Development of potent non-acylhydrazone inhibitors of intestinal sodium-dependent phosphate transport protein 2b (NaPi2b).

Inhibition of intestinal sodium-dependent phosphate transport protein 2b (NaPi2b), responsible for intestinal phosphate absorption, is considered to reduce serum phosphate levels, making it a promising therapeutic approach for hyperphosphatemia. Previously, we aimed to identify new drugs for hyperphosphatemia treatment and obtained zwitterionic compound 3 (IC50 = 64 nM) as a potent selective inhibitor of intestinal NaPi2b. This small-molecule compound is gut-restricted owing to its almost membrane-impermeable property. However, when compound 3, containing an acylhydrazone structure, is exposed to plasma, it is easily metabolized and likely produces an acetylhydrazine compound. Clinical studies have shown that acetylhydrazine is a risk factor for hepatic toxicity owing to its microsomal metabolism, wherein toxic reactive intermediates are formed. Therefore, in this study, we aimed to obtain potent NaPi2b inhibitors without an acylhydrazone structure to reduce the risk of hepatic toxicity. We developed compound 18, an anilide compound with zwitterionic property having potent phosphate uptake inhibitory activity in vitro (IC50 = 14 nM) and low bioavailability (FaFg = 5.9%). Oral administration of compound 18 in rats showed a reduction in phosphate absorption comparable to that observed with lanthanum carbonate, a clinically effective phosphate binder used in hyperphosphatemia treatment. Moreover, combined administration of compound 18 and lanthanum carbonate resulted in an additive effect on phosphate absorption inhibition in rats. Our findings suggest that combination therapy with lanthanum carbonate and compound 18 will not only provide better treatment outcomes for hyperphosphatemia but also reduce gastrointestinal side effects in patients.

Discovery of Gut-Restricted Small-Molecule Inhibitors of Intestinal Sodium-Dependent Phosphate Transport Protein 2b (NaPi2b) for the Treatment of Hyperphosphatemia.

NaPi2b is primarily expressed in the small intestine, lungs, and testes and plays an important role in phosphate homeostasis. The inhibition of NaPi2b, responsible for intestinal phosphate absorption, is considered to reduce serum phosphate levels, making it a promising therapeutic approach for hyperphosphatemia. Using a novel phosphate uptake inhibitor 3 (IC50 = 87 nM), identified from an in-house compound collection in human NaPi2b-transfected cells as a prototype compound, we conducted its derivatization based on a Ro5-deviated strategy to develop orally administrable small-molecule NaPi2b inhibitors with nonsystemic exposure. Consequently, compound 15, a zwitterionic compound with a potent in vitro phosphate uptake inhibitory activity (IC50 = 64 nM) and a low membrane permeability (Pe < 0.025 × 10-6 cm/s), was developed. Compound 15 showed a low bioavailability (F = 0.1%) in rats and a reduction in phosphate absorption in the rat intestinal loop assay comparable to sevelamer hydrochloride, a clinically effective phosphate binder for treating hyperphosphatemia.

A neutralizing anti-fibroblast growth factor (FGF) 8 monoclonal antibody shows anti-tumor activity against FGF8b-expressing LNCaP xenografts in androgen-dependent and -independent conditions.

BACKGROUND: Fibroblast growth factor 8-isoform b (FGF8b) has been detected in human clinical sex-organ related cancers including hormone-refractory prostate cancer. There are, however, few relevant experimental models. A murine monoclonal anti-FGF8 antibody, KM1334, has been shown to neutralize FGF8b and inhibit the growth of androgen-dependent mouse mammary SC-3 cells in vitro and in vivo. In the present study, we evaluated the anti-tumor activity of KM1334 against androgen-dependent and -independent progression of FGF8b-expressing human prostate cancer xenografts. METHODS: FGF8b cDNA was transfected into androgen-dependent human prostate cancer cell line LNCaP, and its xenograft tumors were established subcutaneously in SCID mice with or without castration. KM1334 at the dose of 400 microg/head was injected twice weekly. RESULTS: FGF8b-expressing LNCaP cells secreted FGF8b, showed enhanced level of Erk1/2 phosphorylation, and showed more potent growth properties than mock-expressing cells in vitro and in vivo. KM1334 reduced these properties in vitro, inhibited tumorigenecity in vivo (T/C=0.33), and showed anti-tumor activity against established tumors (T/C=0.47) of FGF8b-expressing cells. FGF8b-expressing LNCaP tumors were androgen-dependent. However, they recurred as androgen-independent FGF8b positive tumors after castration. KM1334 also inhibited the growth of established FGF8b-expressing tumors in the androgen-independent states (T/C=0.47). CONCLUSIONS: These results indicate that humanized monoclonal antibodies, conserving the paratope of KM1334, are a promising candidate for therapy of FGF8b-expressing clinical prostate cancers. Follow-up studies using xenograft models with clinical FGF8b-expressing tumors are required to validate these early findings.