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Synergy between Methionine Stress and Chemotherapy in the Treatment of Brain Tumor Xenografts in Athymic Mice¹

Departments of Neurological Surgery [D. M. K., J. B. W.], and Internal Medicine [E. P. F.], University of Texas Southwestern Medical Center, Dallas, Texas 75390; The University of Pittsburgh Cancer Institute, Pittsburgh, Pennsylvania 15213 [S. C. S.]; and Anticancer Inc., San Diego, California 92111 [ R. M. H., Q. H., M. X., Y. T.]

	ABSTRACT

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This study describes a novel approach to the treatment of brain tumors with the combination of recombinant L-methionine--deamino--lyase and chemotherapeutic regimens that are currently used against such tumors. The growth of Daoy, SWB77, and D-54 xenografts in athymic mice was arrested after the depletion of mouse plasma methionine (MET) with a combination of a MET- and choline-free diet and recombinant L-methionine--deamino--lyase. The treated tumor-bearing mice were rescued from the toxic effects of MET withdrawal with daily i.p. homocystine. This regimen suppressed plasma MET to levels below 5 µM for several days, with no treatment-related deaths. MET depletion for 10–12 days induced mitotic and cell cycle arrest, apoptotic death, and widespread necrosis in tumors but did not prevent tumor regrowth after cessation of the regimen. However, when a single dose of 35 mg/m² of N,N'-bis(2-chloroethyl)-N-nitrosourea (BCNU), which was otherwise ineffective as a single therapy in any of the tumors tested, was given at the end of the MET depletion regimen, a more than 80-day growth delay was observed for Daoy and D-54, whereas the growth of SWB77 was delayed by 20 days. MET-depleting regimens also trebled the efficacy of temozolomide (TMZ) against SWB77 when TMZ was given to animals as a single dose of 180 mg/m² at the end of a 10-day period of MET depletion. The enhanced responses of both Daoy and SWB77 to DNA alkylating agents such as BCNU and TMZ could be attributed to the down-regulation of O⁶-methylguanine-DNA methyltransferase activity. However, the synergy of MET depletion and BCNU observed with D-54 tumors, which do not express measurable O⁶-methylguanine-DNA methyltransferase protein, is probably mediated by a different mechanism. MET depletion specifically sensitizes tumors to alkylating agents and does not significantly lower the toxicity of either BCNU or TMZ for the host. In this regard, the combination approach of MET depletion and genotoxic chemotherapy demonstrates significant promise for clinical evaluation.

	INTRODUCTION

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The prognosis for patients with glioblastoma and anaplastic astrocytoma has changed little despite aggressive cytoreductive surgery, radiation, and chemotherapy (1) . The propensity of individual neoplastic cells to migrate along white matter pathways (2) renders treatment directed solely at the main tumor mass of palliative benefit only. To date, no treatment has been developed that is capable of destroying all residual neoplastic cells within tissue remaining after surgery or radiation therapy, and these residual cells serve as the reservoir from which brain tumors may progress and recur (2) . The failure of chemotherapy to significantly enhance survival by killing or delaying regrowth of tumors from residual neoplastic reservoirs remains challenging. Bifunctional nitrosoureas such as BCNU³ and N-(2-chloroethyl)-N'-cyclohexyl-N-nitrosourea have had only modest objective responses in patients with anaplastic gliomas (3) . The limited responses appear to be due to mechanisms of resistance (4, 5, 6) . More recently, the methylating drug TMZ has shown promising activity against astrocytomas and glioblastomas, but again, resistance mechanisms in the majority of astroglial tumors have limited its effectiveness (7 , 8) .

An important and well-characterized mechanism contributing to the resistance of brain tumors to the nitrosoureas and DNA methylating drugs is the up-regulation of AGT during neoplastic progression (9 , 10) . AGT confers resistance to agents that exert their cytotoxic action via the formation of O⁶-alkylguanine adducts, which either form lethal double-strand cross-links, as is the case with bifunctional nitrosoureas such as BCNU and N-(2-chloroethyl)-N'-cyclohexyl-N-nitrosourea (11) , or interfere with mismatch repair mechanisms resulting in an abortive repair and cell death, as is the case with TMZ, procarbazine, and other DNA methylating agents (12, 13, 14) . The role of AGT in the resistance of brain tumors to DNA alkylating drug therapy has been demonstrated with the use of AGT inactivators, such as BG and O⁶-benzyl-2'-deoxyguanosine (15, 16, 17) , which enhance the efficacy of a variety of DNA alkylating agents against brain tumor xenografts in mice (18, 19, 20) . These observations suggested that drugs that have been marginally active against brain tumors in the past could be successfully reintroduced in combination with AGT inhibitors (21) . A number of clinical trials are currently in progress to determine the feasibility of such a strategy (21, 22, 23) . Unfortunately, the AGT inhibitors currently available are not tumor specific, so they sensitize normal tissues as well as the tumor to the cytotoxic effect of the alkylating drug (24 , 25) . An alternate strategy to achieve specific depletion of tumor AGT has been considered by introducing AGT inhibitors as prodrugs that are activated exclusively by the tumor, but synthesis of tumor-specific AGT inhibitors has not yet been realized.

A method to deplete AGT activity in certain tumors that display strong MET dependence has been developed in culture by MET deprivation and substitution of this essential amino acid with HCYS precursors (26) . MET-dependent tumor cells down-regulate their AGT activity in response to MET deprivation and, as a result, show enhanced tumor cell kill with BCNU (26) . Because we have demonstrated that various degrees of MET dependence are a common finding in brain tumors and because we have developed a method to achieve consistent and protracted depletion of plasma MET levels (27) , the current study examines the effect of MET deprivation on the growth of human brain tumor xenografts in athymic mice. In addition, it evaluates the potential synergism of the MET-depleted state and chemotherapy with BCNU and TMZ as compared with the normal nutritional state. The MET depletion was achieved by dietary restriction and the use of recombinant L-methionine--deamino--lyase (methioninase.)

	MATERIALS AND METHODS

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Chemicals.
rMETase was prepared at AntiCancer Inc. from an rMETase high expression clone derived from Pseudomonas putida. This was used for the production of rMETase in Escherichia coli (28 , 29) . The rMETase was purified with a DEAE-Sepharose (fast flow) column. Endotoxin was removed with an Acticlean Etox (Sterogen, Arcadia, CA) column. The isolated rMETase was 98% pure by HPLC and a single band of M_r 43,000 on SDS-PAGE. The specific activity of rMETase used in this study was 20 units/mg protein, and the endotoxin level was <0.2 units/mg (28) . The K_m for MET and HCYS was 0.7 and 1.7 mM, respectively, whereas the V_max for these two substrates was determined as 0.07 µM/min/unit.⁴ HCYSS was not a substrate for rMETase.⁴ BCNU was purchased from Bristol-Myers Squibb (Princeton, NJ), and TMZ was donated by Schering-Plough Inc. (Madison, NJ).

Animals.
Four-week-old BALB/c-nu/nu athymic mice were purchased from Harlan Laboratories (San Diego, CA). Mice were maintained under filter air barrier conditions and given sterilized food and water.

Tumor Lines.
MET-dependent tumor cell line D-54 and SWB77 (human glioblastomas) and Daoy (human medulloblastoma) xenografts used in this study were grown in our laboratory. Cell lines were propagated in 5% fetal bovine serum (Life Technologies, Inc., Gaithersburg, MD) in Eagle’s MEM (Life Technologies, Inc.) and supplemented with lysine, valine, MET, and leucine (100 mM each); nonessential amino acids (1:100 dilution of stock from Life Technologies, Inc.); 1 mM sodium pyruvate; 1 µM -hydroxy-cobalamin; 10 µM folic acid; and 0.2 mg/ml gentamicin. s.c. tumors grew after injection of 3–4 million cells/animal. Daoy xenografts were propagated in athymic mice and macerated and frozen in 18% DMSO in fetal bovine serum at -70°C until use. Tumor xenografts of D-54, SWB77, and Daoy had AGT activities of <10, 75, and 376 fmol/mg protein, respectively, as determined by biochemical assay. Respective mitotic indices in the xenografts were 5.5, 5.7, and 18.9 mitotic figures per high power field (x400). Some core necrosis was observed in growing Daoy tumors, in agreement with the rapid growth pattern of this tumor, but D-54 and SWB77 tumors showed no necrotic patterns. However, even in Daoy tumors, necrosis was significant in tumor sizes exceeding 500–600 mm³; thus, it did not interfere with the assessment of drug-induced necrosis in the tumors treated in this study.

Diets.
The following pelleted synthetic, mouse formulated diets were prepared by Dyets (Bethlehem, PA). The amino acid defined Lombardi diet without DL-HCYS (diet 518786) is referred to as MET(+)HCYS(-)CHOL(+). The DL-HCYS, choline-deficient diet (diet 518763) is referred to as MET(+)HCYS(-)CHOL(-). Diet 518787 contained 1.7 g/kg DL-HCYS and was MET and choline deficient. It is referred to as MET(-)HCYS(+)CHOL(-). Diet 518788 was devoid of MET, HCYS, and choline and is referred to as MET(-)HCYS(-)CHOL(-). With the exception of the latter diet, all diets were efficient in maintaining growth of athymic mice. The composition of these entirely defined synthetic diets has been published previously (27) . MET(+)HCYS(-)CHOL(+) supported growth of the human tumor xenografts in athymic mice and the growth of athymic mice equally as well as a natural basal diet (Teklad Laboratory diet; Harlan, Indianapolis, IN). All experimental animals received a basal Harlan Teklad laboratory mouse diet until they weighed 16–18 g. At that time, animals were inoculated s.c. with tumors and switched to a MET-deficient synthetic diet with or without choline, as described in individual experiments. METdrs were administered 48 h after withdrawal of dietary MET by switching to the MET(-)HCYS(+)CHOL(-) or the MET(-)HCYS(-)CHOL(-) diets. The latter diet was supplemented with 20 mg/kg daily i.p. injections of HCYSS to maintain the functions of normal tissue.

Drug Treatment.
rMETase was administered i.p. at a dose of 1500 units/kg every 8 h (unless otherwise noted) for 10–12 days in animals receiving MET-free diets. Sterile enzyme was given in a volume of 30 ml/m² surface area in PBS. BCNU was administered i.p. in ethanol in water from a stock solution of 20 mg/ml in anhydrous ethanol. Depending on the dose of BCNU, the injected ethanol carrier varied from 10–15% and was given in a volume of 20 ml/m². TMZ was dissolved in DMSO and administered i.p. in a volume of 20 ml/m². Drug doses were calculated as mg/m² using the formula m² = weight (g)^2/3 x K x 10^-4, where K is 10.5 for mice (30) . In animals of 20 ± 2 g used in this study, the weight (in kg) of the animal is approximately 2.6 x the area surface (in m²).

Tumor Implantation and Treatment.
Approximately 3 x 10⁶ D-54, SWB77, or Daoy cells in 200 µl of 5% serum media were injected s.c. in the left flank of 6-week-old athymic mice weighing between 18 and 20 g. Visible tumors appeared in most of the animals within 3–5 weeks after implantation. The tumors were subsequently measured in two perpendicular dimensions, and their volumes were estimated using the formula (² x ß)/2, where is the shorter of the two dimensions, and ß is the longer of the two dimensions. Treatment was administered to animals with tumors ranging between 120 and 160 mm³ (approximately 4–5 weeks after implantation, depending on the tumor). Tumor mass was measured every other day or as otherwise indicated until tumor volumes exceeded 5x the volume of the tumor at treatment. The data were analyzed using Wilcoxon’s rank-sum test, comparing the time from treatment to 5x treatment volume in individual animals in each of the groups. T - C was the difference between the median time to 5x treatment volume in the treatment group minus the median time to 5x treatment volume in the control group. The number of tumor regressions was also determined. The time tumors started to regress as a result of MET-depleting conditions depended on the tumor. When the METdr was not combined with the chemotherapeutic agent or chemotherapy was applied alone, regression was scored as a >10% maintained reduction of original tumor size over three consecutive daily measurements. When these two treatments were combined, regression was scored for the reduction of tumor size by at least 20% during the entire treatment period (10 days of MET deprivation and 5 days after BCNU or TMZ treatment) as compared with tumor size at the beginning of treatment. A complete response was defined as the disappearance of measurable tumor mass (<1 mm) at some point within a 12-week period after initiation of treatment. A maintained complete response was defined as no tumor regrowth within 12 weeks of completing the treatment regimen. Toxicity was evaluated by animal weight reduction after treatment with the METdr and the drug. Tumor regressions were compared among groups with the two-tailed Fisher’s exact test. Experimental groups were treated with (a) METdrs alone, (b) METdrs followed by a single injection of BCNU, or (c) METdrs followed by a single injection of TMZ. Various dietary combinations were tested with each of the treatments. Control animal groups included (a) animals treated with BCNU alone, (b) animals treated with TMZ alone, and (c) animals treated with the carrier (15% ethanol or DMSO) alone. Control animals received either a MET(+)HCYS(-)CHOL(+) or a MET(+)HCYS(-)CHOL(-) diet throughout.

Determination of MET and HCYS.
MET and HCYS content in plasma was determined by HPLC with electrochemical detection using a Coularray detector equipped with a four-channel 5010 graphite electrode (ESA, Chelmsford, MA) set at 520, 650, 750, and 850 mV operating potentials according to the following method: 150 µl of plasma were mixed with 75 µl of penicillamine (internal standard) and 25 µl of 60 mg/ml Tris 2-carboxy-ethyl-phosphine. Tubes were capped, vortexed for 60 s, and allowed to stand for 10 min at room temperature. The samples were cooled on ice, and 500 µl of ice-cold 0.3 N perchloric acid were added. The tubes were capped tightly, vortexed for 30 s, and centrifuged for 5 min at 10,000 rpm. A 100-µl aliquot of the supernatant was transferred into an ESA 542 autosampler operating at 5°C, and 20 µl were injected onto an 80 x 4.6-mm ESA HR-80 C-18 three µm HPLC column (ESA) equilibrated at 30°C. The sample was eluted isocratically with a mixture of 10% acetonitrile in 0.15 M phosphate buffer (pH 2.9) containing 1.0 mM SDS. HCYS, penicillamine, and MET were eluted at 5.1, 6.7, and 8.6 min, respectively, and identified and quantitated by the ratios of the detector’s response at the operating potentials.

AGT Assay.
Tumors were divided in 0.2–0.3-cm-thick sections with a razor. These sections were sampled, avoiding apparent necrotic and vascular areas. Half of the samples were processed for histology (H&E staining), whereas the other half, adjacent to those selected for histology, were used to measure AGT levels. Samples were homogenized in 20 mM Tris, 0.1 mM EDTA, and 2 mM DTT at 0°C, and protein was determined by the Bradford assay (31) . The AGT assay was performed by using a slightly modified version of a method described previously (26) . [³H]DNA dissolved in 20 mM Tris, 0.1 mM EDTA, and 2 mM DTT (pH 7.8) and containing 60 fmol of O⁶-MeG (total dpm, 24 x 10³) was incubated with 100–500 mg of protein for 1 h at 37°C in a final volume of 500 µl. The reaction was quenched with 0.1 ml of 1 N HCl, and samples were incubated for an additional 45 min at 70°C. Samples were cooled on ice for 1 h, 500 µl of cold ethanol were added, and the mix was centrifuged at 14,000 x g for 5 min. The supernatant was removed and neutralized with sodium bicarbonate and dried by lyophilization. Lyophilized samples were dissolved in 0.12 ml of 0.01 M HCl, spun at 14,000 x g, and analyzed by HPLC using a Supelcosil-C18DB analytical column (Supelco, Inc.). Samples were eluted at a flow rate of 1.5 ml/min with 2% acetonitrile in 0.1 M phosphate buffer (pH 3.5; 0–5 min) followed by a gradient scintillation counting. 7-Methylguanine (7-MeG) and O⁶-MeG were eluted at 4.5 and 13 min, respectively. The ratio of radioactivity of O⁶-MeG:7-MeG from four samples of varying protein concentration was derived and plotted against the amount of protein. The intercept of the central linear response of the curve (between ratios 0.9 and 0.3) with the X axis marks the amount of protein needed to remove 60 fmol of O⁶-MeG from DNA. The assay is highly specific for AGT activity and can detect AGT levels as low as 5 fmol/mg protein with an error of 10%.

Histology.
Fresh livers were harvested from animals in the different dietary groups immediately after sacrifice and immersion fixed in 10% neutral buffered formalin. After overnight fixation, the tissue was dehydrated in graded alcohol solutions to xylene and embedded in paraffin. Sections (6 µm) were cut from the paraffin blocks on a standard rotary microtome, stained with H&E, and evaluated by light microscopy by an observer blinded to the dietary status of the animal.

	RESULTS

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Effect of Dietary MET and Choline on Animal and Tumor Growth.
Growth of animals was not altered when the basal diet was replaced with complete amino acid synthetic diets. In general, animals weighing between 18 and 22 g gained weight at a rate of 0.70 g/day (range, 0.61–1.00 g/day) when fed a synthetic diet sufficient in MET and choline. Growth of 0.60 g/day (range, 0.44–0.77 g/day) was observed when choline was restricted. In comparison, animals given a basal (natural) diet gained 0.55 g/day (range, 0.38–0.78 g/day). Replacement of dietary MET with HCYS in the absence of choline resulted in slower growth of 0.31 g/day (range, 0.22–0.36 g/day). Restriction of MET, choline, and HCYS resulted in severe initial weight loss of 0.9 g/day (range, 0.7–1.1 g/day) and death in 10–14 days. However, when animals fed a MET-, choline-, and HCYS-restricted diet were injected i.p. with 20 mg/kg HCYSS on a daily basis, weight loss was minimized to 0.2–0.3 g/day for the first 10 days. Animals given this type of METdr were alive and healthy for at least 40 days.

None of the tumors tested in these experiments (Daoy, D-54, and SWB77) grew consistently as xenografts in athymic mice fed a MET- and choline-deficient diet, even when HCYS was supplied either in the diet or i.p. In animals fed synthetic diets containing MET and choline, the tumors grew at rates comparable with those observed in animals fed a basal diet. Daoy, D-54, and SWB77 quintupled in 10, 8, and 13 days, respectively, when the host received the MET- and choline-sufficient synthetic diet. Withdrawal of choline resulted in a slight decrease of the rate of animal growth but a marked delay in the establishment of the Daoy and SWB77 tumor xenografts. However, once tumor xenografts were established, they quintupled at rates that were not statistically different from those of xenografts growing in animals fed the complete synthetic diet. These results demonstrate that a synthetic diet sufficient in MET but lacking choline can support the growth of tumor xenografts in athymic mice; therefore, this diet was used after tumor implantation.

Depletion of Plasma MET.
Reduction of plasma MET below 5 µM arrests human xenograft growth in athymic mice (27) . Such low levels have been achieved with a combination of dietary and pharmacological means. As shown in Table 1 , plasma MET was 67 µM in athymic mice bearing 200–300 mm³ Daoy xenografts and fed a synthetic diet that was sufficient in choline, MET, and folates. A 7-day deprivation of dietary choline resulted in the decrease of plasma MET to a third of its base value. Similar MET levels were obtained by restricting MET and choline while supplementing with dietary HCYS. To lower plasma MET below 5 µM, it was necessary to restrict dietary MET, HCYS, and choline and administer 1500 units of rMETase i.p. every 8 h. HCYSS, 20 mg/kg once a day i.p., was used as a rescue agent. As shown in Table 1 , depletion of MET was achieved as early as 2 days after combining a MET-, choline-, and HCYS-deficient diet with rMETase and HCYSS, providing that animals had been adapted to choline deprivation for at least 7 days. With the exception of the MET(-)HCYS(+)CHOL(-) diet, which resulted in a marked increase in the total HCYS in plasma, all other diets and treatments had only a modest effect on HCYS levels. Supplementing HCYSS i.p. during administration of the MET(-)HCYS(-)CHOL(-) diet did not raise the level of plasma HCYS over that of animals fed the MET(+)HCYS(-)CHOL(+) diet.

View larger version (20K): [in this window] [in a new window] [Download PPT slide]   Fig. 1. Time course of down-regulation of AGT activity in viable tumor segments during treatment of athymic mice bearing Daoy (•) or SWB77 () tumor xenografts with a METdr. Animals were placed on a MET(+)HCYS(-)CHOL(-) diet after implantation of the tumor, and when tumors reached 200 mm3, the diet was switched to MET(-)HCYS(-)CHOL(-), and animals were treated with 1500 units/kg rMETase i.p. every 8 h and 20 g/kg HCYSS i.p. every 24 h for the time intervals indicated. Data are the mean from five animals ± SD.

View larger version (24K): [in this window] [in a new window] [Download PPT slide]   Fig. 2. Effect of a 12-day METdr and subsequent BCNU treatment on the growth of human (Daoy) medulloblastoma xenografts implanted s.c. in athymic mice. The METdr [animals were fed a MET(-)HCYS(-)CHOL(-) diet and treated with 1500 units/kg RMETase i.p. every 8 h and 20 mg/kg HCYSS i.p. every 24 h] was initiated when tumors reached a volume of 120–160 mm3. Animals were given a MET(+)HCYS(-)CHOL(-) diet before METdr and returned to the same diet after 12 days of treatment. , untreated controls fed a MET(+)HCYS(-)CHOL(-) diet; •, animals given BCNU (35 mg/m2) with a MET(+)HCYS(-)CHOL(-) diet throughout; , animals given BCNU (65 mg/m2) with a MET(+)HCYS(-)CHOL(-) diet throughout; , animals on a 12-day METdr followed by a MET(+)HCYS(-)CHOL(-) diet; , animals on a METdr followed by a MET(+)HCYS(-)CHOL(-) diet + a single treatment with BCNU (35 mg/m2) administered 8 h after termination of METdr.

Toxicity of METdrs.
Of the organs examined, only the liver was histopathologically affected in mice subjected to METdrs. Histological evaluation of the livers from all animals undergoing MET-depleting treatments revealed preservation of the native hepatic architecture, with variable degrees of hepatocellular lipid accumulation (steatosis) in all animals. The degree of steatosis was influenced considerably by the dietary status of the animal. A 12-day administration of a MET(-)HCY(-)CHOL(-) diet with concomitant treatment with i.p. HCYSS and rMETase was associated with mild hepatocellular lipid accumulation most conspicuously in the mid-zonal areas of the liver (Fig. 3a) . A METdr based on the MET(-)HCY(+)CHOL(-) diet induced more severe steatosis, with similar mid-zonal distribution (Fig. 3b) . Histological sections of livers obtained from animals after reintroduction of dietary MET after termination of a 12-day METdr revealed the persistence of macrovesicular steatosis similar to that seen in the animals maintained previously on MET-deficient diets, with superimposed, more generalized microvesicular steatosis (Fig. 3, c and d) .

View larger version (211K): [in this window] [in a new window] [Download PPT slide]   Fig. 3. Toxicity of METdrs on the liver of athymic mice. a, liver from an animal maintained on a MET(-)HCYS-)CHOL(-) diet and i.p. HCYSS (20 mg/kg) daily while on treatment with rMETase for 12 days, demonstrating very mild macrovesicular fat accumulation within hepatocytes (stained with H&E; original magnification, x150). b, liver from an animal maintained on a MET(-)HCYS(+)CHOL(-) diet while on treatment with rMETase for 12 days, demonstrating the presence of large lipid droplets within hepatocytes, most conspicuously within the mid-zonal region (stained with H&E; original magnfication, x150). c, liver from an animal initially maintained on a MET(-)HCYS(-)CHOL(-) diet + i.p. HCYSS (20 mg/kg) while on treatment with rMETase for 12 days followed by reintroduction of dietary MET for 10 days reveals a mixed macro- and microvesicular steatosis pattern (stained with H&E; original magnification, x100). d, liver from an animal initially maintained on MET(-)HCYS(+)CHOL(-) diet while treated with rMETase for 12 days followed by reintroduction of dietary MET for 10 days. A widespread accumulation of small fat droplets (microvesicular steatosis) is present, in addition to the macrovesicular fat noted in MET-deficient animals (stained with H&E; original magnification, x100).

	DISCUSSION

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Despite the failure of MET deprivation alone to sustain prolonged inhibition in tumor growth, such an approach has considerable potential when used in combination with chemotherapy due to the remarkable synergy between MET depletion and DNA-damaging chemotherapeutic agents such as BCNU and TMZ. Both Daoy and D-54 xenografts did not regrow for at least 80 days after combined treatment with MET-deprivation and BCNU, despite the resistance of both tumors to BCNU (32) . Synergy between MET deprivation and BCNU (35 mg/m²) was also observed in the highly resistant glioblastoma SWB77 xenografts. A more pronounced synergy was observed with TMZ, which, in combination with MET depletion, delayed SWB77 growth by 39 days, which was significantly longer (P < 0.005) than the delays induced by TMZ (12 days) or MET deprivation alone (11 days).

The mechanism by which MET stress sensitizes tumors to alkylating agents is not understood. Resistance to BCNU in Daoy is primarily due to the presence of AGT (18 , 20) . The strong correlation between AGT depletion with BG administration or AGT down-regulation by MET depletion therapy on one hand, and the acquisition of BCNU sensitivity on the other, provides strong support that elimination of AGT levels in Daoy is a major pathway for the reversal of the resistance to BCNU when BCNU is combined with METdrs. The role of AGT down-regulation in sensitizing SWB77 is less clear. Growth of SWB77 xenografts is not delayed by BCNU unless AGT is first depleted with an AGT inhibitor, such as BG (32) . However, even with BG pretreatment, the BCNU-induced growth delay for SWB77 is only 11 days (32) as compared with 20 days shown for BCNU combined with a METdr. A similarly greater synergy of METdrs + TMZ than BG + TMZ (32) indicates that the greater tumor growth delay observed with TMZ in combination with MET depletion (39 days) than with TMZ alone (12 days) is probably not the result of AGT down-regulation alone. The possible modulation of mechanisms of DNA repair, other than AGT, by MET deprivation is further corroborated by the unexpected response of D-54 to MET stress + BCNU treatment. MET deprivation enhances the efficacy of BCNU against the AGT-deficient D-54 by far more than the expected marginal effect observed previously by direct AGT inhibition (43 , 44) . Additional studies are needed to explore the full effect of MET stress on the resistance mechanisms of gliomas to alkylation damage.

The synergy between MET depletion and alkylating agents becomes even more interesting when we take into account its tumor specificity. Unlike DNA repair system inhibitor drugs, which sensitize normal tissue to genotoxic agents, MET depletion does not appear to affect the resistance of normal tissue to either BCNU or TMZ. MET depletion does cause certain changes in the liver of the mouse hosting the tumor, but these changes are diet related and reversible. Thus the reduction of the animal weight during MET deprivation regimens is due to nutritional imbalances rather than to the toxicity of the regimen. The down-regulation of the tumor xenograft AGT, but not of that of the liver or brain, during MET deprivation is in full agreement with a specific sensitization of the tumor xenograft to BCNU and TMZ in the athymic mouse model.

The experiments presented here show a strong synergy between marked depression of plasma MET and the genotoxic drug BCNU against Daoy and D-54 brain tumor xenografts. Near eradication of these two tumors suggests that MET deprivation not only eliminates AGT-related resistance, which was expected, but probably incapacitates other mechanisms and pathways that render BCNU ineffective against some low AGT-containing tumors. Despite the synergy between MET deprivation and TMZ that was also observed with glioblastoma tumor xenograft SWB77, this tumor still resisted this combined modality therapy approach. Such persistent resistance suggests that MET deprivation may not be best combined with these two agents against all MET-dependent tumors. Additional genotoxic compounds must be evaluated in combination with MET-depleting conditions to take advantage of the apparent modification of tumor cell resistance by the stress induced from a short supply of exogenous MET.

	ACKNOWLEDGMENTS

 
We thank Qing Xian Zhou for excellent technical contributions and Dr. Dennis K. Burns for assistance in histology.

	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.

¹ Supported by Grants CA 78561, CA 57725, and CA 86166 from the National Cancer Institute and the Children’s Brain Tumor Foundation of the Southwest.

² To whom requests for reprints should be addressed, at Department of Neurological Surgery, University of Texas Southwestern Medical Center, 5323 Harry Hines Boulevard, Dallas, TX 75390-9186. Phone: (214) 648-6314; Fax: (214) 648-3707; E-mail: dkokki{at}mednet.swmed.edu

³ The abbreviations used are: BCNU, N,N'-bis(2-chloroethyl)-N-nitrosourea; AGT, O⁶-alkylguanine-DNA alkyltransferase; BG, O⁶-benzylguanine; HCYS, homocysteine; HCYSS, homocystine; MET, methionine; METdr, methionine-depleting regimen; rMETase, recombinant methioninase; TMZ, temozolomide; HPLC, high-performance liquid chromatography; T - C, growth delay; O⁶-MeG, O⁶-methylguanine.

⁴ D. M. Kokkinakis, unpublished observations.

Received 11/ 8/00. Accepted 3/16/00.

	REFERENCES

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1. Avgeropoulos N. G., Batchelor T. T. New treatment strategies for malignant gliomas. Oncologist, 4: 209-224, 1999.[Abstract/Free Full Text]
2. Silbergeld D. L., Chicoine M. R. Isolation and characterization of human malignant glioma cells from histologically normal brain. J. Neurosurg., 86: 525-531, 1997.[Medline]
3. Levin V. A., Prados M. R., Wara W. M., Davis R. L., Gutin P. H., Phillips T. L., Lamborn K., Wilson C. B. Radiation therapy and bromodeoxyuridine chemotherapy followed by procarbazine, lomustine, and vincristine chemotherapy for the treatment of anaplastic gliomas. Int. J. Radiat. Oncol. Biol. Phys., 32: 75-83, 1995.[Medline]
4. Belanich M., Pastor M., Randall T., Guerra D., Kibitel J., Alas L., Li B., Citron M., Wasserman P., White A., Eyre H., Jaeckle K., Schulman S., Rector P., Prados M., Coons S., Shapiro W., Yarosh D. Retrospective study of the correlation between DNA repair protein alkyltransferase and survival of brain tumor patients treated with carmustine. Cancer Res., 56: 783-788, 1996.[Abstract/Free Full Text]
5. Jaeckle K. A., Eyre H. J., Townsend J. J., Schulman S., Knudson H. M., Belanich M., Yarosh D. B., Bearman S. I., Giroux D. J., Schold S. C. Correlation of tumor O⁶-methylguanine-DNA methyltransferase levels with survival of malignant astrocytoma patients treated with bis-chloroethylnitrosourea: a Southwest Oncology Group study. J. Clin. Oncol., 16: 3310-3315, 1998.[Abstract]
6. Pegg A. E., Dolan M. E., Moschel R. C. Structure, function, and inhibition of O⁶-alkylguanine-DNA alkyltransferase. Prog. Nucleic Acid Res. Mol. Biol., 51: 167-223, 1995.[Medline]
7. Yung W. K., Prados M. D., Yaya-Tur R., Rosenfeld S. S., Brada M., Friedman H. S., Albright R., Olson J., Chang S. M., O’Neill A. M., Friedman A. H., Bruner J., Yue N., Dugan M., Zaknoen S., Levin V. A. Multicenter Phase II trial of temozolomide in patients with anaplastic astrocytoma or anaplastic oligoastrocytoma at first relapse. J. Clin. Oncol., 17: 2762-2771, 1999.[Abstract/Free Full Text]
8. Bower M., Newlands E. S., Bleehen N. M., Brada M., Begent R. J., Calvert H., Colquhoun I., Lewis P., Brampton M. H. Multicentre CRC Phase II trial of temozolomide in recurrent or progressive high-grade glioma. Cancer Chemother. Pharmacol., 40: 484-488, 1997.[Medline]
9. Citron M., Schoenhaus M., Rothenberg H., Kostroff K., Wasserman P., Kahn L., White A., Burns G., Held D., Yarosh D. O⁶-Methylguanine-DNA methyltransferase in normal and malignant tissue of the breast. Cancer Invest., 12: 605-610, 1994.[Medline]
10. Kokkinakis D. M., Ahmed M., Delgado R., Fruitwala M., Mohiuddin M., Albores-Saavedra J. Role of O⁶-methylguanine-DNA methyltransferase in the resistance of pancreatic tumors to DNA alkylating agents. Cancer Res., 57: 5360-5368, 1997.[Abstract/Free Full Text]
11. Fischhaber P. L., Gall A. S., Duncan J. A., Hopkins P. B. Direct demonstration in synthetic oligonucleotides that N,N'-bis(2-chloroethyl)-nitrosourea cross-links N¹ of deoxyguanosine to N³ of deoxycytidine on opposite strands of duplex DNA. Cancer Res., 59: 4363-4368, 1999.[Abstract/Free Full Text]
12. Karran P., Hampson R. Genomic instability and tolerance to alkylating agents. Cancer Surv., 28: 69-85, 1996.[Medline]
13. Karran P., Bignami M. Self-destruction and tolerance in resistance of mammalian cells to alkylation damage. Nucleic Acids Res., 20: 2933-2940, 1992.[Free Full Text]
14. Lage H., Dietel M. Involvement of the DNA mismatch repair system in antineoplastic drug resistance. J. Cancer Res. Clin. Oncol., 125: 156-165, 1999.[Medline]
15. Dolan M. E., Pegg A. E. O⁶-Benzylguanine and its role in chemotherapy. Clin. Cancer Res., 3: 837-847, 1997.[Abstract]
16. Marathi U. K., Dolan M. E., Erickson L. C. Anti-neoplastic activity of sequenced administration O6-benzylguanine, streptozotocin and 1,3-bis(2-chloroethyl)-1-nitrosourea in vitro and in vivo. Biochem. Pharmacol., 48: 2127-2134, 1994.[Medline]
17. Middleton M. R., Kelley J., Thatcher N., Donnelly D. J., McElhinney R. S., McMurry T. B., McCormick J. E., Margison G. P. O⁶-(4-Bromothenyl)guanine improves the therapeutic index of temozolomide against A375M melanoma xenografts. Int. J. Cancer, 85: 248-252, 2000.[Medline]
18. Schold S. C., Kokkinakis D. M., Rudy J., Moschel R. C., Pegg A. E. Treatment of human brain tumor xenografts with O⁶-benzyl-2'-deoxyguanosine and BCNU. Cancer Res., 56: 2076-2081, 1996.[Abstract/Free Full Text]
19. Kurpad S. N., Dolan M. E., McLendon R. E., Archer G. E., Moschel R. C., Pegg E., Bigner D. D., Friedman H. S. Intra-arterial O⁶-benzylguanine enables the specific therapy of nitrosourea-resistant intracranial human glioma xenografts in athymic rats with 1,3-bis(2-chloroethyl)-1-nitrosourea. Cancer Chemother. Pharmacol., 39: 307-316, 1997.[Medline]
20. Kokkinakis D. M., Moschel R. C., Pegg A. E., Schold S. C. Eradication of human medulloblastoma tumor xenografts with a combination of O⁶-benzyl-2'-deoxyguanosine and 1,3-bis(2-chloroethyl)-1-nitrosourea. Clin. Cancer Res., 5: 3676-3681, 1999.[Abstract/Free Full Text]
21. Friedman H. S., Kerby T., Calvert H. Temozolomide and treatment of malignant glioma. Clin. Cancer Res., 6: 2585-2597, 2000.[Abstract/Free Full Text]
22. Friedman H. S., McLendon R. E., Kerby T., Dugan M., Bigner S. H., Henry A. J., Ashley D. M., Krischer J., Lovell S., Rasheed K., Marchev F., Seman A. J., Cokgor I., Rich J., Stewart E., Colvin O. M., Provenzale J. M., Bigner D. D., Haglund M. M., Friedman A. H., Modrich P. L. DNA mismatch repair of O⁶-methylguanine-DNA methyltransferase analysis and response to Temodal in newly diagnosed malignant glioma. J. Clin. Oncol., 16: 3851-3857, 1998.[Abstract/Free Full Text]
23. Friedman H. S., Kokkinakis D. M., Pluda J., Friedman A. H., Cokgor I., Haglund M. M., Ashley D. M., Rich J., Dolan M. E., Pegg A. E., Moschel R. C., McLendon R. E., Kerby T., Herndon J. E., Bigner D. D., Schold S. C. Phase I trial of O⁶-benzylguanine for patients undergoing surgery for malignant gliomas. J. Clin. Oncol., 16: 3570-3575, 1998.[Abstract]
24. Chinnasamy N., Rafferty J. A., Hickson I., Ashby J., Tinwell H., Margison G. P., Dexter T. M., Fairbairn L. J. O⁶-Benzylguanine potentiates the in vivo toxicity and clastogenicity of temozolomide and BCNU in mouse bone marrow. Blood, 89: 1566-1573, 1997.[Abstract/Free Full Text]
25. Wali R. K., Skarosi S., Hart J., Zhang Y., Dolan M. E., Moschel R. C., Nguyen L., Mustafi R., Brasitus T. A., Bissonnette M. Inhibition of O⁶-methylguanine-DNA methyltransferase increases azoxymethane-induced colonic tumors in rats. Carcinogenesis (Lond.), 20: 2355-2360, 1999.[Abstract/Free Full Text]
26. Kokkinakis D. M., von Wronski M. A., Vuong T. H., Brent T. P., Schold S. C., Jr. Regulation of O6-methylguanine-DNA methyltransferase by methionine in human tumour cells. Br. J. Cancer, 75: 779-788, 1997.[Medline]
27. Kokkinakis D. M., Schold S. C., Jr., Hori H., Nobori T. Effect of long-term depletion of plasma methionine on the growth and survival of human brain tumor xenografts in athymic mice. Nutr. Cancer, 29: 195-204, 1997.[Medline]
28. Lishko V. K., Lishko O. V., Hoffman R. M. The preparation of endotoxin-free L-methionine-alpha-deamino-gamma-mercaptomethane-lyase (L-methioninase) from Pseudomonas putida. Protein Expr. Purif., 4: 529-533, 1993.[Medline]
29. Tan Y., Xu M., Tan X-Z., Tan X-Y., Wang X., Saikawa Y., Nagahama T., Sun X., Lenz M., Hoffman R. M. Overexpression and large-scale production of recombinant L-methionine-alpha-deamino-gamma-mercaptomethane-lyase for novel anticancer therapy. Protein Expr. Purif., 9: 233-245, 1997.[Medline]
30. Hawks C. T. Leary S. L. eds. . Formulatory for Laboratory Animals, : 78 Iowa State University Press Ames, IA 1995.
31. Bradford M. A rapid and sensitive method for the quantitation of microgram quantities of protein utilizing the principle of protein-dye binding. Anal. Biochem., 72: 248-254, 1976.[Medline]
32. Kokkinakis D. M., Bocangel D. B., Schold S. C., Moschel R. C., Pegg A. E. Thresholds of O⁶-alkylguanine-DNA alkyltransferase which confer significant resistance of human glial tumor xenografts to treatment with 1,3-bis(2-chloroethyl)-1-nitrosourea and temozolomide. Clin. Cancer Res., 7: 421-428, 2001.[Abstract/Free Full Text]
33. Stern P. H., Hoffman R. M. Enhanced in vitro selective toxicity of chemotherapeutic agents for human cancer cells based on a metabolic defect. J. Natl. Cancer Inst. (Bethesda), 76: 629-639, 1986.
34. Hoffman R. M., Jacobsen S. J. Reversible growth arrest in simian virus 40-transformed human fibroblasts. Proc. Natl. Acad. Sci. USA, 77: 7306-7310, 1980.[Abstract/Free Full Text]
35. Breillout F., Hadida F., Echinard-Garin P., Laseaux V., Poupon M. F. Decreased rat rhabdomyosarcoma pulmonary metastases in response to a low methionine diet. Anticancer Res., 7: 861-867, 1987.[Medline]
36. Guo H., Lishko V., Herrera H., Groce A., Kubota T., Hoffman R. M. Therapeutic tumor-specific cell-cycle block induced by methionine starvation in vivo. Cancer Res., 53: 5676-5679, 1993.[Abstract/Free Full Text]
37. Tan Y., Xu M., Guo H., Sun X., Kubota T., Hoffman R. M. Anticancer efficacy of methioninase in vivo. Anticancer Res., 16: 3931-3936, 1996.[Medline]
38. Hoshiya Y., Guo H., Kubota T., Inada T., Asanuma F., Yamada Y., Koh J., Kitajima M., Hoffman R. M. Human tumors are methionine dependent in vivo. Anticancer Res., 15: 717-718, 1995.[Medline]
39. Goseki N., Yamazaki S., Shimojyu K., Kando F., Maruyama M., Endo M., Koike M., Takahashi H. Synergistic effect of methionine-depleting total parenteral nutrition with 5-fluorouracil on human gastric cancer: a randomized, prospective clinical trial. Jpn. J. Cancer Res., 86: 484-489, 1995.[Medline]
40. Goseki N. Evaluation of the survival time of A0–90 clinical trial for progressive or recurrent gastric cancer. J. Jpn. Soc. Cancer Ther., 33: 610 1996.
41. Goseki N., Yamazaki S., Endo M., Onodera T., Kosaki G., Hibino Y., Huwahata T. Antitumor effect of methionine-depleting total parenteral nutrition with doxorubicin administration on Yoshida sarcoma-bearing rats. Cancer (Phila.), 69: 1865-1872, 1992.[Medline]
42. Yoshioka T., Wada T., Uchida N., Maki H., Yoshida H., Ide N., Kasai H., Hojo K., Shono K., Maekawa R., Yagi S., Hoffman R. M., Sugita K. Anticancer efficacy in vivo and in vitro, synergy with 5-fluorouracil, and safety of recombinant methioninase. Cancer Res., 58: 2583-2587, 1998.[Abstract/Free Full Text]
43. Tan Y., Sun X., Xu M., Tan X-Z., Sasson A., Rashidi B., Han Q., Tan X-Y., Wang X., An Z., Sun F-X., Hoffman R. M. Efficacy of recombinant methioninase in combination with cisplatinum on human colon tumors in nude mice. Clin. Cancer Res., 5: 2157-2163, 1999.[Abstract/Free Full Text]
44. Mecham J. O., Rowitch D., Wallace C. D., Stern P. H., Hoffman R. M. The metabolic defect of methionine dependence occurs frequently in human tumor cell lines. Biochem. Biophys. Res. Commun., 117: 429-434, 1983.[Medline]
45. Tan Y., Zavala J., Sr., Xu M., Zavala J., Jr., Hoffman R. M. Serum methionine depletion without side effects by methioninase in metastatic breast cancer patients. Anticancer Res., 16: 3937-3942, 1996.[Medline]
46. Tan Y., Zavala J., Sr., Han Q., Xu M., Sun X., Tan X-H., Tan X., Magana R., Geller J., Hoffman R. M. Recombinant methioninase infusion reduces the biochemical endpoint of serum methionine with minimal toxicity in high-stage cancer patients. Anticancer Res., 17: 3857-3860, 1997.[Medline]

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