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Induction of Apoptosis Using Inhibitors of Lysophosphatidic Acid Acyltransferase-ß and Anti-CD20 Monoclonal Antibodies for Treatment of Human Non-Hodgkin's Lymphomas

Authors' Affiliations: ¹ Fred Hutchinson Cancer Research Center; Departments of ² Medicine, ³ Pathology, and ⁴ Biological Structure from the University of Washington and ⁵ Cell Therapeutics Inc., Seattle, Washington

Requests for reprints: John M. Pagel, Clinical Research, Fred Hutchinson Cancer Research Center, D5-390, 1100 Fairview Avenue North, Seattle, WA 98109. Phone: 206-667-1868; Fax: 1-206-667-5454; E-mail: jpagel{at}fhcrc.org.

	Abstract

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Purpose: Lysophosphatidic acid acyltransferase-ß (LPAAT-ß) is a transmembrane enzyme critical for the biosynthesis of phosphoglycerides whose product, phosphatidic acid, plays a key role in raf and AKT/mTor-mediated signal transduction.

Experimental Design: LPAAT-ß may be a novel target for anticancer therapy, and, thus, we examined the effects of a series of inhibitors of LPAAT-ß on multiple human non–Hodgkin's lymphoma cell lines in vitro and in vivo.

Results: We showed that five LPAAT-ß inhibitors at doses of 500 nmol/L routinely inhibited growth in a panel of human lymphoma cell lines in vitro by >90%, as measured by [³H]thymidine incorporation. Apoptotic effects of the LPAAT-ß inhibitors were evaluated either alone or in combination with the anti-CD20 antibody, Rituximab. The LPAAT-ß inhibitors induced caspase-mediated apoptosis at 50 to 100 nmol/L in up to 90% of non–Hodgkin's lymphoma cells. The combination of Rituximab and an LPAAT-ß inhibitor resulted in a 2-fold increase in apoptosis compared with either agent alone. To assess the combination of Rituximab and a LPAAT-ß inhibitor in vivo, groups of athymic mice bearing s.c. human Ramos lymphoma xenografts were treated with the LPAAT-ß inhibitor CT-32228 i.p. (75 mg/kg) daily for 5 d/wk x 4 weeks (total 20 doses), Rituximab i.p. (10 mg/kg) weekly x 4 weeks (4 doses total), or CT-32228 plus Rituximab combined. Treatment with either CT-32228 or Rituximab alone showed an approximate 50% xenograft growth delay; however, complete responses were only observed when the two agents were delivered together.

Conclusions: These data suggest that Rituximab, combined with a LPAAT-ß inhibitor, may provide enhanced therapeutic effects through apoptotic mechanisms.

Inhibitors of lysophosphatidic acid acyltransferase-ß (LPAAT-ß) have recently been explored as novel anticancer therapeutic agents (4–7). The gene for LPAAT-ß is encoded in a region of the class III human MHC and its product is an intrinsic transmembrane enzyme critical for the biosynthesis of phosphoglycerides (8). The specific role of LPAAT, also known as 1-acyl-sn-glycerol-3-phosphate-acyltransferase, is to catalyze the transfer of acyl groups from acyl-CoA to lysophosphatidic acid, to form phosphatidic acid (4, 9, 10). Phosphatidic acid has also been shown to be critical for signal transduction in the ras/raf/mitogen-activated protein kinase and PI3K/mTor oncogenic pathways (11–13). The most common isoforms are LPAAT- and LPAAT-ß, which show varied expression levels on different tissues (9, 10). Whereas LPAAT- is expressed at a relatively constant level in virtually all human tissue tested, LPAAT-ß is expressed at low levels in most normal tissues and is increased in epithelial tumor tissues and endothelial cells (4, 10). Enzymatic inhibition of the LPAAT-ß enzyme seems to interrupt these oncogenic pathways, leading to apoptosis (4).

In this study, we investigated the effects of inhibitors of LPAAT-ß activity in combination with Rituximab on human non–Hodgkin's lymphoma cells, in vitro and in vivo, in an effort to enhance the therapeutic efficacy of anti-CD20 antibody therapy by increasing the level of apoptosis that may be necessary to overcome antibody resistance. We have shown that exposure of human non–Hodgkin's lymphoma cells to the combination of LPAAT-ß inhibitors and Rituximab enhances apoptosis in vitro and augments antitumor responses in vivo.

	Materials and Methods

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Non–Hodgkin's lymphoma tumor cell lines. The CD-20 expressing human Burkitt's lymphoma cell line Ramos was obtained from the American Type Culture Collection (Manassas, VA). The B lymphoma cell lines SU-DHL4 (DHL-4), TAB, Oci-Ly8, and FL-18 were gifts from Dr. David Maloney (Fred Hutchinson Cancer Research Center, Seattle, WA). Cell lines were maintained in RPMI 1640 with 2 mmol/L L-glutamine (Life Technologies, Grand Island, NY), supplemented with 10% fetal bovine serum (BioWhittaker, Walkersville, MD), 1 mmol/L sodium pyruvate, 100 units/mL penicillin, 100 µg/mL streptomycin, and 0.25 µg/mL Fungizone (BioWhittaker). Cells were incubated at 37°C with 5% CO₂ and maintained in log phase growth. Primary T and B cells were isolated and cultivated by Cell Therapeutics Incorporated (Seattle, WA). Peripheral blood mononuclear cells were isolated from whole blood using Histopaque (Sigma) gradient centrifugation. T and B lymphocytes were separated using magnetic beads from Biosource International (Camarillo, CA) coated with antibodies for CD3, CD3e, CD19, and CD8 from PharMingen (San Diego, CA). All primary populations were then cultivated in RPMI (Life Technologies, Carlsbad, CA) and 10% heat-inactivated fetal bovine serum. The "activated" population of B lymphocytes included 100 EU/mL lipopolysaccharide (Sigma, St. Louis, MO) and for T lymphocytes 2.5 µg/mL concanavalin A (Sigma).

Lysophosphatidic acid acyltransferase-ß inhibitors and reagents. We studied three previously described triazine LPAAT-ß inhibitors (CT-32228, CT-32176, and CT-32212) and two pyrimidine LPAAT-ß inhibitors (CT-32615 and CT-32521; refs. 14, 15). The CT-32212 compound is structurally similar to CT-32176 and CT-32228, but is relatively inactive and was, therefore, used as a negative control (4). The molecular structures of the compounds are shown in Fig. 1.

View larger version (20K): [in this window] [in a new window] [Download PPT slide]   Fig. 1. Chemical structures of LPAAT-ß inhibitors. Similarities in the structures of the triazine LPAAT-ß inhibitors (CT-32228, CT-32176, and CT-32212) and the pyrimidine LPAAT-ß inhibitors (CT-32521 and CT-32615) are depicted below. These families primarily differ in the number of nitrogen atoms in the center core ring. Both groups possess substitutions at the 2,5-positions on ring A (left ring) with CT-32228 having a 2-methyl-5-chloro substitution, and CT-32615 a 2-ethoxy-5-chloro substitution. Both groups possess para substitutions on ring C (right ring) with CT-32228 having a bromo substitution and CT-32615 a hydroxymethyl substitution.

Total lysophosphatidic acid acyltransferase activity in non–Hodgkin's lymphoma cells. LPAAT activity was assayed in primary T and B lymphocytes and in hematologic cell lines as described by Hideshima et al. (7). This assay does not distinguish between LPAAT- and LPAAT-ß activities (data not shown) and, hence, will be called total endogenous LPAAT activity.

Growth inhibition assays. The effects of LPAAT-ß inhibitors on the growth of lymphoma cell lines were tested using a [³H]thymidine incorporation assay (16). Cells were plated in 24-well flat-bottomed plates at a density of 1.25 x 10⁵ cells in 1.0 mL culture medium. The LPAAT-ß inhibitors were freshly dissolved in 100% DMSO (American Type Culture Collection) and added to wells in concentrations ranging from 10 to 1,000 nmol/L. Cell suspensions were incubated with LPAAT-ß inhibitors for 24 to 96 hours at 37°C. For the final 8 hours, 200 µL aliquots of each cell suspension were transferred in triplicate into 96-well flat-bottomed plates, and then 1 µCi of [³H]thymidine (Perkin-Elmer) was added to each of the 200 µL cell suspensions to bring the final volume to 220 µL. Untreated cells and cells that were incubated with DMSO diluent alone were used as negative controls. Following this final incubation at 37°C, cells were harvested onto glass fiber filters (Millipore, Inc., Billerica, MA) with a Packard Filtermate Harvester and [³H]thymidine incorporation was analyzed by liquid scintillation on a Packard Top Count Microplate Scintillation Counter (Packard Instruments, Meriden, CT). Counts per minute were analyzed and proliferation rates were calculated for each experimental condition. The mean and SE values for each time point were plotted to generate growth inhibition curves for each experimental group. All experiments were done in triplicate.

Apoptosis assays. Apoptosis assays were done using the ApoAlert apoptosis kit using Annexin V–conjugated FITC to detect phosphatidylserine translocated to the outer leaflet of the cell membrane and propidium iodide staining for detection of nonspecific cellular necrosis (BD Biosciences Clontech). Non–Hodgkin's lymphoma cells (1 x 10⁶/mL) were incubated at 37°C for 48 hours with LPAAT-ß inhibitors at concentrations ranging from 50 to 100 nmol/L, either alone or in combination with 1.0 mg/mL Rituximab. Cell suspensions were subsequently washed and incubated with Annexin V-FITC (20 µg/mL), propidium iodide (50 µg/mL), and 1x binding buffer [0.1 mol/L HEPES (pH 7.4), 1.4 mol/L NaCl, 25 mmol/L CaCl₂; BD Biosciences Clontech]. Additional assays using the same concentrations of LPAAT-ß inhibitor and Rituximab were done using the APO LOGIX Carboxyfluorescein Caspase (FAM-VAD-FMK) Detection kit (Cell Technology, Minneapolis, MN) for detection of activated caspases. Flow cytometry was done on a fluorescence-activated cell sorter and data analysis was done using CellQuest software (Becton Dickinson, San Jose, CA). Average and SE values were collected and are reported for each group of compounds studied. Sodium azide (2% final concentration) was used as a positive control. Negative controls included untreated cells and cell suspensions were treated with DMSO vehicle alone.

Mouse studies: Mice. Nonobese diabetic CB17 severe combined immunodeficient mice were obtained from the animal health facility at the Fred Hutchinson Cancer Research Center. Mice ages 6 to 8 weeks were kept in specific pathogen-free conditions and maintained under protocols approved by the Fred Hutchinson Cancer Research Center Institutional Animal Care and Use Committee.

Therapy experiments. Mice received s.c. injections of either 10 x 10⁶ Ramos lymphoma tumor cells, in experiments to establish palpable xenograft tumors, or 7 x 10⁶ cells for experiments designed to treat animals in minimal residual disease state. Mice with similar palpable tumor sizes (500 mm³) were selected for experimentation before receiving LPAAT-ß inhibitor alone, Rituximab alone, or the combination of LPAAT-ß inhibitor and Rituximab. In all murine experiments, CT-32228 was chosen as the LPAAT-ß inhibitor because of its more favorable metabolic characteristics compared with CT-32615. Using human liver microsomes and a concentration of 5 mmol/L of each compound, 13% of CT-32228 was metabolized after 30 minutes, compared with 55% metabolism of CT-32615. Using mouse liver microsomes, at 20 mmol/L, CT-32228 was 25% metabolized after 30 minutes, compared with 41% metabolism of CT-32615. In minimal residual disease experiments, mice received the same therapeutic agents 72 hours following delivery of s.c. Ramos cells and before the appearance of palpable tumors. In each experiment, a group of five mice received DMSO alone as a control. Groups of five mice received either 72 mg/kg LPAAT-ß inhibitor i.p. daily for 5 d/wk x 4 weeks (total 20 doses), 10 mg/kg Rituximab i.p. once weekly x 4 weeks (total 4 doses), or a combination of LPAAT-ß inhibitor and Rituximab administered at identical doses to those used in single-agent animal groups. A dose of 72 mg/kg of LPAAT-ß inhibitor was chosen for these studies based on the activity of these compounds in prior dose-escalation studies treating epithelial carcinomas using severe combined immunodeficient mice.⁶ In addition, doses of <72 mg/kg of LPAAT-ß inhibitor alone had suboptimal efficacy in a dose-response study of murine lymphoma (data not shown). The dose of Rituximab (10 mg/kg) used was derived from previous xenograft experiments (17). Mice in this study were monitored every other day for general appearance, weight loss, and tumor volume measurements. Mice were euthanized if tumors grew large enough to cause obvious discomfort or impair ambulation.

Toxicity studies. In toxicity studies, groups of five mice received LPAAT-ß inhibitors at doses of 18, 36, or 72 mg/kg for 5 d/wk with a maximum of 4 weeks (up to 20 total doses) of therapy. On the first day of each treatment week, mice were also bled through the retro-orbital venous plexus and blood was collected for analysis of serum alanine aminotransferase, aspartate aminotransferase, urea nitrogen, and creatinine levels. An untreated group and mice treated with only DMSO served as control mice, which were sacrificed at the end of the fourth treatment week.

In a separate series of experiments, groups of five mice assigned to treatment control groups in the manner described above were sacrificed and necropsied. Representative 5-µm sections stained by H&E were prepared from lungs, liver, spleen, kidneys, stomach, and small and large intestine. Slides were labeled with random numbers and each tissue analyzed in a blinded fashion for enumeration of apoptotic cells characterized by pyknosis, condensation of chromatin, and blebbing of apoptotic bodies. The degree of apoptosis in each tissue was graded semiquantitatively as absent, mild, moderate, or severe (18). This apoptosis scale was adapted from a routine grading system designed to evaluate apoptosis in patients with graft-versus-host disease following hematopoietic stem cell transplant. Grades were determined in the gastrointestinal tract by evaluation of the number of apoptotic cells in 50 mucosal crypts per glands for each therapeutic group analyzed. A mild apoptotic grade was assigned to specimens containing three to nine apoptotic cells per 50 epithelial crypt, a moderate grade was associated with 10 to 20 apoptotic cells per 50 crypts, and severe apoptosis was induced in samples with >20 apoptotic cells per 50 crypts.

	Results

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Endogenous levels of lysophosphatidic acid acyltransferase activity in primary B and T lymphocytes and human non–Hodgkin's lymphoma cell lines. Total LPAAT activity was determined in a variety of human non–Hodgkin's lymphoma tumor cell lines and primary B and T lymphocytes cells using the cell-free enzymatic assay described in Materials and Methods. Activity levels in a panel of human lymphoma cells lines, including two Burkitt's lymphoma (Daudi and Ramos), two large B-cell lymphoma cell lines (Oci-Ly8 and TAB), and two transformed follicular non–Hodgkin's lymphoma cell lines (FL18 and DHL-4), displayed LPAAT activity levels ranging from 3.9 ± 0.2 to 8.0 ± 0.2 nmol/min/mg (Table 1). LPAAT activity levels in the majority of these human non–Hodgkin's lymphoma cell lines were greater than the levels seen in unstimulated and stimulated primary human B and T cells: unstimulated and stimulated primary B cells had an expression level of 2.6 ± 0.1 and 3.2 ± 0.4 nmol/min/mg, respectively, and stimulated and unstimulated T lymphocytes had endogenous LPAAT activity levels of 2.9 ± 0.1 and 4.5 ± 0.2 nmol/min/mg, respectively. A single murine B-cell line, A20, expressed significantly lower levels of LPAAT activity (0.9 ± 0.1 nmol/min/mg) compared with the human cell lines.

View larger version (16K): [in this window] [in a new window] [Download PPT slide]   Fig. 2. Cell inhibition induced by LPAAT-ß inhibitors. Three human non–Hodgkin's lymphoma cell lines (Ramos, FL-18, and DHL-4) were incubated with 500 nmol/L of the LPAAT-ß inhibitor CT-32615. Proliferation was examined by measuring [3H]thymidine incorporation for 24 to 72 hours. Experimental samples were normalized to controls treated with the DMSO vehicle alone. CT-32212 is an inactive analogue used as a negative control at a concentration of 500 nmol/L. Each sample was tested in triplicate and each experiment was done on three separate occasions.

View larger version (17K): [in this window] [in a new window] [Download PPT slide]   Fig. 3. Induction of apoptosis by LPAAT-ß inhibitors. Ramos cells were separately incubated with four LPAAT-ß inhibitors for 48 hours at increasing concentrations (50-800 nmol/L). Apoptosis was measured by quantifying the Annexin-positive population after staining with FITC-Annexin and propidium iodide. LPAAT-ß inhibitors were dissolved in 100% DMSO and cells treated with vehicle control only are shown in the first column. Cells treated with a 2% azide solution are shown as a positive control. Points, cell percentages averaged from triplicate samples; bars, SD.

View larger version (26K): [in this window] [in a new window] [Download PPT slide]   Fig. 4. Apoptosis due to LPAAT-ß inhibitor (CT-32228) and Rituximab. The degree of apoptosis in both DHL-4 and Ramos cells is represented by the mean number of cells that became Annexin V (A) or FAM (B) positive following the appropriate treatment using either 50 nmol/L of CT-32228 inhibitor or Rituximab at 1 µg/mL alone or the combination of the two agents.

View larger version (41K): [in this window] [in a new window] [Download PPT slide]   Fig. 5. Apoptosis induced by LPAAT-ß inhibitors and Rituximab. Annexin V and propidium iodide staining are shown in Ramos cells treated with CT-32176 (50 nmol/L), Rituximab (1.0 µg/mL), a combination of the two agents, or vehicle control after 48 hours. Percentages indicate the fraction of cells outside the region denoted by the box (R2) and represent cells that became Annexin V+ following treatment. The R1 region was established by maintaining a healthy control population exceeding 95% for each experiment. This is a representative figure for the 24-hour time point from one of three concordant experiments.

In vivo treatment with lysophosphatidic acid acyltransferase-ß inhibitors and Rituximab in a minimal tumor burden model. To assess the in vivo potential of LPAAT-ß inhibitors, we initially tested them alone and in combination with Rituximab in a murine model of "minimal disease." Mice were injected s.c. with 7 x 10⁶ Ramos Burkitt's lymphoma cells. Seventy-two hours after injection, mice were randomly allocated to one of four groups: (a) mice that received daily i.p. injections of 72 mg/kg of the LPAAT-ß inhibitor CT-32228 alone for 5 d/wk for 4 weeks (total of 20 doses), (b) mice that received 10 mg/kg Rituximab once per week i.p. for 4 weeks (total of four doses), (c) the combination of CT-32228 and Rituximab at the doses and schedules above, or (d) DMSO diluent alone. Treatment doses were used based on results from previous studies, as noted in Materials and Methods. In addition, doses <72 mg/kg of the LPAAT-ß inhibitor showed suboptimal efficacy in a prior dose-escalation study of murine lymphoma (data not shown). No tumor development was detected in any of the five mice treated with the combination of CT-32228 and Rituximab; however, four of five (80%) mice treated with Rituximab alone (P = 0.50) and five of five (100%) of mice treated with CT-32228 alone (P = 0.004) developed palpable tumors by day 16 after tumor implantation (Fig. 6). All control mice treated with the DMSO vehicle alone developed progressive tumor growth requiring euthanasia by day 31 after injection (P = 0.004 for comparison to combination of CT-32228 and Rituximab).

View larger version (16K): [in this window] [in a new window] [Download PPT slide]   Fig. 6. Tumor growth in a lymphoma minimum residual disease model. Groups of five mice received s.c. injections of 7 x 106 Ramos cells followed 72 hours by i.p. injection of either 72 mg/kg CT-32228, 10 mg/kg Rituximab, a combination of these two agents, or DMSO vehicle alone. Biweekly measurements of tumor xenografts (mm3) were obtained from each treatment group. Average tumor volumes (points) were calculated for each group and are shown for each treatment group with SDs (bars). Curves were truncated when the first mouse required euthanasia because of tumor progression. Results shown are representative of three separate experiments.

View larger version (18K): [in this window] [in a new window] [Download PPT slide]   Fig. 8. Kaplan-Meier cumulative survival plots for mice treated in minimum residual disease model (A) and for mice treated after establishment of palpable lymphoma xenografts (B). Groups of 10 mice that received s.c. injections of 7 x 106 Ramos cells in the minimal residual disease model (A), or groups of 10 mice bearing 500 mm3 Ramos tumor xenografts (B), were treated as described in the legend to Figs. 4 and 5, respectively, and analyzed for survival as a function of time. Treatment groups included mice treated with 10 mg/kg Rituximab, 72 mg/kg CT-32228, a combination of these two agents at the same doses, or DMSO vehicle alone. A and B, treatment groups designated in Figs. 6 and 7, respectively.

View larger version (17K): [in this window] [in a new window] [Download PPT slide]   Fig. 7. Tumor growth in a palpable lymphoma xenograft model. Groups of five mice bearing established Ramos lymphoma xenografts were injected i.p. with either 72 mg/kg CT-32228, 10 mg/kg Rituximab, a combination of these two agents, or DMSO vehicle alone. Biweekly measurements of tumor xenografts (mm3) were obtained from each treatment group. Average tumor volumes (points) were calculated for each group and are shown for each treatment group with SDs (bars). Curves were truncated when the first mouse required euthanasia because of tumor progression. Results shown are representative of three separate experiments.

Toxicity analysis in mice receiving CT-32228. To further elucidate systemic toxicities incurred as a result of treatment with CT-32228, hematologic, hepatic, and renal parameters were assessed in nontumor-bearing mice that received CT-32228 concentrations ranging from 18 to 72 mg/kg (Table 2). Blood was obtained weekly from the retro-orbital venous plexus to measure leukocyte counts and hemoglobin values. Minor decrements were observed in the leukocyte counts of all groups receiving DMSO regardless of the presence of an LPAAT-ß inhibitor (Table 2), with nadirs occurring 7 days after therapy. Significant differences were seen only between control (1.1 ± 0.2 K/µL) and the highest concentration, 72 mg/kg (0.3 ± 0.0 K/µL). Nadirs were observed in hemoglobin levels after 21 days and in platelet levels after 21 days in mice receiving 36 mg/kg of the LPAAT-ß inhibitor.

Mouse weight loss was 0% for mice receiving DMSO vehicle alone, 0% for 18 mg/kg, 16% for 36 mg/kg, and 18% for 72 mg/kg. Thus, blinded examination of H&E–stained tissue sections from mice were analyzed for determination of apoptosis induction. Examination of sections from the gastrointestinal tract suggested that the gastrointestinal epithelium was the only tissue to develop measurable levels of cellular apoptosis among the tissues studied. The gastrointestinal tract showed minimal or absent apoptosis in epithelial cells of mice receiving 18 mg/kg of LPAAT-ß inhibitor, indistinguishable from apoptosis scores observed in normal untreated animals or mice receiving only DMSO. Mild levels of apoptosis (three to nine apoptotic cells per 50 epithelial crypts) were seen in mice receiving 36 mg/kg. In contrast, severe generalized apoptosis (>20 apoptotic cells per 50 epithelial crypts) was observed in the gastrointestinal tract of in all animals receiving 72 mg/kg. Apoptosis was most marked in the colon, where almost all crypts in every section displayed multiple apoptotic cells, including many that had sloughed into the crypt lumens (Fig. 9). These alterations were milder in the small intestine and fore-stomach. The glandular stomach was least involved. The histology of other organs did not differ substantially between animals treated with CT-32228 and controls.

View larger version (141K): [in this window] [in a new window] [Download PPT slide]   Fig. 9. Apoptosis of epithelial cells in the gastrointestinal tract of mice receiving 72 mg/kg of LPAAT-ß inhibitor. In the fore-stomach (A), small numbers of shrunken apoptotic epithelial cells displayed condensation of chromatin and peripheral aggregation of chromatin beneath the nuclear membrane (arrows). Apoptosis was much more severe in the colon (C), where degenerating cells were frequently observed in the crypt epithelium and in the lumens, where they lie in clumps. For comparison, apoptosis was not evident in sections of fore-stomach (B) and colon (D) from normal mice.

	Discussion

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Inhibition of the LPAAT-ß isoform has also been shown to have negative proliferative effects on hematopoietic cell lines. The inhibition of the LPAAT-ß enzyme using nanomolar concentrations of aryldiaminotriazine compounds resulted in significant inhibition of cell proliferation in vitro in Epstein-Barr virus–transformed B non–Hodgkin's lymphoma, T-cell leukemia, chronic myeloid leukemia, promyelocitic leukemia, and Burkitt's lymphoma cell lines (4). Hideshima et al. (7) also showed that LPAAT-ß inhibitors caused antiproliferative effects in multiple myeloma cells at concentrations of <200 nmol/L. Interestingly, the effects of LPAAT-ß inhibitors were shown on the observed cytotoxicity toward myeloma cells in the microenvironment of the bone marrow, suggesting that inhibition of LPAAT-ß can occur in a clinically relevant environment.

Consistent with these prior studies, we postulated that LPAAT-ß may also be an effective novel therapeutic target for the inhibition of B non–Hodgkin's lymphoma cell growth. The biological effect of these compounds on non–Hodgkin's lymphoma cells, however, had not been previously characterized. In this study, we found that cell growth of human non–Hodgkin's lymphoma cells is inhibited up to 10-fold with the use of an LPAAT-ß inhibitor compared with untreated malignant B cells. These results suggest that LPAAT-ß can be a potential target for the inhibition of non–Hodgkin's lymphoma proliferation, and may serve as an important therapeutic intervention to treat non–Hodgkin's lymphoma patients. To further elucidate the mechanism of the antiproliferation effects mediated by LPAAT-ß inhibition, we did a series of experiments examining the apoptotic potential of these novel agents on human non–Hodgkin's lymphoma cells. Whereas the protective role of phosphatidic acid against apoptosis is still a topic of debate, inhibiting enzymes involved in the production of phosphatidic acid has been shown to be associated with regulation of cell-signaling pathways involved in cell growth and viability (4, 5, 24). It has also been shown that new novel agents, such as the aryldiaminotriazines that inhibit LPAAT-ß, can also induce apoptosis in a variety of tumor cell lines (4). We and others have hypothesized that apoptosis triggered by specific targeting may be preferred to apoptosis induced by untargeted therapies due to limited inflammatory changes and a potential reduced risk of mutation, helping to ensure that tumor cells are eliminated.

Caspases are cysteine proteins that mediate apoptosis after activation by specific signals originating from both outside and inside the cell (25). Other authors have suggested that apoptosis induced by LPAAT-ß inhibitors in myeloma cells is mediated by activation of caspase-8 and caspase-7 (7) and involves ligation of death receptors (5), suggesting that the extrinsic pathway is utilized in apoptosis induced by these agents (25). The intrinsic pathway, on the other hand, involves the release of cytochrome c from mitochondria, which induces Apaf-1 and leads to the activation of caspase-3 and caspase-9 (25). This process is facilitated through an important group of Bcl-2 proteins, including Bax and Bak, that regulate the permeability of the mitochondrial membrane and consequently influence the induction of apoptosis (25, 26). Recent data show activated caspase activity and apoptosis in a majority of cell lines derived from a variety of human epithelial tumors when treated with LPAAT-ß inhibitors (4, 5, 7). We found that the induction of apoptosis in multiple non–Hodgkin's lymphoma tumor cell lines mediated by LPAAT-ß inhibitors is also mediated by caspase activation.

Anti-CD20 antibodies also induce cell death through apoptotic pathways, particularly when cross-linked on the surface of non–Hodgkin's lymphoma tumor cell lines (1, 27). Ligation of the CD20 antigen by Rituximab, a chimeric human IgG1 monoclonal antibody, has been shown to lead to intracellular increases in calcium levels and poly(ADP-ribose) polymerase cleavage in vitro, an important substrate for apoptosis (19). More recent data suggests that the mitochondrial intrinsic pathway plays a key role in Rituximab-mediated apoptosis by releasing cytochrome c, leading to the activation of caspase-9 and subsequent activation of caspase-3 (19). Additional antiapoptotic proteins, such as Bcl-2, also prevent the release of cytochrome c and act to inhibit apoptosis (28). Thus, down-regulation of Bcl-2 may lower the apoptosis threshold for activation and allow the apoptotic cascade to be triggered more easily in response to anticancer agents such as LPAAT-ß inhibitors and anti-CD20 antibodies (1, 3, 19). Similar results have been achieved using antisense oligodeoxynucleotides to suppress Bcl-2 activity and create an environment that is more sensitive to the induction of apoptosis when used in the presence of Rituximab (29). Therefore, we utilized human non–Hodgkin's lymphoma cell lines with known elevated Bcl-2 levels to show that these lymphoma cell lines are also sensitive to treatment with LPAAT-ß inhibitors. These results have led us to hypothesize that a combination treatment involving anti-CD20 antibody therapy and an LPAAT-ß inhibitor may lead to an increased level of apoptosis induction in non–Hodgkin's lymphoma cells compared with the degree of apoptosis seen with the use of either agent alone. In a similar manner, inhibition of the PI3K/Akt survival pathway along with Gemcitabine has been found to effectively enhance apoptosis in innately drug-resistant human pancreatic cancer cells (26). The method of targeting multiple pathways of the apoptotic cascade may serve as a way to guard against possible mutations in a single apoptotic pathway, and effectively cast a wider tumoricidal net, preventing emergence of resistant tumor cells (25).

Despite the tolerability and widespread use of single-agent Rituximab, it is efficacious in only 50% to 60% of relapsed indolent non–Hodgkin's lymphoma patients and the median duration of response for relapsed non–Hodgkin's lymphoma patients is on the order of 12 months (1). Therefore, a combination treatment of Rituximab and LPAAT-ß inhibitors may overcome cytotoxic resistance and lead to a more efficacious therapy for non–Hodgkin's lymphoma patients. Our results using athymic mice bearing human non–Hodgkin's lymphoma xenografts treated with both Rituximab and first-generation LPAAT-ß inhibitors suggest that these agents may have additive effects when administered in combination. However, due to the toxicity of compounds, such as CT-322228 at doses required for adequate tumoricidal activity, additional classes of compounds with enhanced therapeutic effectiveness will need to be identified before clinical development can be undertaken. Additional screening of diversity libraries is under way to identify LPAAT-ß inhibitors that induce less gastrointestinal apoptosis, while maintaining or augmenting tumoricidal activity.

We have documented that CT-32228, a first-generation LPAAT-ß inhibitor used at high doses, induced apoptosis of cells in the intestinal epithelial lining, as previously seen with alterations in lysophosphatidic acid levels (28, 30). Given the described trophic effects of lysophosphatidic acid on intestinal epithelium (31), it is possible that altering the route of feeding or the complexity of the diet may influence the intestinal cell proliferative and barrier functions when exposed to LPAAT-ß inhibitors (32). Thus, future studies using LPAAT-ß inhibitors will explore the concomitant use of specific nutrients and diet-derived compounds, such as glutamate, glycine, and zinc oxide, as well as polypeptides such as teduglutide (glp-2), which has been shown to alter intracellular G protein signaling pathways and provide a cytoprotective effect in animal models of colon injury (33). Moreover, because the most severe apoptotic abnormalities were present in the large intestine, the potential role of luminal bacteria or bacterial products should be evaluated. Prior studies using elective microbial decontamination has been effective in protecting against mucositis associated with radiation therapy in patients with solid tumors (34, 35). We will also investigate the use of intraluminal antibiotics that change the gut flora as a tool to protect against colonic mucosal injury after LPAAT-ß inhibitor administration. These potential improvements in administration of the LPAAT-ß inhibitors, as well as the future identification of compounds with a superior therapeutic index, may lead to a novel therapeutic approach targeting the ras/raf pathway to provide enhanced therapeutic effects through apoptotic mechanisms.

	Acknowledgments

 
We thank Alexey Ball for his expert technical assistance.

	Footnotes

 
Grant support: Lymphoma Research Foundation Career Development Award (JMP), American Society of Clinical Oncology Young Investigator Award (JMP), NIH grant K12 CA76930 (JMP), Hext Foundation, and Penny E. Petersen Memorial Fund.

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.

⁶ J. Singer, personal communication.

Received 11/16/04; revised 3/31/05; accepted 4/19/05.

	References

Top Abstract Materials and Methods Results Discussion References

 

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