and bleomycin-induced lung fibrosis in mice (Urushiyama et al. 2019). Additionally,
naftopidil also induces G1 cell cycle arrest and decreases the mRNA expression of
COL4A1 (which encodes type IV collagen) and ACTA2 (which encodes α smooth
muscle actin) in human lung fibroblasts. These results suggested that naftopidil may
have potent therapeutic effects on the tumor stroma of PCa, including fibroblasts and
vascular endothelial cells.
Carcinoma-associated fibroblasts (CAFs) are present in the tumor microenviron-
ment of PCa and are characterized as activated fibroblasts that promote PCa cell
proliferation. In the PCa cell microenvironment, normal fibroblasts and CAFs
secrete various growth factors, cytokines, extracellular matrix proteins, and
microRNAs, which function to support PCa cell survival and proliferation in a
paracrine manner (Ishii et al. 2018b). In our laboratory, we examined the effects of
naftopidil on the proliferation of primary cultured CAFs derived from patients with
PCa. Naftopidil weakly inhibited the proliferation of primary cultured CAFs com-
pared with that of PCa cells, normal prostatic fibroblasts, and vascular endothelial
cells (unpublished data; Fig. 8.1). This result may be explained by the slower
proliferation of CAFs compared with that of other cells. Because naftopidil inhibits
cell cycle progression, highly proliferative cells may be strongly affected by
naftopidil in the tumor microenvironment of PCa. Additional work is needed to
fully elucidate the roles of naftopidil in CAFs.
Clinical studies have shown that the incidence of PCa is reduced in patients with
BPH administered with naftopidil for at least 3 months compared with that in
patients administered with tamsulosin (Yamada et al. 2013). Moreover, our DR
studies in patients with latent PCa concomitant with BPH also suggested that
naftopidil may have applications in long-term prevention by blocking progression
to clinical PCa. Thus, long-term naftopidil use for patients with BPH may have
various clinical benefits, and naftopidil may have application in the chemopreven-
tion of PCa in patients with BPH.
8.3.2
New Clinical Applications of Naftopidil in PCa Treatment
Recently, we proposed two possible clinical applications of naftopidil, i.e., in
combination treatment with radiotherapy (RT) or as a chemotherapy for PCa treat-
ment (Iwamoto et al. 2017; Ishii et al. 2018a).
Clinically, α1-AR antagonists, including naftopidil, improve outcomes in patients
with PCa and urinary morbidities related to brachytherapy (Merrick et al. 2005) and
extra beam RT (Prosnitz et al. 1999) without impairing safety. Indeed, additive
naftopidil treatment combined with RT has been shown to increase RT efficacy in
PC-3 cells by directly suppressing growth and by blocking the RT-induced expres-
sion of the antioxidant enzyme manganese superoxide dismutase (Iwamoto et al.
2017). Conversely, additive tamsulosin treatment combined with RT did not exert
these effects.
Additionally, additive naftopidil treatment combined with docetaxel (DTX) was
shown to promote DTX efficacy in LNCaP cell-derived tumors (sub-renal capsule
8
Drug Repositioning of the Phenylpiperazine Derivative Naftopidil in. . .
115