Novel Inhibitor for Downstream Targeting of Transforming Growth Factor-β Signaling to Suppress Epithelial to Mesenchymal Transition and Cell Migration

Cancer metastasis accounts for most of the mortality associated with solid tumors. However, antimetastatic drugs are not available on the market. One of the important biological events leading to metastasis is the epithelial to mesenchymal transition (EMT) induced by cytokines, namely transforming growth-factor-β (TGF-β). Although several classes of inhibitors targeting TGF-β and its receptor have been developed, they have shown profound clinical side effects. We focused on our synthetic compound, HPH-15, which has shown anti-fibrotic activity via the blockade of the TGF-β Smad-dependent signaling. In this study, 10 μM of HPH-15 was found to exhibit anti-cell migration and anti-EMT activities in non-small-cell lung cancer (NSCLC) cells. Although higher concentrations are required, the anti-EMT activity of HPH-15 has also been observed in 3D-cultured NSCLC cells. A mechanistic study showed that HPH-15 inhibits downstream TGF-β signaling. This downstream inhibition blocks the expression of cytokines such as TGF-β, leading to the next cycle of Smad-dependent and -independent signaling. HPH-15 has AMPK-activation activity, but a relationship between AMPK activation and anti-EMT/cell migration was not observed. Taken together, HPH-15 may lead to the development of antimetastatic drugs with a new mechanism of action.


Introduction
Although new and effective therapies are constantly being developed for some types of cancers, cancer remains one of the leading causes of death worldwide [1]. The ability of cancer cells to easily metastasize makes cancer treatment particularly difficult. Cancer metastasis is the migration of cancer cells from the primary tumor to distant locations through blood/lymphatic vessels to form new tumors in remote organs [2,3]. Metastasis accounts for more than 90% of the mortality caused by solid tumors [4,5]. Therefore, the molecular mechanism of metastasis has been extensively studied, and the development of anti-metastatic drugs has been attempted [4,5]. However, such drugs are not on the market yet.
The events of cancer metastasis are complex. One of the important biological events leading to metastasis is the epithelial to mesenchymal transition (EMT) [6,7], in which epithelial cancer cells undergo morphological changes to spindle-like mesenchymal cells with less adhesion between cell-to-cell junctions, ultimately acquiring migratory and invasive capabilities [8]. During EMT, epithelial cells lose their E-cadherin protein localized in the plasma membrane and upregulate the expression of N-cadherin and vimentin. E-cadherin maintains cell adhesion and epithelial structure, while N-cadherin and vimentin increase cell mobility and contribute to the morphological changes of the cell, making them important markers of EMT. EMT is driven by the induction of transcription factors, such as Snail1 and zinc finger E-box binding homeobox 1 (Zeb1) [9,10]. These transcription factors are known to be induced by various cytokines and their downstream signaling depending on the cell type [11].
For example, transforming growth-factor β (TGF-β) is a major inducer of EMT in non-small-cell lung cancer (NSCLC) cells via Smad-dependent and Smad-independent pathways [12,13]. Furthermore, it has been reported that the suppression of these signals inhibits EMT [14,15]. Therefore, TGF-β signaling may be a target of anti-EMT drugs. To date, several classes of inhibitors targeting TGF-β or its receptor have been developed, and some have been clinically tested. Such known agents include TGF-β-neutralizing antibodies, ligand traps that block the interaction between TGF-β and its receptors, and selective small molecules targeting the TGF-β receptor or its kinase inhibitors [16]. One particular example is the low-molecular-weight TGF-β receptor inhibitor, LY3200882, which showed great potential in both in vitro cell models and in vivo animal models [17]. However, as TGF-β has multifaceted functions whose inhibition has led to profound side effects, such inhibitors have not been approved yet [18]. Furthermore, to the best of our knowledge, there are no inhibitors targeting downstream TGF-β signaling.
We previously reported a low-molecular weight compound, HPH-15 ( Figure 1A), which blocked the TGF-β Smad-dependent signaling in dermal fibroblasts and improved skin fibrosis in a mouse model of systemic sclerosis [19]. Here, we report that HPH-15 exerts anti-cell migration and anti-EMT activities in NSCLC cells by downstream targeting of TGF-β signaling, which is a new mechanism as far as we know. molecular mechanism of metastasis has been extensively studied, and the development of anti-metastatic drugs has been attempted [4,5]. However, such drugs are not on the market yet.
The events of cancer metastasis are complex. One of the important biological events leading to metastasis is the epithelial to-mesenchymal transition (EMT) [6,7], in which epithelial cancer cells undergo morphological changes to spindle-like mesenchymal cells with less adhesion between cell-to-cell junctions, ultimately acquiring migratory and invasive capabilities [8]. During EMT, epithelial cells lose their E-cadherin protein localized in the plasma membrane and upregulate the expression of N-cadherin and vimentin. Ecadherin maintains cell adhesion and epithelial structure, while N-cadherin and vimentin increase cell mobility and contribute to the morphological changes of the cell, making them important markers of EMT. EMT is driven by the induction of transcription factors, such as Snail1 and zinc finger E-box binding homeobox 1 (Zeb1) [9,10]. These transcription factors are known to be induced by various cytokines and their downstream signaling depending on the cell type [11].
For example, transforming growth-factor β (TGF-β) is a major inducer of EMT in nonsmall-cell lung cancer (NSCLC) cells via Smad-dependent and Smad-independent pathways [12,13]. Furthermore, it has been reported that the suppression of these signals inhibits EMT [14,15]. Therefore, TGF-β signaling may be a target of anti-EMT drugs. To date, several classes of inhibitors targeting TGF-β or its receptor have been developed, and some have been clinically tested. Such known agents include TGF-β-neutralizing antibodies, ligand traps that block the interaction between TGF-β and its receptors, and selective small molecules targeting the TGF-β receptor or its kinase inhibitors [16]. One particular example is the low-molecular-weight TGF-β receptor inhibitor, LY3200882, which showed great potential in both in vitro cell models and in vivo animal models [17]. However, as TGF-β has multifaceted functions whose inhibition has led to profound side effects, such inhibitors have not been approved yet [18]. Furthermore, to the best of our knowledge, there are no inhibitors targeting downstream TGF-β signaling.
We previously reported a low-molecular weight compound, HPH-15 ( Figure 1A), which blocked the TGF-β Smad-dependent signaling in dermal fibroblasts and improved skin fibrosis in a mouse model of systemic sclerosis [19]. Here, we report that HPH-15 exerts anti-cell migration and anti-EMT activities in NSCLC cells by downstream targeting of TGF-β signaling, which is a new mechanism as far as we know.

Results
The anti-migration activity of HPH-15 was examined using a TGF-β-stimulated NSCLC cell line. HPH-15 was synthesized as previously described [20]. The A549 cell line [21], a widely used NSCLC cell line, was used in this study. Before the assay, the toxicity of HPH-15 in the A549 cells was examined. The cells were incubated with 0.1-50 μM of HPH-15 for 1 or 2 d, and the 3-(4,5-dimethylthiazol-2-yl)-2,5-diphenyltetrazolium bromide (MTT) assay was performed. It was demonstrated that 0.1-10 μM of HPH-15 did not show toxicity in both 1 and 2 d incubation but was toxic at 50 μM of HPH-15 in 2 d incubation ( Figure 1B,C). Then, 1-10 μM of HPH-15 was used to examine its effect on anticell migration activity. The activity was evaluated using an in vitro scratch assay, in which cell migration over 1 d in wound areas of TGF-β-stimulated A549 cells treated with HPH-15 was measured ( Figure 1D). In the presence of TGF-β, the cellular area increased more than in the absence of TGF-β due to cell migration. Nearly 40% of this migration was suppressed by 5 μM of HPH-15, and HPH-15 completely inhibited cell migration at 10 μM.
Next, we examined the anti-EMT activity of HPH-15. It has been reported that TGFβ stimulation induces EMT in A549 cells [22]. A549 cells were incubated with TGF-β and HPH-15 (10 μM) for 3 d, and cell morphology was observed under a microscope. A549 cells normally gathered, and there were almost no spaces inside a cell cluster in the absence of TGF-β ( Figure 2A). When stimulated with TGF-β, the cell morphology changed to a spindle shape, and spaces were observed between cells. In the presence of both TGFβ and HPH-15, the cell changed the morphology to that similar to normal cells without spaces. A549 cells incubated with both TGF-β and HPH-15 were lysed and immunoblot analysis was performed. It was followed by normalization of total proteins to observe the levels of EMT marker proteins ( Figure 2B,C). TGF-β treatment decreased the levels of the epithelial marker E-cadherin and increased those of the mesenchymal markers N-cadherin and vimentin. These changes were suppressed by the HPH-15 treatment. E-cadherin

Results
The anti-migration activity of HPH-15 was examined using a TGF-β-stimulated NSCLC cell line. HPH-15 was synthesized as previously described [20]. The A549 cell line [21], a widely used NSCLC cell line, was used in this study. Before the assay, the toxicity of HPH-15 in the A549 cells was examined. The cells were incubated with 0.1-50 µM of HPH-15 for 1 or 2 d, and the 3-(4,5-dimethylthiazol-2-yl)-2,5-diphenyltetrazolium bromide (MTT) assay was performed. It was demonstrated that 0.1-10 µM of HPH-15 did not show toxicity in both 1 and 2 d incubation but was toxic at 50 µM of HPH-15 in 2 d incubation ( Figure 1B,C). Then, 1-10 µM of HPH-15 was used to examine its effect on anti-cell migration activity. The activity was evaluated using an in vitro scratch assay, in which cell migration over 1 d in wound areas of TGF-β-stimulated A549 cells treated with HPH-15 was measured ( Figure 1D). In the presence of TGF-β, the cellular area increased more than in the absence of TGF-β due to cell migration. Nearly 40% of this migration was suppressed by 5 µM of HPH-15, and HPH-15 completely inhibited cell migration at 10 µM.
Next, we examined the anti-EMT activity of HPH-15. It has been reported that TGF-β stimulation induces EMT in A549 cells [22]. A549 cells were incubated with TGF-β and HPH-15 (10 µM) for 3 d, and cell morphology was observed under a microscope. A549 cells normally gathered, and there were almost no spaces inside a cell cluster in the absence of TGF-β ( Figure 2A). When stimulated with TGF-β, the cell morphology changed to a spindle shape, and spaces were observed between cells. In the presence of both TGF-β and HPH-15, the cell changed the morphology to that similar to normal cells without spaces. A549 cells incubated with both TGF-β and HPH-15 were lysed and immunoblot analysis was performed. It was followed by normalization of total proteins to observe the levels of EMT marker proteins ( Figure 2B,C). TGF-β treatment decreased the levels of the epithelial marker E-cadherin and increased those of the mesenchymal markers N-cadherin and vimentin. These changes were suppressed by the HPH-15 treatment. E-cadherin and vimentin protein levels in these cells were also observed by immunostaining. E-cadherin and vimentin were normally localized in the membrane and cytoplasm, respectively ( Figure 2D). In the presence of TGF-β and both TGF-β and HPH-15, the same relative amounts of protein as seen in Figure 2B,C were observed. Furthermore, vimentin expression spread in the spindle-shaped area with TGF-β. Next, the mRNA levels of the marker proteins in the cells were examined. After A549 cells were incubated with TGF-β and HPH-15 (10 µM) for 1 d, RNA was extracted, and RT-PCR was performed ( Figure 2E). The results showed that TGF-β inhibited the transcription of E-cadherin and enhanced the transcription of N-cadherin and vimentin. Then, HPH-15 suppressed the effects of TGF-β. These results demonstrate that 10 µM of HPH-15 has inhibitory activity against TGF-β-induced EMT. 022, 23, x FOR PEER REVIEW 4 of 17 proteins in the cells were examined. After A549 cells were incubated with TGF-β and HPH-15 (10 μM) for 1 d, RNA was extracted, and RT-PCR was performed ( Figure 2E). The results showed that TGF-β inhibited the transcription of E-cadherin and enhanced the transcription of N-cadherin and vimentin. Then, HPH-15 suppressed the effects of TGFβ. These results demonstrate that 10 μM of HPH-15 has inhibitory activity against TGF-βinduced EMT. Recently, three-dimension (3D)-cultured cells have been used in cancer studies because tumors are 3D structures in vivo. Microwells were fabricated, and A549 cells were cultured for 2 d in each microwell. To demonstrate that A549 spheroids formed, the mor- Recently, three-dimension (3D)-cultured cells have been used in cancer studies because tumors are 3D structures in vivo. Microwells were fabricated, and A549 cells were cultured for 2 d in each microwell. To demonstrate that A549 spheroids formed, the morphology of the cells was observed under a microscope, and their hypoxia status was determined using a chemical probe [23] ( Figure 3A). The spheroid was incubated with TGF-β and 10-50 µM of HPH-15 for 1 d. RNA was extracted from the spheroid, and RT-PCR was performed to determine the mRNA levels of EMT marker proteins. As shown in Figure 3B, 10 ng/mL TGF-β suppressed the mRNA level of E-cadherin and increased those of N-cadherin and vimentin, like that observed in Figure 2E. However, in the spheroid, 10 and 20 µM of HPH-15 did not show clear anti-EMT activity, while it was able to inhibit EMT at 50 µM. Notably, 50 µM of HPH-15 was not toxic against normally cultured A549 ( Figure 1B) in 1 d incubation. Furthermore, the amounts of mRNA shown in Figure 3B are the value normalized by that of GAPDH. Thus, the effect of HPH-15 at 50 µM is considered to be unrelated to its toxicity. A higher concentration of HPH-15 was required in 3D-cultured cells than in normal 2D-cultured cells.
These results show that HPH-15 activates AMPK, and the activation is not a cause of its anti-EMT and anti-cell migration properties.  Next, we examined whether HPH-15 exerts its anti-EMT activity via Smad-dependent pathways. First, the transcription from the Smad-binding element (SBE) was examined by a reporter assay using a pGL4.48[luc2P/SBE/Hygro] vector (which has SBE fused to a downstream firefly luciferase gene) and pRL-Luc vector (which carries a β-actin promoter fused to a downstream Renilla luciferase gene, which served as an internal control). Cultured A549 cells were co-transfected with these vectors and incubated for 16 h. The cells were then further incubated for 8 h with TGF-β and HPH-15 (10 µM) before a luciferase assay was performed. TGF-β enhanced Smad-dependent transcription, which was inhibited by HPH-15 ( Figure 4A). Next, the phosphorylation of Smad2 and Smad3, which plays important roles in Smad-dependent signaling, was examined. After incubation of A549 cells for 1 d with TGF-β and HPH-15 (10 µM), the cells were lysed, and immunoblotting was performed ( Figure 4B,C). Without TGF-β, definite phosphorylation of Smad2 and Smad3 was not observed. Upon TGF-β stimulation, both proteins were phosphorylated; upon HPH-15 treatment, the amount of phosphorylated protein was reduced by half. Notably, the levels of Smad2 and Smad3 did not change in the presence of TGF-β or HPH-15. To gain insight into the mechanism of the inhibitory activity of HPH-15, the time course of Smad2/3 phosphorylation was examined. At 2 h post-stimulation with TGF-β, phosphorylation of Smad2 and Smad3 began, and phosphorylation continued up to 8 h ( Figure 4D). Smad-dependent signaling is known to express cytokines such as TGF-β that continue to stimulate this signaling, thereby maintaining the transduction of this signaling [24]. Phosphorylation was inhibited throughout this time course in the presence of the TGF-β receptor inhibitor SB525334 [25]. In contrast, while treatment with HPH-15 did not inhibit phosphorylation at 2 h post-stimulation, and inhibition was eventually observed after 4 h. These results suggest that HPH-15 does not directly affect Smad-dependent signaling and inhibits the downstream event of the signaling. In fact, mRNA of TGF-β expressed by TGF-β was suppressed by HPH-15 at 4 and 24 h post-stimulation ( Figure 4E).    Next, we examined the Smad-independent pathway [12,13]. Similar to the experiment to observe the Smad-dependent pathway ( Figure 4B), the phosphorylation of Akt and extracellular signal-regulated kinase (ERK) was examined ( Figure 5A,B). Upon TGF-β stimulation, phospho-Akt increased, and virtually no phosphorylated ERK was phosphorylated. HPH-15 inhibited the phosphorylation caused by stimulation. The amounts of Akt and ERK did not change with TGF-β/HPH-15 treatment.  Finally, we focused on the other signaling protein adenosine monophosphate-activated protein kinase (AMPK), since it has been reported that AMPK activation inhibits EMT and cell migration [26]. The effect of HPH-15 on AMPK phosphorylation was examined. A549 cells were incubated for 1 or 3 d with TGF-β and HPH-15 (10 µM) before being lysed to perform immunoblotting ( Figure 6A). Interestingly, AMPK was phosphorylated in the presence of HPH-15. AMPK was then knocked down using siRNA ( Figure 6B), and the inhibitory activity of HPH-15 on cell migration was examined as described in Figure 1C. Treatment with HPH-15 showed the same anti-cell migration activity as in both A549 and AMPK-knockdown cells ( Figure 6C). Furthermore, immunoblot analysis using these two cell lines showed similar anti-EMT activity to those treated with HPH-15 ( Figure 6D). These results show that HPH-15 activates AMPK, and the activation is not a cause of its anti-EMT and anti-cell migration properties.

Discussion
Previously, we reported a compound named SN-1, which has a cysteamine-pyridinecysteamine structure that binds to the zinc sites of proteins [27][28][29]. Furthermore, we attempted extensive structural modifications by removing and/or introducing substituents [20,[30][31][32][33], and achieved improved zinc protein selectivity. HPH-15 is one of them, and we first reported it as an anti-herpes virus compound [20] (note that "HPH-8" in reference [20] was later renamed "HPH-15" when the anti-fibrosis activity of HPH-15 was found [19]). While we classify HPH-15 as one of our metal-binding compounds, the metal binding property seems minimal due to the bulky tert-butyl groups. The biological activity of HPH-15 is not directly related to metal binding.
In this study, we focused on the ability of HPH-15 to block the TGF-β Smad-dependent signaling and investigated its anti-cell migration activity. As expected, 10 µM of HPH-15 showed inhibitory activity against TGF-β-driven EMT and cell migration in NSCLC cells. Lung cancer is one of the leading causes of cancer-associated deaths [1], and NSCLC is the most common lung malignancy [34]. Many patients with lung cancer are diagnosed at an advanced stage, and the prognosis of these patients remains very poor owing to early cancer metastasis [34,35]. In many cases, NSCLC metastasizes to the brain to develop brain tumors, which reduces the quality of life of the patients [36].
Mechanistic studies showed that HPH-15 inhibited downstream TGF-β signaling ( Figure 4D). This downstream inhibition blocks the expression of cytokines such as TGF-β ( Figure 4E) that lead to the next cycle of Smad-dependent and Smad-independent signaling. The action mechanism of HPH-15 to inhibit EMT proposed in this study is shown in Figure 7. TGF-β inhibitors are expected to be effective drugs against cancer-related diseases, and various inhibitors targeting TGF-β or its receptor have been developed [16]. However, side effects were observed, and clinical tests failed [18]. The toxicity is caused by the multifaceted functions of TGF-β. As far as TGF-β inhibitors go, the mechanism of inhibition by HPH-15 identified in this study is new, and fewer side effects than those observed from inhibitors targeting the TGF-β receptor are expected.

Discussion
Previously, we reported a compound named SN-1, which has a cysteamine-pyridine-cysteamine structure that binds to the zinc sites of proteins [27][28][29]. Furthermore, we attempted extensive structural modifications by removing and/or introducing substituents [20,[30][31][32][33], and achieved improved zinc protein selectivity. HPH-15 is one of them, and we first reported it as an anti-herpes virus compound [20] (note that "HPH-8" in reference 20 was later renamed "HPH-15" when the anti-fibrosis activity of HPH-15 was found [19]). While we classify HPH-15 as one of our metal-binding compounds, the metal binding property seems minimal due to the bulky tert-butyl groups. The biological activity of HPH-15 is not directly related to metal binding.
In this study, we focused on the ability of HPH-15 to block the TGF-β Smad-dependent signaling and investigated its anti-cell migration activity. As expected, 10 μM of HPH-15 showed inhibitory activity against TGF-β-driven EMT and cell migration in NSCLC cells. Lung cancer is one of the leading causes of cancer-associated deaths [1], and NSCLC is the most common lung malignancy [34]. Many patients with lung cancer are diagnosed at an advanced stage, and the prognosis of these patients remains very poor owing to early cancer metastasis [34,35]. In many cases, NSCLC metastasizes to the brain to develop brain tumors, which reduces the quality of life of the patients [36].
Mechanistic studies showed that HPH-15 inhibited downstream TGF-β signaling ( Figure 4D). This downstream inhibition blocks the expression of cytokines such as TGFβ ( Figure 4E) that lead to the next cycle of Smad-dependent and Smad-independent signaling. The action mechanism of HPH-15 to inhibit EMT proposed in this study is shown in Figure 7. TGF-β inhibitors are expected to be effective drugs against cancer-related diseases, and various inhibitors targeting TGF-β or its receptor have been developed [16]. However, side effects were observed, and clinical tests failed [18]. The toxicity is caused by the multifaceted functions of TGF-β. As far as TGF-β inhibitors go, the mechanism of inhibition by HPH-15 identified in this study is new, and fewer side effects than those observed from inhibitors targeting the TGF-β receptor are expected. It is still unclear what the direct target of HPH-15 is and how it leads to the inhibition of TGF-β signaling. Its anti-cell migration and anti-EMT properties were unrelated to AMPK activation activity. While research into the mechanism is ongoing, this study gives It is still unclear what the direct target of HPH-15 is and how it leads to the inhibition of TGF-β signaling. Its anti-cell migration and anti-EMT properties were unrelated to AMPK activation activity. While research into the mechanism is ongoing, this study gives us insight into how to develop it into a clinically used anti-metastatic drug. Furthermore, the weaker activity seen in 3D-cultured cells (Figure 3) should be improved. Resistance of 3D-cultured cells to various drugs has been reported [37], and it could be caused by enhancement of drug efflux [38] and/or difficulty of drugs in entering a cell which tightly interacts with adjacent cells. The activity of HPH-15 against 3D-cultured cells may be improved by drug-delivery tactics. This study could lead to the development of new antimetastatic drugs for NSCLC and other cancers.

Chemicals and a Cytokine
HPH-15 was synthesized as previously reported [20] and SB525334 was purchased from Selleck Biotech (Tokyo, Japan). Each compound was dissolved in dimethyl sulfoxide (DMSO) (FUJIFILM-Wako, Osaka, Japan) and the solution was added to the cell-culture medium at a 1:100 volume. TGF-β1 was purchased from R&D Systems (Minneapolis, MN, USA), and used as TGF-β. TGF-β was added to the cell culture medium, followed by the addition of a compound before incubation continued for 1 h.

Generation of Cancer Spheroids and Hypoxia Assay
The spheroid culture microwells were fabricated by photolithography of SU-8 (KAYAKU Advanced Materials, Westborough, MA, USA) on a coverslip. The device consists of eightyfive microwells with a diameter of 400 µm and a depth of 200 µm. The bottom of each microwell was coated with Prevelex CC1 (Nissan Chemical, Tokyo, Japan). A549 cells (1.0 × 10 6 cells/mL/well) were seeded in spheroid culture microwells. After incubation for 2 d, an A549 spheroid was formed in each well. The spheroids were incubated with a hypoxia chemical probe LOX-1 (1 µM) (SCIVAX Life Sciences, Tokyo, Japan) for 16 h to analyze their hypoxic status. Fluorescence generated from LOX-1 and spheroid morphology was observed using a BIOREVO BZ-9000 (Keyence).

Protein Knockdown
To knock down AMPK in A549 cells, AMPKα1/2 siRNA (h) (Santa Cruz, Dallas, TX, USA) was transfected into cells using Lipofectamine 3000 (Thermo Fisher Scientific, Waltham, MA, USA). Control siRNA-A (Santa Cruz Biotechnology) was used as a control siRNA. After transfection with siRNA, the cells were incubated for 1 d and used for subsequent experiments.

In Vitro Scratch Assay
The assay was conducted as described previously, in which cell migration for 1 d in wound areas of TGF-β-stimulated A549 cells, prepared by scraping with a 200 µL pipette tip, was measured [40]. The only difference was that an FBS-free medium was used.

Immunostaining of Cells
The assay was conducted as described previously [41]. The differences were as follows: the primary antibodies used were an E-cadherin Antibody (H-108) (Santa Cruz) and a Vimentin Antibody (E-5) (Santa Cruz). The secondary antibodies used were a Goat anti-Mouse IgG (H + L) Cross-Adsorbed Secondary Antibody, Alexa Fluor 488 (Thermo Fisher Scientific), and a Goat anti-Rabbit IgG (H + L) Cross-Adsorbed Secondary Antibody, TRITC (Thermo Fisher Scientific). After the reaction with the secondary antibodies, a phosphate-buffered saline (PBS) solution containing 1% Hoechst33342 (Dojindo Laboratories, Kumamoto, Japan) was added to the cells and incubated for 15 min. A Zeiss LSM 700 laser-scanning confocal microscope (Carl Zeiss, Oberkochen, Germany) was used for fluorescence microscopy.

Conclusions
A small molecule, HPH-15, was found to have anti-EMT and anti-cell-migration properties in NSCLC cells. To the best of our knowledge, the mechanism of inhibition downstream of TGF-β signaling is new, although inhibitors targeting the TGF-β receptor or its kinase are known. The elucidation of mechanistic details is ongoing. Cancer metastasis is the main cause of mortality in solid tumors, and anti-metastatic drugs are not yet available. This study could lead to the development of anti-metastasis drugs in the near future.