Vascular disrupting agents (VDA) offer a strategy to starve solid tumors of nutrients and oxygen concomitant with tumor shrinkage. Several VDAs have progressed into early clinical trials, but their therapeutic value seems to be compromised by systemic toxicity. In this report, we describe the design and characterization of a novel VDA, ICT2588, that is nontoxic until activated specifically in the tumor by membrane-type 1 matrix metalloproteinase (MT1-MMP). HT1080 cancer cells expressing MT1-MMP were selectively chemosensitive to ICT2588, whereas MCF7 cells that did not express MT1-MMP were nonresponsive. Preferential hydrolysis of ICT2588 to its active metabolite (ICT2552) was observed in tumor homogenates of HT1080 relative to MCF7 homogenates, mouse plasma, and liver homogenate. ICT2588 activation was inhibited by the MMP inhibitor ilomastat. In HT1080 tumor–bearing mice, ICT2588 administration resulted in the formation of the active metabolite, diminution of tumor vasculature, and hemorrhagic necrosis of the tumor. The antitumor activity of ICT2588 was superior to its active metabolite, exhibiting reduced toxicity, improved therapeutic index, enhanced pharmacodynamic effect, and greater efficacy. Coadministration of ICT2588 with doxorubicin resulted in a significant antitumor response (22.6 d growth delay), which was superior to the administration of ICT2588 or doxorubicin as a single agent, including complete tumor regressions. Our findings support the clinical development of ICT2588, which achieves selective VDA targeting based on MT-MMP activation in the tumor microenvironment. Cancer Res; 70(17); 6902–12. ©2010 AACR.
Disruption of the vascular network within tumors is known to be an efficient chemotherapeutic strategy, with a number of vascular disrupting agents (VDA) currently undergoing clinical trials (1, 2). Several VDAs target the colchicine-binding site of tubulin, induce rapid conformational changes in tumor vasculature, blood vessel occlusion, and consequent tumor necrosis (1–4). The disruption of a single tumor blood vessel has the effect of starving and consequently killing the many tumor cells it supports, making this a very effective therapeutic strategy. However, the prevalence of cardiotoxicity, cardiac ischemia, and arrhythmias in clinical trials of systemically administered VDAs targeting the colchicine-binding site of tubulin suggests that their therapeutic value is compromised by intrinsic systemic toxicity (5–7). Strategies focused on improving the therapeutic index of these VDAs, reducing systemic exposure, and improving tumor selectivity and response are paramount.
Matrix metalloproteinases (MMP) comprise a family of 24 zinc-dependent endopeptidases with structural similarity and a pivotal role in tumorigenesis and tumor progression (8–10). Originally, it was believed that the MMPs functioned purely to break down the extracellular matrix to facilitate tumor invasion, a concept now shown to be too simplistic (9). In addition to extracellular matrix breakdown and tumor cell invasion, MMPs also play a major role in controlling tumor cell growth, migration, differentiation, and ultimately metastasis (8, 9). The MMP family comprises two groups, that is, the soluble and membrane-type MMPs (MT-MMPs), with the MT-MMPs further subclassified by their cell surface association, either by a transmembrane domain (MT1, 2, 3, and 5) or by a glycophosphatidylinositol anchor (MT4 and 6). Transmembrane MT-MMPs play a role in many tumorigenic processes, and their expression is elevated in a wide range of tumors, including non–small cell lung cancer (11–15). MT1-MMP (also known as MMP-14), the prototypic and most widely studied member of this family, has a crucial role in tumorigenesis, particularly tumor cell dissemination and metastasis (15–18). For instance, induced expression of MT1-MMP into null or nonmalignant cells renders the cells capable of invasion, and knockdown of MT1-MMP inhibits cell invasion and tumor progression (19–23). A crucial role for MT1-MMP in tumor angiogenesis has been reported by several in vitro and in vivo studies (12, 24–26). The therapeutic potential of this is illustrated by MT1-MMP–selective antibody inhibition of angiogenesis and tumor progression (25). The pivotal role for MT1-MMP in tumor expansion and progression, its elevated expression in a wide range of tumor types and its unique localization tethered to the cell surface, strongly support its potential as a target for therapeutic exploitation in cancer.
Several successful approaches for targeting chemotherapy directly to malignant tissue have emerged, including antigen targeting, antibody- or gene-directed enzyme prodrug therapy, and tumor enzyme–activated chemotherapy (27). In particular, the exploitation of enzymes elevated selectively in the tumor microenvironment to convert an inactive drug into its active chemotherapeutic metabolite has shown significant promise, as exemplified by the bioreductive drug AQ4N (Banoxantrone; refs. 28, 29) and the clinically used agent capecitabine (Xeloda; refs. 27, 30). Consequently, a significant effort has been focused on the identification of suitable tumor enzymology and the development of therapeutics directed against these targets, including proteolytic enzymes of the tumor degradome (31). In this regard, a potential strategy to improve the therapeutic index of VDAs is to selectively release an active VDA from an inactive form within the tumor microenvironment, such as by using the increased activity of MMPs (31).
In this study, we have designed and developed a novel agent (ICT2588) that is selectively metabolized by MT-MMPs, particularly MT1-MMP, to release an active VDA, azademethylcolchicine (ICT2552). The activation of this agent (ICT2588) selectively in the tumor, coupled with negligible/undetectable levels of the active azademethylcolchicine (ICT2552) in normal tissues in vivo, led to a significant antitumor effect with a greater therapeutic index. Furthermore, coadministration of ICT2588 with the chemotherapeutic agent doxorubicin resulted in a significantly enhanced antitumor effect and tumor cures in preclinical studies.
Materials and Methods
The human fibrosarcoma (HT1080; ATCC CCL-121) and breast carcinoma (MCF7; ATCC HTB-22) cell lines were obtained from American Type Culture Collection and were authenticated both morphologically and by short tandem repeat analysis. Cell lines were cultured as monolayers in RPMI 1640 supplemented with 10% (v/v) fetal bovine serum, 1 mmol/L of sodium pyruvate, and 2 mmol/L of l-glutamine. All cell lines were used at a low passage in our laboratory for a maximum of 6 months postresuscitation and were tested regularly to confirm lack of Mycoplasma infection.
Female BALB/c immunodeficient nude mice (Harlan Blackthorne) were housed in an air-conditioned room with regular alternating cycles of light and darkness and received Harlan 2018 diet and water ad libitum. The facilities were approved by the Home Office and met all current regulations and standards of the United Kingdom. The mice were used between the ages of 6 and 8 weeks in accordance with institutional guidelines, and all procedures were carried out under a U.K. Home Office Project License, following U.K. Coordinating Committee on Cancer Research guidelines (32).
Mice were implanted s.c. with 2 to 3 mm3 fragments of HT1080 or MCF7 tumor xenografts. Resultant tumors were removed, snap-frozen in liquid nitrogen, and stored at −70°C.
Quantification of MMP expression by real-time reverse transcription-PCR
Assessment of MMP gene expression as determined by quantitative reverse transcription-PCR was performed as previously described (33). The 18S rRNA gene was used as an endogenous control, using previously validated procedures (34). All primers and fluorogenic probe nucleotide sequences were previously shown to be MMP gene–specific (33, 34). The CT (cycle at which amplification entered the exponential phase) was used as an indicator of the level of target RNA in each tissue, that is, a lower CT indicated a higher quantity of target RNA.
Cells were lysed on ice with extraction buffer, containing 50 mmol/L of Tris-HCl (pH 7.6), 1.5 mmol/L of NaCl, 0.5 mmol/L of CaCl2, 1 μmol/L of ZnCl, 0.01% Brij 35, and 0.25% Triton X-100 for 15 minutes. For xenograft tumors, tissue was weighed, incubated on ice in extraction buffer for 15 minutes, homogenized, and incubated for a further 15 minutes on ice. The resulting protein extract was collected via centrifugation at 2,000 × g for 10 minutes at 4°C. Equal amounts of proteins (representing 1 × 105 cells or 0.1 mg xenograft tissue) were resolved by 10% SDS-PAGE and blotted onto Hybond-P membrane (Amersham, United Kingdom). Nonspecific antibody binding was blocked via incubation in 5% enhanced chemiluminescence blocking reagent (Amersham). The blot was probed with a monoclonal antibody to MT1-MMP (MAB3328; Chemicon International) overnight at 4°C followed by a rabbit anti-mouse horseradish peroxidase–conjugated antibody (Dako). Antibody reactivity was detected by chemiluminescence using ECL-Plus (Amersham).
Synthesis of MT-MMP targeted compound
The MT-MMP–targeted agent, ICT2588 (Fig. 2A), was synthesized as a COOH-terminal– and NH2-terminal–modified peptide conjugate of azademethylcolchicine (ICT2552) using a combinatorial of solution and solid phase chemistries, as developed in house (35). Compound purity and identity was shown by high-performance liquid chromatography and mass spectrometry (Supplementary Fig. S1).
In vitro chemosensitivity of HT1080 and MCF7 cells to the agents was determined using the 3-(4,5-dimethylthiazol-2-yl)-2,5-diphenyltetrazolium bromide assay, described elsewhere (36). Cells were exposed to ICT2588 (2.4 nmol/L to 5 μmol/L), its authentic metabolite, ICT2552 (0.1 nmol/L to 5 μmol/L), or solvent (DMSO). Solvent concentrations did not exceed 0.1% and were not cytotoxic. Chemosensitivity was assessed following either 24 or 96 hours of agent exposure, with cell survival determined 96 hours posttreatment. Survival curves were obtained and IC50 values calculated.
Immunocytochemical analysis of microtubule disruption
Assessment of microtubule disruption induced by ICT2588 and ICT2552 in HT1080 and MCF7 cells was performed using previously described methodologies (37). ICT2588 or its authentic metabolite, ICT2552, were tested at the IC50 concentration identified for HT1080 [as determined by 3-(4,5-dimethylthiazol-2-yl)-2,5-diphenyltetrazolium bromide assay] and at one-tenth this dose. After 24 hours of agent exposure, tubulin disruption was assessed by α-tubulin fluorescence immunocytochemistry and visualized by confocal microscopy.
ICT2588 metabolism in tissues ex vivo
Cell pellets and xenograft tumors were homogenized in MMP activity buffer [50 mmol/L Tris-HCl (pH 7.6), 1.5 mmol/L NaCl, 0.5 mmol/L CaCl2, 1 μmol/L ZnCl, and 0.01% v/v Brij-35] and the resultant supernatants collected by centrifugation. Supernatants (equivalent to 100 mg tissue/mL) were then assayed for their ability to activate ICT2588 (final concentration, 20 μmol/L). Reaction aliquots were removed over a 120-minute period, proteins precipitated using acetonitrile, and agent and metabolites analyzed by liquid chromatography-mass spectrometry (LC-MS). Detection was performed on a Waters Alliance system using a photodiode array detector, and a Micromass ZMD Mass Spectrometer connected in series. Agent and metabolites were separated on a RPB reversed-phase high-performance liquid chromatography column (HiChrom) using a mobile phase of acetonitrile/water/0.05% trifluoroacetic acid, with a gradient from 22.5% to 50% acetonitrile over 30 minutes at 1.2 mL/min. ICT2588 was quantified using absorption measurement at 360 nm. Metabolic intermediates were detected as singularly and doubly charged ions and identified by mass spectrometry.
MMP selectivity was shown by the ability of recombinant MMPs (200 ng) to activate ICT2588 (20 μmol/L) by incubation at 37°C in MMP activity buffer. In parallel, MMPs were incubated with a control substrate to verify proteolytic activity. Activation was assessed by recombinant human MT1-, MT2-, MT3-, MT5-MMP, and MMP-9 (Chemicon) and MMP-1, -2, -10, -12, and -13 (R&D Systems; detailed in Supplementary Fig. S2). Aliquots of the reaction (20 μL) were removed at intervals up to 9 hours and analyzed by LC-MS.
To confirm MMP involvement in the metabolism of ICT2588, homogenates of HT1080 xenografts were coincubated with either ilomastat (GM6001; Chemicon; ref. 38), a broad-spectrum MMP inhibitor, or CTT (Biomol; ref. 39), a selective MMP-2/MMP-9 inhibitor. These homogenates were assayed for their ability to activate ICT2588 in the presence of inhibitor, as described above.
Distribution, activation, and metabolism of ICT2588 and ICT2552 were evaluated in mice bearing HT1080 tumors. Mice were injected i.p. with either ICT2588 (150 mg/kg), ICT2552 (10.2 mg/kg), or solvent (10% DMSO/arachis oil). Tumors, blood, and normal tissues (liver, kidney, lung, heart, and spleen) were collected at defined times posttreatment. Blood was centrifuged at 5,000 × g for 10 minutes, and the resulting plasma diluted 1:5 into methanol. Tissue samples were immediately frozen in liquid nitrogen prior to homogenization in ice-cold methanol. Following centrifugation, concentrations of agent and metabolites were determined in the resultant supernatants by LC-MS. Calibration samples were established using agent-free plasma and tissues.
To differentiate the activated metabolite produced by proteolysis of ICT2588 from that of the nonconjugated agent (azademethylcolchicine), these are termed ICT2552act and ICT2552, respectively.
Assessment of vascular shutdown and induction of tumor necrosis
The degree of functional tumor vasculature and proportion of hemorrhagic necrosis was assessed 24 hours following i.p. administration of ICT2552 (10.2 mg/kg), ICT2588 (150 mg/kg), or solvent (10% DMSO/arachis oil) to mice bearing HT1080 tumors, using methodologies described and detailed previously (37, 40, 41)
Mice bearing HT1080 tumors of ∼32 mm3 were randomized into groups receiving either ICT2588 (37.5, 50, 62.5, or 75 mg/kg) or the molar equivalent of its authentic metabolite (ICT2552; 7.5, 10, 12.5, or 15 mg/kg) via i.p. administration. Tumor volume (measured by calipers) and animal body weight were recorded daily for up to 64 days. Tumor volumes were calculated using the formula: (a2 × b)/2 (a being the smaller and b the larger dimension of the tumor), and normalized to the respective volume on day 0. Mann-Whitney U tests were performed to determine the statistical significance of any differences in growth rate (based on tumor volume doubling time) between control and treated groups, and between the different compounds.
For combination studies with doxorubicin, ICT2588 was administered i.p. at 75 mg/kg, whereas doxorubicin was administered i.v. at 5 mg/kg. The study involved five treatment groups: ICT2588 alone, doxorubicin alone, doxorubicin administered 20 minutes prior to ICT2588, doxorubicin administered 6 hours after ICT2588, or doxorubicin administered 24 hours after ICT2588. Tumor measurements were conducted as described above.
MMPs and MT-MMPs are differentially expressed in human preclinical tumor models
The expression profile of MMPs in human preclinical tumor models reported in the literature is incomplete. Using human cell lines and associated xenograft models representing a range of tumor types, we assessed the expression of 22 MMPs using quantitative reverse transcription-PCR. A diverse profile of MMP expression in both human tumor cell lines (Fig. 1A) and the corresponding in vivo xenograft models (Fig. 1B) was observed. High expression levels of MT1-MMP were observed in the majority of tumor models analyzed, with extremes being the fibrosarcoma model HT1080 (very high levels; CT ≤ 25) and the breast carcinoma cell line MCF7 (undetectable MT1-MMP mRNA; CT = 40). This strongly supports the presence of active MT1-MMP, as previously reported by our group (33). The differential was further confirmed at the protein level in cell lines by Western blotting (Fig. 1C), in agreement with previous studies (25, 26). In contrast with cell lines grown in vitro, a weak band corresponding to MT1-MMP protein was observed in ex vivo MCF7 tumor homogenates (Fig. 1C).
Differential activation of ICT2588 in human tumor models in vitro
HT1080 and MCF7 cells were used to assess the activation and cytotoxicity of our azademethylcolchicine-peptide conjugate (ICT2588) in vitro. HT1080 cells (MT1-MMP positive) were at least 10-fold more chemosensitive to ICT2588 than MCF7 cells (MT1-MMP negative) in vitro (Table 1). This is in contrast with exposure of the cells to the authentic metabolite, ICT2552, which was equally cytotoxic to HT1080 and MCF7 cells (Table 1). These differentials in cytotoxicity were reflected pharmacodynamically by the induction of tubulin disruption in these cell lines. ICT2552 induced tubulin foci and morphologic changes indicative of tubulin disruption in both HT1080 and MCF7 cells in vitro. In contrast, the peptide-conjugated agent (ICT2588) induced these changes in the HT1080 cell line but not the MCF7 cells in vitro (data not shown).
The lack of activity of ICT2588 against MCF7 and the lack of observable intracellular fluorescence following treatment also supported the concept that the peptide-conjugated agent, ICT2588, was inactivated and could not enter cells, thereby requiring activation by extracellular proteolysis.
MT-MMP–selective activation of ICT2588
A panel of recombinant MMPs, representing the different MMP subclasses were used to evaluate the selectivity and site of proteolytic cleavage in vitro. The type I MT-MMPs [MT1-(MMP-14), MT2-(MMP-15), MT3-(MMP-16), and MT5-(MMP-24)] hydrolyzed the glycine-homophenylalanine bond of ICT2588 (Fig. 2A; Supplementary Fig. S2). The secreted MMP-2, which is regulated by MT1-MMP (42), was also observed to activate ICT2588 through cleavage of the homophenylalanine-tyrosine bond (Fig. 2A). In contrast, activation of ICT2588 was not observed by the other recombinant-secreted MMPs evaluated.
Metabolism of ICT2588 in tumor but not normal tissues
In order for ICT2588 to be a viable therapeutic strategy, it must show activation in tumor tissue, systemic stability, and limited activation in non-diseased tissue. Metabolism of ICT2588 and formation of its authentic metabolite, ICT2552act, were studied ex vivo using HT1080 and MCF7 human tumor xenograft homogenates and murine plasma and tissues. Rapid metabolism of ICT2588 was observed in the HT1080 xenograft homogenate (t1/2 = 4.4 min). In comparison, ICT2588 was relatively stable in MCF7 xenograft homogenate (t1/2 = 33.1 min), murine liver (t1/2 = 22.0 min), and murine blood plasma (t1/2 > 40 min; Fig. 2B).
Metabolism of ICT2588 in HT1080 homogenates resulted in the rapid production of active azademethylcolchicine, with no detectable peptide-conjugated metabolites of ICT2588. To observe these metabolites, homogenates required >500-fold dilution or the reaction was conducted at 4°C (date not shown). The rapid metabolism of these intermediates to the active agent was confirmed using the chemically synthesized peptide-conjugated metabolites.
The involvement of MMPs was assessed by determining the degree of agent activation by HT1080 homogenates in the presence of the MMP inhibitor ilomastat (GM6001; ref. 38) and the MMP-2/MMP-9–selective inhibitor CTT (39). Ilomastat resulted in a dose-dependent decrease in metabolism of ICT2588 by HT1080 (Fig. 2C). In contrast, no significant inhibition of ICT2588 activation was observed in the presence of CTT (data not shown).
Tissue distribution of ICT2588 and tumor-selective activation in vivo
Following ICT2588 administration, ICT2588 and its corresponding metabolites were measured. The activated metabolite produced by proteolysis of ICT2588 is termed ICT2552act. The pharmacokinetic profile of ICT2588 (Fig. 3: Supplementary Fig. S3) shows extensive distribution of the parent agent with accumulation in the tumor tissue with time. Furthermore, a differential in ICT2552act concentration in tumor compared with normal tissues was observed (Fig. 3B; Supplementary Fig. S3). All throughout the experiment, levels of ICT2552act were below detectable levels in plasma and heart (Fig. 3C; Supplementary Fig. S3). In all tissues investigated, concentrations of activated agent (ICT2552act) following ICT2588 administration were at least 50% lower in mouse organs relative to tumor tissue. After 6 hours, ICT2552act was still present in tumor tissue but was below detectable levels in normal tissues investigated (Fig. 3C; Supplementary Fig. S3). By way of comparison, ICT2552 (as a nonconjugated agent) was widely distributed throughout the mice following i.p. administration, with the liver being representative of all normal mouse tissues (Supplementary Fig. S3). At 4 hours postadministration, the concentrations of ICT2552 were not significantly different between tumor and liver tissue, but concentrations were below the level of detection in plasma (Supplementary Fig. S3).
Induction of tumor vascular collapse and hemorrhagic necrosis following ICT2588 treatment in vivo
Administration of ICT2588 to HT1080 tumor–bearing mice resulted in a 90% decrease in the level of functional tumor vasculature (Fig. 4A). This effect was comparable to that observed following administration of ICT2552 at an equimolar concentration (80% reduction; Fig. 4A). This result is consistent with the conversion of the peptide-conjugated agent, ICT2588, to ICT2552act within the tumor in vivo (Fig. 4A). Concurrent to the induction of vascular damage within the tumor by ICT2588 was the 3-fold increase in hemorrhagic necrosis (Fig. 4B) as well as a rim of viable tumor cells, consistent with other VDA therapeutics (Fig. 4B).
Antitumor activity of ICT2588
HT1080 tumor–bearing mice were treated with the MT1-MMP–targeted agent, ICT2588 (37.5, 50, 62.5, and 75 mg/kg) or the nonconjugated agent, ICT2552, at equimolar doses (7.5, 10, 12.5, and 15 mg/kg), and tumor growth compared with vehicle-treated controls. ICT2588 resulted in a significant antitumor response, with growth delays of between 2.0 and 5.6 days (P < 0.01; Fig. 5A); one mouse in the 62.5 mg/kg ICT2588 group showed a complete tumor remission. In contrast, ICT2552 at equimolar doses produced a significantly lower antitumor response (Fig. 5B). At all doses used, administration of ICT2588 led to no significant loss in mouse body weight (maximum of 6%; data not shown).
Coadministration of ICT2588 with doxorubicin
Combination therapy of ICT2588 and doxorubicin in mice bearing HT1080 tumors produced a significant tumor response in all treatment groups relative to controls, ICT2588 or doxorubicin as a single agent. Administration of ICT2588 6 hours prior to doxorubicin (14-d growth delay) showed no significant difference in the antitumor activity observed compared with coadministration of both agents simultaneously (19-d growth delay). However, administration of doxorubicin to mice with established ICT2588-induced vascular collapse (24 h) resulted in a significantly greater effect than dosing each agent alone and results in complete tumor remission or cure in the majority (four of seven) of treated mice (Fig. 5C). This result was obtained using ICT2588 and doxorubicin at 50% and 30% of their maximum deliverable doses, respectively.
Disruption of the vascular supply to tumors is recognized as an effective therapeutic strategy (1, 2). Several colchicine-based VDAs have shown preclinical efficacy, but none have yet progressed through clinical trials. One reason for the lack of clinical progression of these VDAs is the prevalence of off-target effects on the cardiovascular system (2, 5, 6). A strategy to improve tumor selectivity with attendant diminution of systemic toxicity, and hence, improved therapeutic index is an attractive approach to the development of VDAs. Consequently, we have preclinically designed and developed ICT2588 as a novel approach to the selective delivery of a VDA to be activated by MT-MMP endopeptidase in the tumor microenvironment.
Elevated expression of the class-I transmembrane MMPs, particularly MT1-MMP, was shown in a large number of tumor types across a panel of preclinical tumor models. Increased proteolytic activity in these tumors is supported by our previous study which showed a direct relationship between MT1-MMP mRNA expression and enzyme activity (33). Previous studies have also shown a correlation between MT1-MMP expression and malignancy of different tumor types (14, 15, 25). The detection of low levels of MT1-MMP protein in MCF7 xenografts (in contrast with MCF7 cells in vitro) indicates that MT1-MMP is also present in murine tumor stroma (18, 43) and tumor neovasculature (25, 44). Hence, we rationalize that MT1-MMPs are available as a potential trigger for tumor-selective drug activation in a wide range of tumor types.
We designed and evaluated ICT2588, a COOH-terminal– and NH2-terminal–modified peptide conjugate of the VDA azademethylcolchicine (ICT2552). ICT2588 possesses a peptide sequence rationalized to be specifically activated by MT1-MMP and was end-capped at its COOH terminus to prevent nonspecific exopeptidase degradation.
We showed conversion of ICT2588 to its active metabolite (ICT2552act) and differential in vitro chemosensitivity in HT1080 (high MT1-MMP) but not in MCF7 (undetectable MT1-MMP) tumor cells. MMP dependency was shown by the lack of ICT2588 activation in the presence of the pan-MMP inhibitor ilomastat. In addition, MMP selectivity was supported by the cleavage of ICT2588 at the glycine-homophenylalanine bond by MT-MMPs but not by secreted MMPs. Although activation by MMP-2 was also evident at the P1′–P2′ position (homophenylalanine-tyrosine), this endopeptidase is not a major contributor to ICT2588 activation because hydrolysis was not significantly diminished by an MMP-2–selective inhibitor (CTT). Furthermore, MMP-2 activation is dependent on MT1-MMP activity (42).
This therapeutic strategy relies on specific MT-MMP activation of ICT2588 followed by subsequent nonspecific exopeptidase cleavage to produce azademethylcolchicine (ICT2552), the active VDA. In our analyses of tumor metabolism of ICT2588 in vivo and ex vivo, we observed only ICT2552act and no peptide-fragment metabolites of ICT2552. We interpret this to infer that MT-MMP cleavage of ICT2588 is followed by rapid exopeptidase-mediated degradation of the consequent ICT2552act-peptide fragments to produce ICT2552act.
Previous attempts to produce a MMP-activated peptide-conjugate of a chemotherapeutic were unable to produce agents that were sufficiently stable or tumor-selective in vivo (31). However, our study showed the stability of ICT2588 (peptide-conjugated VDA) in plasma and liver relative to rapid production of the active VDA (ICT2552act) in tumor ex vivo, a finding confirmed by widespread distribution and stability of the nontoxic ICT2588 in vivo coupled to tumor-specific activation to ICT2552act. Accumulation of ICT2588 and ICT2552act in the tumor may be due to the induction of vascular collapse and trapping of ICT2588 in the tumor microenvironment facilitating the prolonged availability of ICT2588 for metabolism by the MT1-MMP–dependent angiogenic tumor neovasculature.
Formation of active VDA in the tumors in vivo is consistent with the several-fold decrease in functional tumor vasculature and increased hemorrhagic necrosis, an observation consistent with the pharmacodynamics of other colchicine-like VDAs, such as ZD6126 and the combretastatins (2). Although equimolar doses of ICT2588 and ICT2552 caused comparative vascular shutdown, the magnitude of this effect was not consistent with their respective antitumor activities. Specifically, ICT2588 (75 mg/kg) produced a significant 2-fold greater growth delay (4.4 d; P < 0.01) compared with an equimolar dose of ICT2552 (15 mg/kg; 1.9 d). Furthermore, despite both the peptide-conjugated agent (ICT2588) and its authentic metabolite (ICT2552) demonstrating dose-response relationships, a significantly greater response was observed with equimolar equivalents of ICT2588. The superior efficacy of ICT2588 is likely due to the improved tumor-directed delivery and thus increased and prolonged tumor concentration of active VDA (ICT2552) in the peptide-conjugated form compared with the widely distributed and systemically active ICT2552.
Although monotherapy with ICT2588 resulted in a significant antitumor effect, a viable rim of tumor cells remained following treatment. The presence of this viable rim is consistent with previous reports following VDA treatment (1, 2) and is believed to be the result of these tumor cells receiving their nutrients and oxygen from the established vasculature of the surrounding normal tissues rather than the VDA-sensitive tumor vasculature (4). Consequently, the viable rim can be targeted by cotreatment with antiproliferative agents (2). In support of this, the combination of ICT2588 with doxorubicin resulted in a significant antitumor response, and more importantly, tumor cures in the majority of mice. The combination of ICT2588 and doxorubicin was superior to monotherapy irrespective of dosing and sequence schedule. The increased antitumor benefit of cotreatment with doxorubicin, 24 hours after ICT2588, is likely a result of doxorubicin targeting the proliferative cells in the viable rim, which are nonresponsive to ICT2588, and the ICT2588-mediated elimination of poorly perfused tumor areas, which are likely to be inaccessible or resistant to doxorubicin (45, 46). Mobilization of circulating endothelial cells into this region might also contribute to antitumor benefit, as suggested for ZD6126 and paclitaxel (45).
Clinical studies show that VDAs could demonstrate efficacy below their maximum tolerated doses; an observation consistent with ICT2588. This was the case with ICT2588 and doxorubicin in our study, suggesting that additive toxicity would be unlikely. The cardiovascular toxicity associated with several VDAs in clinical trials (5–7) is unlikely with ICT2588 because the circulating and cardiac levels of the active agent (ICT2552) are undetectable. This suggests a greater therapeutic index for ICT2588 relative to other VDAs due to the tumor-selective release and elevated tumor concentrations of ICT2552act, and the potential for reduced off-target toxicities. In conclusion, the significant therapeutic efficacy, in vivo stability, mechanism of action, tumor-selective release, and potential for circumventing systemic toxicity associated with systemically active VDAs strongly support ICT2588 as a potential therapeutic for the clinic.
Disclosure of Potential Conflicts of Interest
No potential conflicts of interest were disclosed.
We thank Patricia Cooper for in vivo studies.
Grant Support: This work at the Institute of Cancer Therapeutics was supported by programme grants from Cancer Research-UK and Yorkshire Cancer Research. The work by D.R. Edwards and C.J. Pennington was supported by a Cancer Research-UK project grant.
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.
- Received April 27, 2010.
- Revision received July 13, 2010.
- Accepted July 13, 2010.
- ©2010 American Association for Cancer Research.