Nicotinamide Phosphoribosyltransferase (NAMPT) Is a New Target of Antitumor Agent Chidamide
ABSTRACT: Chidamide is a histone deacetylase (HDAC) inhibitor that is currently used to treat cutaneous T-cell lymphoma in clinic. Herein nicotinamide phosphoribosyltransferase (NAMPT) was identified to be a new target of chidamide on the basis of the pharmacophore analysis, molecular docking, biological assays, inhibitor design, and structure−activity relationship study. The polypharmacology of chidamide will provide important information for better understanding its antitumor mechanism. Also, design of dual NAMPT/HDAC inhibitors may serve as an effective strategy to develop novel antitumor agents.
The balance between acetylation and deacetylation of histone plays an essential role in maintaining cell homeostasis.1 These two processes are regulated by histone acetyltransferase (HAT) and histone deacetylase (HDAC) which increases and decreases gene transcription, respectively.2 It has been reported that HDAC is overexpressed in various tumor cells.3,4 HDAC inhibitors (Figure 1) can decrease the acetylation level to modify the gene expression and induce death of cancer cells.5 HDAC inhibitors (e.g., vorinostat, romidepsin, belinostat, and panobinostat) have been widely used in the clinic for the treatment of cutaneous T-cell lymphoma and multiple myeloma.6−8 Chidamide (1) is abenzamide HDAC inhibitor, which was marketed in China forthe treatment of cutaneous T-cell lymphoma in 2015.9 Chidamide showed good inhibitory activity against class I (HDAC1−3) and class IIb HDACs (HDAC10), whereas it was poorly effective toward other class I, IIa, and IV HDAC isoforms.10 Although its antitumor potency and antitumor mechanism have been widely investigated,11−14 the research for target profiling of chidamide is still rare, which limits deeper understanding its antitumor mechanism.Nicotinamide adenine dinucleotide (NAD+) plays an essential role in cellular physiological processes.15 There are four synthetic routes of NAD+, including the de novo pathwaysynthesized from tryptophan (Trp), the alternative salvage pathway synthesized from nicotinic acid (NA) or nicotinamide ribose (NR), and the primary salvage pathway synthesized from nicotinamide (NAM). In mammalian cells, NAD+ relies on the primary salvage pathway using NAM as the precursor, in which nicotinamide phosphoribosyltransferase (NAMPT) is the rate-limiting enzyme16 (Figure 1A). Recently, NAMPT is recognized as a promising target for the development of novel antitumor agents.
Although two NAMPT inhibitors (FK866 and CHS828) have been progressed into clinical trials for treatment of cutaneous T-cell lymphoma and metastatic melanoma.17 However, further drug development was hampered due to significant side effects, which inspired the discovery of novel NAMPT inhibitors. Previously, we identified a series of new NAMPT inhibitors through high-throughput screening.18−20 Moreover, novel NAMPT/HDAC dual inhibitors were rationally designed on the basis of the synergistic effects between NAMPT and HDAC, which showed excellent in vitro and in vivo antitumor efficacy toward human colon cancer cell HCT116.21 Herein NAMPT wasproven to be a new target of chidamide by pharmacophore analysis, molecular docking, inhibitor design, and biological assays, which provided new insights for the antitumor mechanism of chidamide and important information for new antitumor drug development.The pharmacophore of HDAC inhibitors consists of three parts (Figure 1B): cap, linker, and zinc binding region (ZBG, hydroxamic acid or o-phenylenediamine).22 Similar to HDAC inhibitors, the pharmacophore of NAMPT inhibitors also includes cap, linker, and hydrophobic tails (Figure 1C). For chidamide, its (E)-3-(pyridin-3-yl)acrylamide ZBG could be regarded as a bioisostere of the hydrophobic tail in NAMPT inhibitors. Thus, we envisioned that chidamide might be a NAMPT inhibitor.To validate the hypothesis, molecular docking was initially carried out to investigate whether chidamide shares a similar binding mode to NAMPT inhibitors.
Chidamide was docked into the active site of NAMPT (PDB code 2GVJ)23 using docking software Gold.24 The results showed that chidamide bound to the same pocket of FK866 in the active site of NAMPT (Figure 2). As shown in Figure 2A, the pyridyl group of chidamide formed face to face π−π interactions with TYR18, PHE193, and ARG311, respectively, which were similar to that of FK866. The carbonyl oxygen and nitrogen atom of the pyridyl amide group formed two hydrogen bondswith SER275 and ASP219, respectively, while FK866 only formed a hydrogen bond with SER275. The results suggested that chidamide could bind to the active site of NAMPT. Thus, the inhibitory activity of chidamide against human recombi- nant NAMPT was tested using the fluorometric assay described in our previous studies.19 As shown in Table 1, chidamide was proven to be a NAMPT inhibitor with an IC50 value of 2.1 μM.Cellular thermal shift assay (CETSA)21 was further performed to investigate whether NAMPT is the direct binding target of chidamide in HCT116 cells using FK866 as the positive control. The results indicated that the NAMPT expression level of cells treated with chidamide was more stable compared with the control, indicating a good bindingare represented with dash lines. The figure was generated using PyMol (http://www.Pymol.org/). (B) Superimposition of FK866 (green) and chidamide (purple) in the active region of NAMPT. The figure was generated using PyMol (http://www.Pymol.org/).affinity between the chidamide and NAMPT protein (Figure 3).The decrease in NAD+ level is a classic feature after inhibition of NAMPT activity.21 Therefore, we measured the NAD+ variation qualitatively compared with the control group. As shown in Figure 4A, chidamide effectively decreased the cellular NAD+ level after incubation with human HCT116 cells for 24 h.The addition of NA could activate the alternative rescue pathway to synthesize NAD+.
Furthermore, the addition of the downstream product NMN could skip the exertion of activity of NAMPT to obtain NAD+. Herein, rescue studies25 showed that addition of NA (4 μM) or NMN (10 μM) could significantly rescue cells from treatment with chidamide in HCT116 cells and human leukemia cells including K562, HL60, and HEL (Figure 4B−E), further confirming that NAMPT is a target of chidamide.To investigate the role of NAMPT in exerting the antitumor activity of chidamide, four chidamide analogs 7a−d (Scheme 1) were designed as the control molecules by removing the pharmacophores of HDAC (o-phenylenediamine) or NAMPT ((E)-3-(pyridin-3-yl)acrylamide) inhibitors. Enzyme inhibition and in vitro antitumor activity assay (Table 1) showed that compounds 7a and 7b without the pharmacophore of NAMPT inhibitors lost NAMPT inhibitory activity. Interestingly, their HDAC1 inhibitory activities were improved, while HDAC2 and HDAC3 inhibitory activities were comparable to chidamide (Table 1). For the antitumor activity, they retainedgood potency against the K562 cell line, whereas the growth inhibitory activity against HCT116, HL60, and HEL cell lines was decreased. Similarly, after the removal of pharmacophore of HDAC inhibitors, compounds 7c and 7d lost HDAC inhibitory activity but retained the NAMPT inhibitory activity. However, their antitumor activities were significantly de-creased. Compounds 7a−d and chidamide were also assayed for cytotoxicity against cancer cells deficient in NAMPT using siRNA.26 The results indicated that NAMPT inhibitors chidamide, 7a, and 7b showed decreased inhibitory activity in NAMPT-deficient cells, further confirming that NAMPT is a target of chidamide. The detailed contribution of HDAC1−3 and NAMPT to the antitumor activity of chidamide still remains to be further explored.
In summary, NAMPT was identified to be a new target of chidamide on the basis of the similarity of pharmacophore between HDAC and NAMPT inhibitors. Chidamide had low micromolar inhibitory activity toward NAMPT and signifi- cantly decreased cellular NAD+ level, which shares a similar binding mode to NAMPT inhibitor FK866. The results are helpful for better understanding of antitumor mechanism of chidamide. The modification of chidamide by removal of HDAC pharmacophore and NAMPT pharmacophore signifi- cantly decreased its antitumor activity, indicating that dual inhibition of HDAC and NAMPT might lead to improved antitumor activity. In our previous studies, the balanced inhibitory activity against both targets was found to be important for the antitumor activity.