinically, naftopidil has high tolerability with fewer side effects in patients with
BPH. Our studies of DR imply that naftopidil-inhibited cell cycle progression may
block the progression of latent PCa concomitant with BPH to clinical PCa. We
believe that long-term orally active naftopidil may have clinical benefits in patients
with BPH as a chemopreventive agent for PCa during BPH treatment.
Acknowledgments We would like to thank Drs. Hideki Kanda, Yasuhide Hori, and Yoichi
Iwamoto for their assistance during the experiments and Mrs. Izumi Matsuoka and Ms. Yumi
Yoshikawa for the technical support.
8
Drug Repositioning of the Phenylpiperazine Derivative Naftopidil in. . .
117