Abstract 05: Cyclooxygenase-2 Inhibition As A New Tool To Combat Angiogenesis Inhibitor-induced Hypertension And Renal Toxicity

Angiogenesis inhibitors are effective anti-cancer agents, but also cause hypertension and renal injury. Earlier, we observed in rats that high-dose aspirin (capable of blocking cyclooxygenase (COX)-1 and -2) prevented these side effects better than low-dose aspirin (blocking COX-1 only). Therefore, we hypothesized that selective COX-2 inhibition would prevent toxicity during angiogenesis inhibition, and that this toxicity involves a reduced ratio of vasodilator/constrictor COX-derived prostanoids, i.e., prostacyclin (PGI 2 ) and thromboxane (TXA 2 ). Male WKY rats received vehicle, angiogenesis inhibition (sunitinib (SU), 14 mg/kg/day) alone or combined with COX-2 inhibition (celecoxib, 10mg/kg/day), a PGI 2 analogue (iloprost 100 μg/kg/day), or a dual TXA 2 synthase/receptor antagonist (picotamide, 2.5 mg/kg/day) for 8 days (n=7-8/group). Mean arterial pressure (MAP) was measured via radiotelemetry, vascular function was assessed via wire myography, and biochemical measurements were performed by ELISA. SU induced a rapid increase in MAP (16±2 vs. 3±1 mmHg after vehicle on day 6, P<0.001), which was blunted by celecoxib (10±2 mmHg on day 6, P=0.06 versus SU), temporarily attenuated by iloprost (on treatment days 1-2) and unaffected by picotamide. Wire myography demonstrated a trend towards increased vasoconstrictor response to endothelin-1 in iliac arteries after SU, which was prevented by celecoxib (P<0.001). SU increased albuminuria (0.6±0.1 vs. 0.3±0.1 mg/24h after vehicle; P<0.001), and this was prevented by celecoxib only (0.4±0.1 mg/24h, P=0.01 vs. SU). SU increased the PGI 2 /TXA 2 ratio in both plasma (2.7±1.2 vs. 0.6±0.2 after vehicle, P=0.05) and urine (22±2.2 vs. 0.9±0.2 after vehicle, P<0.001). In conclusion, selective COX-2 inhibition combats angiogenesis inhibitor-induced hypertension and renal toxicity. SU paradoxically increases the PGI 2 /TXA 2 ratio, particularly in the kidney. Although this upregulation might initially be protective, it could eventually contribute to renal toxicity, most likely because PGI 2 exerts deleterious effects in excessive concentrations. Targeting excessive renal PGI 2 production might be another promising strategy to prevent renal toxicity during angiogenesis inhibition.

OMRT-7. Angiogenesis inhibitors strongly synergize with therapeutics targeting tumor metabolism

Angiogenesis inhibition has become a mainstay of oncology despite having fallen short of its early promise. As originally envisioned, angiogenesis inhibition would cut off the blood supply, deprive tumor cells of key nutrients, leading to their death. In practice, while there is evidence that tumors under angiogenesis treatment do in fact exhibit some degree of metabolic stress, this is stress is not sufficient to induce significant cancer cell death. We posit that the full potential of angiogenesis inhibition can be realized by the combination of angiogenesis inhibition with emerging tumor metabolism targeting therapies. Because tumors under angiogenesis inhibition are already in a state of nutrient stress, the effects of metabolically targeted therapies such as amino acid depletion (e.g. asparginase, methionine restriction), inhibitors of stress adaption (AMPK and GCN2 inhibitors) or energy metabolism (e.g. IACS-010759, Metformin, POMHEX) stand to dramatically increase in potency whilst remaining selective for (angiogenic) tumor versus (non-angiogenic) normal tissue. Here, we provide proof-of-principal for this thesis. First, we performed metabolomic profiling of angiogenesis-inhibited tumors, which corroborates a state of nutrient stress in angiogenesis-inhibited tumors. Second, we demonstrate dramatic anti-neoplastic synergy (effectively curing of xenografted tumor-bearing mice, irrespective of initial tumor size), without enhanced adverse toxicities, between the OxPhos inhibitor IACS-010759 and the angiogenesis tyrosine kinase inhibitor, Tivozanib. The same results were recapitulated with the anti-VEGFA antibody, Avastin, and the OxPhos inhibitor could be substituted with the Enolase inhibitor HEX, with similar effects. The synergy was observed in a broad range of tumor types, even those without clear genetic susceptibilities. Together, these results suggest that angiogenesis inhibitors synergize broadly with cancer therapies targeting metabolism, allowing the realization of the full potential of these previously disappointing drugs. Our results warrant systematic combination clinical trials between angiogenesis inhibitors and established, as well as emerging anti-metabolic cancer therapies.

Bioactive fractions and compound of Ardisia crispa roots exhibit anti-arthritic properties mediated via angiogenesis inhibition in vitro

Background Ardisia crispa (Thunb.) A.DC (Primulaceae), is a medicinal herb traditionally used by Asian people as remedies to cure inflammatory related diseases, including rheumatism. The plant roots possess various pharmacological activities including antipyretic, anti-inflammation and antitumor. Previous phytochemical studies of the plant roots have identified long chain alkyl-1,4-benzoquinones as major constituents, together with other phytochemicals. Hexane fraction of the plant roots (ACRH), was previously reported with anti-angiogenic and anti-arthritic properties, while its effect on their anti-arthritic in vitro, is yet unrevealed. Considering the significance of angiogenesis inhibition in developing new anti-arthritic agent, thus we investigated the anti-arthritic potential of Ardisia crispa roots by suppressing angiogenesis, in vitro. Methods Ardisia crispa roots hexane extract (ACRH) was prepared from the plant roots using absolute n-hexane. ACRH was fractionated into quinone-rich fraction (QRF) and further isolated to yield benzoquinonoid compound (BQ), respectively. In vitro experiments using VEGF-induced human umbilical vein endothelial cells (HUVECs) and IL-1β-induced human fibroblast-like synoviocytes for rheumatoid arthritis (HFLS-RA) were performed to evaluate the effects of these samples on VEGF-induced HUVECs proliferation and tube formation, and towards IL-1β-induced HFLS-RA proliferation, invasion, and apoptosis, respectively. Therapeutic concentrations (0.05, 0.5, and 5 μg/mL) tested in this study were predetermined based on the IC50 values obtained from the MTT assay. Results ACRH, QRF, and BQ exerted concentration-independent antiproliferative effects on VEGF-induced HUVECs and IL-1β-induced HFLS-RA, with IC50 values at 1.09 ± 0.18, 3.85 ± 0.26, and 1.34 ± 0.16 μg/mL in HUVECs; and 3.60 ± 1.38, 4.47 ± 0.34, and 1.09 ± 0.09 μg/mL in HFLS-RA, respectively. Anti-angiogenic properties of these samples were verified via significant inhibition on VEGF-induced HUVECs tube formation, in a concentration-independent manner. The invasiveness of IL-1β-induced HFLS-RA was also significantly inhibited in a concentration-independent manner by all samples. ACRH and BQ, but not QRF, significantly enhanced the apoptosis of IL-1β-induced HFLS-RA elicited at their highest concentration (5 μg/mL) (P < 0.05). Conclusions These findings highlight the bioactive fractions and compound from Ardisia crispa roots as potential anti-arthritic agents by inhibiting both HUVECs and HFLS-RA’s cellular functions in vitro, possibly mediated via their anti-angiogenic effects.