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¹ Shire BioChem, Inc., Laval, Quebec, Canada and ² Maxim Pharmaceuticals, Inc., San Diego, California

Requests for reprints: Shailaja Kasibhatla, Maxim Pharmaceuticals, Inc., 6650 Nancy Ridge Drive, San Diego, CA 92121. Phone: 858-202-4042; Fax: 858-202-4000. E-mail: skasibhatla{at}maxim.com

	Abstract

Top Abstract Introduction Materials and Methods Results Discussion References

 
A novel series of 2-amino-4-(3-bromo-4,5-dimethoxy-phenyl)-3-cyano-4H-chromenes was identified as potent apoptosis inducers through a cell-based high throughput screening assay. Six compounds from this series, MX-58151, MX-58276, MX-76747, MX-116214, MX-116407, and MX-126303, were further profiled and shown to have potent in vitro cytotoxic activity toward proliferating cells only and to interact with tubulin at the colchicine-binding site, thereby inhibiting tubulin polymerization and leading to cell cycle arrest and apoptosis. Furthermore, these compounds were shown to disrupt newly formed capillary tubes in vitro at low nanomolar concentrations. These data suggested that the compounds might have vascular targeting activity. In this study, we have evaluated the ability of these compounds to disrupt tumor vasculature and to induce tumor necrosis. We investigated the pharmacokinetic and toxicity profiles of all six compounds and examined their ability to induce tumor necrosis. We next examined the antitumor efficacy of a subset of compounds in three different human solid tumor xenografts. In the human lung tumor xenograft (Calu-6), MX-116407 was highly active, producing tumor regressions in all 10 animals. Moreover, MX-116407 significantly enhanced the antitumor activity of cisplatin, resulting in 40% tumor-free animals at time of sacrifice. Our results identify MX-116407 as the lead candidate and strongly support its continued development as a novel anticancer agent for human use.

	Introduction

Top Abstract Introduction Materials and Methods Results Discussion References

 
The initial hit compound of a novel series of 2-amino-4-(3-bromo-4,5-dimethoxy-phenyl)-3-cyano-4H-chromenes was identified in a cell-based high throughput screening assay by measuring the induction of apoptosis using our pro-fluorescent caspase substrate (1–3). Analogues were made of the hit compound and activity and stability optimization studies identified six analogues synthesized in this series (MX-58151, MX-58276, MX-76747, MX-116214, MX-116407, and MX-126303) for further characterization. Compounds from this series were shown to have potent in vitro cytotoxic activity toward proliferating cells only and to interact with tubulin at the colchicine-binding site, thereby inhibiting tubulin polymerization and leading to cell cycle arrest and apoptosis (4). Furthermore, these compounds were shown to disrupt newly formed capillary tubes in vitro at low nanomolar concentrations. This activity suggested that the compounds might have vascular targeting activity.

Microtubules are highly dynamic assemblies of the protein tubulin and are major structural components in cells. They are important in the maintenance of cell shape, cellular movement, and cell division (5–7). Tubulin represents one of the best cancer targets identified to date given the large and diverse group of tubulin targeting anticancer drugs and their success in the clinic (8–12). These drugs, by interfering with the dynamic instability of tubulin, arrest dividing cells in the M phase of the cell cycle leading to apoptotic cell death. However, emerging resistance to antimitotic agents has limited their ultimate effectiveness and there is a renewed interest in the discovery and development of new agents that are active in multidrug-resistant cells and that interact with tubulin at sites different from those of the taxanes and Vinca alkaloids (13). This field has exploded in the last few years and led to the discovery of small molecular weight inhibitors that have shown promising antitumor activity even in tumors expressing multidrug-resistant phenotypes (14).

In addition to their tubulin-mediated cytotoxicity, Vinca alkaloids and colchicine have also been reported to induce hemorrhagic necrosis of solid tumors (15). However, because these additive antitumor effects were only observed at doses approaching or exceeding their maximum tolerated dose (MTD), this attribute has not been fully explored. This has led to the development of a second generation of tubulin-binding agents that destabilize the tubulin cytoskeleton by interacting at the colchicine-binding site at doses that are well tolerated (16). Due to their short half-lives, these compounds preferentially target tumor endothelial cells while sparing normal vasculature (17, 18). These agents, exemplified by combretastatin A-4 phosphate (CA4P) prodrug and ZD6126, both of which are analogues of colchicines, are called vascular targeting agents. Unlike antiangiogenesis drugs, which attempt to prevent the formation of new tumor blood vessels, vascular targeting agents starve existing solid tumors by depriving them of blood flow, causing tumor cell death.

In this study, we have evaluated the ability of 2-amino-4-(3-bromo-4,5-dimethoxy-phenyl)-3-cyano-4H-chromenes compounds to induce tumor necrosis and their potential to act as antitumor agents. To this end, we investigated the pharmacokinetic and toxicity profiles of these six compounds in the series and examined their ability to induce tumor necrosis. We also examined the antitumor efficacy of a subset of these compounds in three different human solid tumor xenografts and addressed the chemoenhancing potential of the optimal analogue.

	Materials and Methods

Top Abstract Introduction Materials and Methods Results Discussion References

 
Compounds
ZD6126 was synthesized at Shire BioChem (Laval, Quebec, Canada) according to published procedures (19). MX-58151, MX-58276, MX-76747, MX-116214, MX-116407, and MX-126303 were synthesized at Shire BioChem and Maxim Pharmaceuticals according to methods described previously (4).³ MX compounds were dissolved in a mixture of Cremophor EL (5-10%) and ethanol (5-10%) in saline; ZD6126 was dissolved in water and 5% aqueous sodium carbonate solution was added drop-wise until a clear solution was obtained; cisplatin (0.4 mg/mL) was dissolved in 0.9% saline. Drugs were given at constant injection volumes of 10 mL/kg of mouse body weight i.p. (ZD6126 and cisplatin) or i.v. (MX compounds).

Cell Culture
The human lung carcinoma Calu-6 cell line was purchased from the American Type Culture Collection (Manassas, VA); the human breast carcinoma MDA-MB-435 cell line was obtained from the Frederick Research Tumor Repository (Frederick, MD). Cell lines were maintained in either MEM (Calu-6) or RPMI 1640 (MDA-MB-435) supplemented with fetal bovine serum (10%, Life Technologies, Burlington, Ontario, Canada) and supplements (nonessential amino acids, glutamine, sodium pyruvate, vitamins, and glucose; Cellgro Mediatech, Inc., Herndon, VA) according to the cell supplier's instructions. All cell lines were maintained at 37°C in a humidified atmosphere of 95% air and 5% CO₂. Cells were grown in absence of antibiotics and periodically checked for Mycoplasma contamination by Hoechst 33258 staining (20).

Tumor Fragments
The MX-1 breast carcinoma tumor fragments were originally obtained from the Frederick Research Tumor Repository and maintained by passage in NCr mice.

Animals
Athymic (Crl:CD-1-nuBr) and severe combined immunodeficient [Crl:Icr:Ha(ICR)-scid] mice 6 to 8 weeks old were purchased from Charles Rivers Laboratories (St-Constant, Quebec, Canada). Tac:Cr;(NCr)-Hfh11nu (NCr) mice 6 to 8 weeks old were purchased from Taconic Farms (Germantown, NY). Animals were maintained under specific pathogen-free conditions and had access to sterile food and water ad libitum. All animal studies were done in the animal facility at Shire BioChem with the prior approval of the local Institutional Animal Care Committee and in agreement with the guidelines provided by the Canadian Council for Animal Care.

Pharmacokinetic Profiling
The six compounds under evaluation were given i.v. at a dose of 10 mg/kg to CD-1 male mice (n = 30 mice, per compound). Blood was collected into EDTA (final concentration, 2 mg/mL)–containing tubes by cardiac puncture at 2, 5, 15, 30, 45, 60, 90, 120, 180, and 240 minutes following compound administration. Samples were centrifuged at 10,000 x g for 10 minutes and plasma samples were collected and stored at –20°C until use. Mouse plasma (100 µL) was mixed with 50 µL internal standard and diluted with deionized water (900 µL). The mixture (1 mL) was loaded onto Oasis HLB 30-mg 96-well solid-phase extraction plate (Waters Corp., Milford, PA). After sequential washes with deionized water (1 mL) and 20% methanol (1 mL), the sample and the internal standard were eluted with acetonitrile (1 mL) and then evaporated to dryness under a gentle stream of nitrogen. The residues were reconstituted with 50% methanol (100 µL) in water and aliquots (10 µL) were analyzed by tandem liquid chromatography/mass spectrometry. The chromatography was achieved on a Luna C18 column (50 x 2 mm, 5 µm, Phenomenix, Torrance, CA) with a 5-minute elution gradient of acetonitrile (20–80%) in ammonium formate (10 mmol/L). The flow rate was 0.25 mL/min and total run time was at 12 minutes. Quantitation was done on a tandem liquid chromatography/mass spectrometry (TSQ7000, ThermoFinnigan, San Jose, CA) equipped with APCI source. Standard curve in mouse plasma ranged from 5 to 5,000 ng/mL, with minimum seven calibration points and three levels of quality controls.

Plasma concentration-time data were analyzed by noncompartmental linear pharmacokinetic methods using Kinetica (Innaphase, Philadelphia, PA). Maximum serum concentrations (C_max) were read directly from the experimental data, with t_max defined as the time of the first measurement (2 minutes). The terminal phase rate constants (k) were estimated using least squares regression analysis of the serum concentration-time data obtained during the terminal log-linear phase. The terminal half-life (t) was calculated by the equation 0.693/k. The area under the serum concentration-time curve from time 0 to 240 minutes was estimated using linear trapezoidal approximation and was extrapolated to infinity according to the formula: AUC_{(0 )} = C_last/k, where C_last is the estimated concentration at time t_last = 240 minutes. Clearance was calculated as dose/AUC_{(0 )} and Vss was estimated as dose x AUMC/AUC², where AUMC is the area under the first moment curve (21).

Toxicity Studies
Toxicity profile of each tested compound was assessed after a single dose treatment or either a single or a twice daily treatment repeated for 5 consecutive days. A 14-day observation period followed the treatment period. CD-1 male mice (6–10 mice per dose) were given by a slow bolus injection at a constant volume of 10 mL/kg through the caudal vein while restrained in a plexiglass retainer tube. To monitor the general health condition and drug-associated toxicity, mice were weighed at least twice weekly and inspected daily for clinical abnormalities. The animals were euthanized under isoflurane anesthesia and blood was collected by cardiac puncture. The collected blood was immediately distributed into EDTA-containing tubes (hematology samples) or clotting gel–containing tubes (clinical chemistry samples) and sent for analysis at Cirion Biopharma, Inc. (Laval, Quebec, Canada). Macroscopic necropsies were done at 24 hours post-treatment (single dose) or after the last treatment (5-day repeat treatment) and again at the end of the 14-day observation period. Right kidney, liver, spleen, and thymus were weighed.

The MTD was estimated as the dose that resulted in 20% of body weight loss compared with the animal weight at the beginning of the treatment, <10% death rate, reversible observed clinical signs and hematology/clinical chemistry changes, and no visible macroscopic tissue changes at the end of the observation period. A drug dose was considered toxic if animals lost 20% of their initial body weight or if there was >10% lethality when applying humanized end points as described by the Canadian Council for Animal Care. The mice were prematurely euthanized when the MTD criteria were crossed or the established humanized end points as described by the Canadian Council for Animal Care were reached.

Tumor Necrosis and Vascular Dysfunction
Necrosis was assessed by light microscopy at 40x magnification. MDA-MB-435 tumor-bearing mice were injected with single doses of compounds at different concentrations as indicated. Tumors were excised 24 hours later and rapidly snap frozen in CryoMatrix (Cryomatrix, Pittsburgh, PA). Sections (6 µm) were prepared and stained with Gomori (Sigma Chemical Co., St. Louis, MO). The level of necrosis was scored visually according to the following scale: 1, 0-10% necrosis; 2, 11-20% necrosis; ...; 10, 91-100% necrosis.

Functional vasculature was assessed as described previously (22). Hoechst 33342 (10 mg/kg) was injected into the tail vein of MDA-MB-435 tumor-bearing mice followed by a single bolus injection of vehicle, MX-116407 (10, 20, or 40 mg/kg), or CA4P (150 mg/kg). Four hours later, a second dye, DiOC₇(3), was injected; 2 minutes after injection, the mice were euthanized and tumors were rapidly removed, embedded in a tissue holder, and immediately frozen in liquid N₂ for sectioning. Perfused blood vessels in the tumor could be visualized by the surrounding halo of fluorescent Hoechst 33342– and/or DiOC₇(3)-labeled endothelial cells. The two dyes have different excitation and emission spectra, which allow separate detection. This method provides an estimate of the relative degree of perfused tumor vasculature. For each tumor, an average percentage image area was calculated. A total of three mice were imaged in each group.

Antitumor Efficacy Studies
Female severe combined immunodeficient mice were injected s.c. with 2 x 10⁶ MDA-MB-435 cells. Tumor-bearing animals were randomized (10 mice per group) and treatment was started when tumor volumes reached 50 to 100 mm³ (day 20). Doses and administration schedules are described in Table 1.

Female athymic CD-1 (nu/nu) mice were injected s.c. with 2 x 10⁶ Calu-6 cells in 50% Matrigel. Administration of compounds or vehicle began at day 24 when the average tumor size reached 250 mm³. Tumor-bearing animals were randomized (10 per group) prior to treatment. MX-76747, MX-116214, and MX-116407 were given i.v. at 10, 15, or 45 mg/kg, respectively, daily for 5 consecutive days (days 24–28). ZD6126 was given i.p. at 100 mg/kg on days 24 to 28. In the combination studies, a single dose of 4 mg/kg cisplatin was given i.p. 24 hours prior to treatment with MX-116407.

Tumor measurements taken by electronic calipers twice weekly were converted to tumor volumes (in mm³) using the standard formula: width² x length x 0.52 (23). Compound efficacy was assessed once the tumors in the control group had reached at least five times their original volume (500% growth) by percentage of treated versus control (% T/C) defined as the (mean treated tumor volume) / (mean control tumor volume) x 100. A % T/C value of <42 was considered effective (24, 25). Tumor growth inhibition (TGI) was calculated by subtracting the % T/C from 100%. Tumor growth delay (TGD) was determined as the time delay necessary to double the mean tumor volume (starting from day 1 of treatment) in treated versus control animals. Statistical analysis was done by ANOVA or by Student's t test. Differences were considered to be significant at P < 0.05.

	Results

Top Abstract Introduction Materials and Methods Results Discussion References

 
Pharmacokinetics
The plasma concentration-time profiles and pharmacokinetic variables of MX-58151, MX-58276, MX-76747, MX-116214, MX-116407, and MX-126303 after single i.v. doses of 10 mg/kg are shown in Fig. 1 and Table 1, respectively. The clearance of the six compounds varied 5-fold. MX-126303 was cleared at a rate close to the mouse liver blood flow (1.4 versus 1.8 mL/min; ref. 26), which resulted in one of the lowest measured C_max at 2 minutes (12.3 µg/mL) and lowest exposure (159.6 µg x min/mL) compared with the other five drug candidates. In contrast, MX-116214 was characterized by the slowest clearance of this series (0.25 mL/min) and had the greatest exposure (998.4 µg x min/mL), resulting in plasma concentrations in the micromolar range up to 4 hours. Despite their differences in clearance, these two compounds had the longest terminal half-lives (70 minutes), suggesting that the tissue distribution is greater for MX-126303 than for MX-116214. The other compounds were characterized by intermediate plasma clearances and terminal elimination half-lives of 40 minutes. Highest initial concentrations were achieved by MX-58151, MX-58276 and MX-76747 (26–29 µg/mL).

View larger version (14K): [in this window] [in a new window] [Download PPT slide]   Figure 1. Plasma concentration-time curves of selected compounds. The pharmacokinetics of MX-58151 (), MX-58276 (), MX-76747 (), MX-116214 (), MX-116407 (), and MX-126303 (•) were evaluated in male CD-1 mice (n = 3 per time point). A single dose of each different compound was given i.v. at 10 mg/kg. Plasma was collected by cardiac puncture at 2, 5, 15, 30, 60, 90, 120, 180, and 240 minutes following compound administration.

View larger version (52K): [in this window] [in a new window] [Download PPT slide]   Figure 2. Regrowth of MDA-MB-435 tumors after a single dose of MX-116407. Twelve mice bearing MDA-MB-435 tumor xenografts were treated with a single i.v. bolus dose of MX-116407 (100 mg/kg) when tumors reached an average volume of 250 mm3 (day 49). A, tumors were measured twice weekly and on days 1, 4, 7, and 14 after treatment with MX-116407. Three mice were sacrificed for tumor necrosis evaluation. B, Gomori staining 24 hours after treatment (x40). C, Gomori staining 14 days after treatment (x40). Representative necrotic (N) and viable (V) regions are identified. Regrowth seems to originate from the tumor rim.

View larger version (17K): [in this window] [in a new window] [Download PPT slide]   Figure 3. Functional vasculature determination following single dose of MX-116407. Perfused vasculature in the Calu-6 tumor was assessed by a double fluorescent dye staining procedure as described in Materials and Methods. Vehicle and CA4P were used as negative and positive controls, respectively. Columns, mean of three animals per group; bars, SD.

View larger version (24K): [in this window] [in a new window] [Download PPT slide]   Figure 4. Activity of selected compounds against the human breast (MX1) tumor xenograft. MX1 human breast fragments were implanted s.c. by trocar in nu/nu female mice. Treatment was initiated when the primary tumor reached a size of 150 mm3 (day 13). MX-76747 (10 mg/kg, ), MX-116214 (15 mg/kg, ), and MX-116407 (45 mg/kg, ) were given i.v. on days 13-17 and days 20-24. ZD6126 (100 mg/kg, ) was given i.p. on the same days. Saline control group (solid line); Cremophor/ethanol/dextrose control group (dashed line). Solid horizontal bar, treatment period.

View larger version (18K): [in this window] [in a new window] [Download PPT slide]   Figure 5. In vivo antitumor activity of selected compounds against the human lung (Calu-6) tumor xenograft. BALB/c female nude mice 6–8 weeks old were injected s.c. with 2 x 106 Calu-6 cells (day 0). Treatment was initiated when the primary tumor reached a size of 250 mm3 (day 24). MX-76747 (10 mg/kg, ), MX-116214 (15 mg/kg, ), and MX-116407 (45 mg/kg, ) were given i.v. on days 24–28. ZD6126 (100 mg/kg, ) was given i.p. on the same days. Vehicle control (Cremophor/ethanol/saline) group (). Solid horizontal bar, treatment period.

View larger version (21K): [in this window] [in a new window] [Download PPT slide]   Figure 6. Growth of Calu-6 human tumor xenografts after treatment with MX-116407 in combination with cisplatin. Treatment was initiated when tumors reached an average size of 250 mm3 (day 24). Cisplatin was given daily at 4 mg/kg i.p. (•) 1 day prior to MX-116407. MX-116407 was given daily for 5 days at 45 mg/kg alone () or in combination with cisplatin (). Vehicle control group (Cremophor/ethanol/saline) was dosed daily for 5 days (). A, tumor growth results are expressed as a percentage of growth in relation to the size of each tumor on the day of first treatment (this value was set as 100% and tumor growth is reported in percentage). B, relative tumor volumes of all the animals from the different treatment groups are compared at day 42, after which time animals from the control group had to be sacrificed due to tumor burden. Solid horizontal bar, treatment period for MX-116407 and vehicle.

	Discussion

Top Abstract Introduction Materials and Methods Results Discussion References

Tubulin-binding agents are known to have antivascular activity, but for most compounds, this effect is observed at or close to the MTD (5). However, the newer generation of tubulin-interacting agents, such as CA4P and ZD6126, have shown a selective effect against tumor vasculature at doses around one-third (28) to one-tenth (29, 30) of their respective MTDs. The six compounds profiled in this study all induced extensive tumor necrosis. Within 24 hours of administration, the entire center of the tumor was necrotic with a thin viable rim of tumor cells surviving at the periphery. This pattern of central necrosis with a thin viable rim of tumor cells was first reported with CA4P (30) and is consistent with vasculature targeting agents (18, 31–33). However, when the dose required to induce significant tumor necrosis was compared with the dose that caused significant but reversible toxicities, it became evident that some compounds were more effective than others.

Also observed with this series of compounds was that the compounds with the most potent antivascular effects were not the most potent in vitro (4). Indeed, although MX-126303 had the best in vitro cytotoxic activity, it induced tumor necrosis at levels close to its MTD, suggesting that its toxicity is linked with its effect on tubulin inhibition rather than targeting selectively endothelial cells. The antivascular activity of MX-126303 is reminiscent of other tubulin-binding agents, such as colchicine and vinblastine, which have vascular-damaging activity only at their MTDs. However, its pharmacokinetic profile is similar to classic antivascular agents such as ZD6126 and CA4P, which have short plasma half-lives (29, 34). On the other hand, MX-116407, while less cytotoxic than MX-126303 in vitro, had more tumor-selective antivascular activity. We observed 80% tumor necrosis at 25 mg/kg, corresponding to one-fourth of its MTD. This may be related to the differences in pharmacokinetic profile. Although both MX-116407 and MX-126303 have rapid distribution phases, resulting in maximum concentrations at the earliest time point evaluated (10 and 12.3 µg/mL, respectively), their clearance rates were quite different, varying by 2.4-fold. This results in a 8-fold difference in concentration after 45 minutes (3.5 versus 0.44 µg/mL for MX-116407 and MX-126303, respectively; Fig. 1). A rapid distribution coupled with a slow clearance is thus likely to be important for good antitumor activity.

A second explanation might relate to our finding that apoptosis induction following a 3-hour treatment with MX-126303 is irreversible after drug washout, whereas induction of apoptosis following MX-116407 treatment is reversible (4). This may suggest that MX-116407 and MX-126303 have different tubulin-binding kinetics, leading to differences in pharmacologic profile. Indeed, the improved therapeutic index observed with CA4P compared with colchicine has been correlated to their differences in the on/off rate of binding to tubulin (11, 17, 35), leading to the hypothesis that a successful vascular targeting agent would have reversible binding kinetics and relatively rapid clearance in vivo (19).

The vascular targeting activity of this novel series of compounds, suggested by the induction of tumor necrosis, led us to investigate their antitumor potential. Whereas treatment of mice bearing MDA-MB-435 tumor xenografts with MX-58151, MX-58276, and MX-126303 resulted in poor antitumor activity with % T/Cs of 65, 75, and 75, respectively, MX-76747, MX-116214, and MX-116407 resulted in moderate antitumor activity with % T/Cs of 58, 55, and 43, respectively. According to National Cancer Institute criteria, compounds resulting in % T/C values of 42 are considered to have antitumor activity (24). The moderate antitumor activity is likely a result of regrowth of the tumor originating from the viable rim of tumor cells remaining after the treatment. We have observed that the MDA-MB-435 tumors have repopulated spontaneously 14 days after the cessation of treatment, although % T/C values were calculated at day 50, 10 days after cessation of treatment. We have further evaluated MX-76747, MX-116214, and MX-116407 in other human tumor xenograft models. In the human breast (MX-1) tumor xenograft, all three compounds showed significant antitumor activity with % T/Cs ranging between 0.7 and 17. In the human lung (Calu-6) tumor xenograft, MX-116407 was highly active, producing tumor regressions in all 10 animals. Moreover, MX-116407 significantly enhanced the antitumor activity of cisplatin, producing tumor-free animals in a significant number (4 of 10) of cases at time of sacrifice.

In summary, we have identified 2-amino-4-(3-bromo-4,5-dimethoxy-phenyl)-3-cyano-4H-chromenes as a novel series of vascular targeting agents with promising antitumor activity. Our encouraging results with MX-116407 strongly support its continued development as a novel anticancer agent for human use.

	Acknowledgments

 
We thank Louis Vaillancourt for the synthesis of ZD6126 and Johanne Cadieux for assistance in the preparation of the article.

	Footnotes

 
The costs of publication of this article were defrayed in part by the payment of page charges. This article must therefore be hereby marked advertisement in accordance with 18 U.S.C. Section 1734 solely to indicate this fact.

³ W. Kemnitzer et al. Discovery of 4-aryl-4H-chromenes as a new series of apoptosis inducers using a cell- and caspase-based high throughput screening assay; structure-activity relationships of the 4-aryl group. J Med Chem In press 2004.

Received 5/ 7/04; revised 7/16/04; accepted 9/15/04.

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