Termination of DNA synthesis by 9-beta-D-arabinofuranosyl-2-fluoroadenine. A mechanism for cytotoxicity

In vitro cytotoxic effects of fludarabine (2-F-ara-A) in combination with commonly used antileukemic agents by isobologram analysis

Fludarabine phosphate (2-F-ara-AMP) is an adenine nucleoside analogue that shows significant activity against chronic lymphocytic leukemia and indolent lymphoma. We assessed the cytotoxic interaction produced by the combination of the active metabolite of fludarabine phosphate, fludarabine (9-beta-D-arabinofuranosyl-2-fluoroadenine, 2-F-ara-A), and some commonly used antileukemic agents against human hairy cell leukemia cell line JOK-1, human chronic lymphocytic leukemia cell line SKW-3, and adult T cell leukemia cell lines ED-40810 (-) and SALT-3. The leukemia cells were exposed simultaneously to 2-F-ara-A and to the other agents for 4 days. Cell growth inhibition was determined using MTT reduction assay. The isobologram method of Steel and Peckham was used to evaluate the cytotoxic interaction. 2-F-ara-A and cytarabine showed synergistic effects in SKW-3 cells, additive and synergistic effects in JOK-1 and SALT-3 cells, and additive effects in ED-40810(-) cells. 2-F-ara-A and doxorubicin showed additive effects in SKW-3, ED-40810(-) and SALT-3 cell lines, and additive and synergistic effects in JOK-1 cells. 2-F-ara-A showed additive effects with etoposide, 4-hydroperoxy-cyclophosphamide, and hydroxyurea in all four cell lines. 2-F-ara-A showed antagonistic effects with methotrexate and vincristine in all four cell lines. Our findings suggest that the simultaneous administration of fludarabine phosphate with cytarabine, doxorubicin, etoposide, cyclophosphamide, or hydroxyurea would be advantageous for cytotoxic effects. Among these agents, cytarabine may be the best agent for the combination with fludarabine phosphate. The simultaneous administration of fludarabine phosphate with methotrexate or vincristine would have little cytotoxic effect, and this combination may be inappropriate. These findings may be useful in clinical trials of combination chemotherapy with fludarabine phosphate and these agents.

9-(2-Phosphonylmethoxyethyl)-N6-cyclopropyl-2,6-diaminopurine (cpr-PMEDAP) as a prodrug of 9-(2-phosphonylmethoxyethyl)guanine (PMEG)

9-(2-Phosphonylmethoxyethyl)-N6-cyclopropyl-2,6-diaminopurine (cpr-PMEDAP) is an acyclic nucleotide analog of the [9-(2-phosphonylmethoxyethyl)-] (PME) series containing a cyclopropyl substituent on the N6 position of the 2,6-diaminopurine (DAP) base. Growth inhibition assays in a broad range of tumor cell lines demonstrated that this analog had potent antiproliferative activity with IC50 values similar to those of the structurally related guanine analog 9-(2-phosphonylmethoxyethyl)guanine (PMEG). A substantially lower growth inhibitory effect was observed for the 2,6-diaminopurine analog, PMEDAP. To dissect the basis for these varying potencies, the metabolism of the three analogs was examined in a human pancreatic carcinoma cell line, BxPC-3. HPLC analysis of the intracellular metabolites demonstrated that the cpr-PMEDAP was deaminated to PMEG and subsequently phosphorylated to PMEG mono- and diphosphates (PMEGp and PMEGpp). The level of PMEGpp generated from cpr-PMEDAP-treated cells was 50% greater than the level generated from cells incubated with PMEG. The presence of PMEG in the DNA of cells incubated with cpr-PMEDAP confirmed that the cpr-PMEDAP was converted to PMEG. In contrast, PMEDAP was not deaminated to PMEG, but directly phosphorylated to PMEDAPp and PMEDAPpp. The adenylate deaminase inhibitor 2'-deoxycoformycin (dCF) inhibited the conversion of cpr-PMEDAP in a rat liver cytosolic extract and increased the IC50 value for growth inhibition by 40-fold. The antiproliferative activities of PMEG and PMEDAP were unaffected by dCF. Thus, it appears that cpr-PMEDAP, but not PMEDAP, is converted by an adenylate deaminase-like enzyme and functions as a prodrug of PMEG.

Fludarabine-based protocol for human umbilical cord blood transplantation in children with Fanconi anemia

PURPOSE

A novel conditioning regimen of fludarabine monophosphate (FLM), anti-T-lymphocyte globulin (ATG), and low-dose cyclophosphamide with no irradiation for human umbilical cord blood transplantation (HUCBT) for the treatment of Fanconi anemia (FA) is described.

PATIENT AND METHODS

A 12-year-old girl with FA received a human umbilical cord blood transplant from a fully matched sibling donor. After the HUCBT, the patient was given granulocyte colony stimulating factor in combination with erythropoietin. Pretransplant conditioning consisted of FLM (30 mg/m2/d) from day -10 to day -5, cyclophosphamide (10 mg/kg/d) on day -7 and -6, and rabbit ATG (ATG-Frasenius, 10 mg/kg/d) from day -4 to day -1. Cyclosporin A (3 mg/kg/d) was administered from day -1 as graft-versus-host disease prophylaxis. Cord blood from a sibling donor was used as a source of hematopoietic stem cells.

RESULTS

Engraftment was normal and sustained. The regimen was well tolerated with very mild toxicity and no major transplant-related complications or >grade II graft-versus-host disease. Chimerism was 100% donor origin as determined by restriction fragment length polymorphism.

CONCLUSIONS

It is possible to achieve sustained engraftment and only mild toxicity in FA after HUCBT with a conditioning regimen of FLM, ATG, and cyclophosphamide with no irradiation. These preliminary results with this novel conditioning protocol are encouraging and should be evaluated in a larger group of patients with FA undergoing HUCBT.

Incorporation and excision of 9-(2-phosphonylmethoxyethyl)guanine (PMEG) by DNA polymerase delta and epsilon in vitro

PMEG (9-(2-phosphonylmethoxyethyl)guanine) is an acyclic nucleotide analog being evaluated for its anti-proliferative activity. We examined the inhibitory effects of PMEG diphosphate (PMEGpp) toward DNA polymerases (pol) delta and epsilon and found it to be a competitive inhibitor of both these enzymes. The apparent Ki values for PMEGpp were 3-4 times lower than the Km values for dGTP. The analog was shown to function as a substrate and to be incorporated into DNA by both enzymes. Examination of the ability of pol delta and pol epsilon to repair the incorporated PMEG revealed that pol epsilon could elongate PMEG-terminated primers in both matched and mismatched positions with an efficiency equal to 27 and 85% that observed for dGMP-terminated control template-primers. Because PMEG acts as an absolute DNA chain terminator, the elongation of PMEG-terminated primers is possible only by cooperation of the 3'-5'-exonuclease and DNA polymerase activities of the enzyme. In contrast to pol epsilon, pol delta exhibited negligible activity on these template-primers, indicating that pol epsilon, but not pol delta, can repair the incorporated analog.

Ara-C: cellular and molecular pharmacology

The antimetabolite cytosine arabinoside (ara-C) represents a prototype of the nucleoside analog class of antineoplastic agents and remains one of the most effective drugs used in the treatment of acute leukemia as well as other hematopoietic malignancies. The ability of ara-C to kill neoplastic cells is regulated at three distinct but interrelated levels. First, the activity of ara-C depends on conversion to its lethal triphosphate derivative, ara-CTP, a process that is influenced by multiple factors, including nucleoside transport, phosphorylation, deamination, and levels of competing metabolites, particularly dCTP. Second, the antiproliferative and lethal effects of ara-C are linked to the ability of ara-CTP to interfere with one or more DNA polymerases as well as the degree to which it is incorporated into elongating DNA strands, leading to DNA fragmentation and chain termination. Finally, the fate of the cell is ultimately determined by whether a threshold level of ara-C-mediated DNA damage is exceeded, thereby inducing apoptosis, or programmed cell death. The latter process is influenced by components of various signal transduction pathways (e.g., PKC) and expression of oncogenes (e.g., bcl-2, c-Jun), perturbations in which may significantly alter ara-C sensitivity. A better understanding of these factors could eventually lead to the development of novel therapeutic strategies capable of overcoming ara-C resistance and improving therapeutic efficacy.

Differential Incorporation of Ara-C, Gemcitabine, and Fludarabine Into Replicating and Repairing DNA in Proliferating Human Leukemia Cells

The major actions of nucleoside analogs such as arabinosylcytosine (ara-C) and fludarabine occurs after their incorporation into DNA, during either replication or repair synthesis. The metabolic salvage and DNA incorporation of the normal nucleoside, deoxycytidine, is functionally compartmentalized toward repair synthesis in a process regulated by ribonucleotide reductase. The aim of this study was to investigate the metabolic pathways by which nucleoside analogs that do (fludarabine, gemcitabine) or do not (ara-C) affect ribonucleotide reductase are incorporated into DNA in proliferating human leukemia cells. Using alkaline density-gradient centrifugation to separate repaired DNA from replicating DNA and unreplicated parental DNA strands, approximately 60% of ara-C nucleotide in DNA was incorporated by repair synthesis in CCRF-CEM cells; the remainder was incorporated by replication. In contrast, fludarabine and gemcitabine, nucleosides that inhibit ribonucleotide reductase and decreased deoxynucleotide pools, were incorporated mainly within replicating DNA. Hydroxyurea also depleted deoxynucleotide pools and increased the incorporation of ara-C into DNA by replicative synthesis. Stimulation of DNA repair activity by UV irradiation selectively enhanced the incorporation of all nucleosides tested through repair synthesis. These findings suggest that the pathways by which therapeutically useful nucleoside analogs are incorporated into DNA are affected by cellular dNTP pools from de novo synthesis and by the relative activities of DNA repair and replication. The antitumor activity of these drugs may be enhanced by combination with either ribonucleotide reductase inhibitors to increase their incorporation into replicating DNA or with agents that induce DNA damage and evoke the DNA repair process.

Differential Incorporation of Ara-C, Gemcitabine, and Fludarabine Into Replicating and Repairing DNA in Proliferating Human Leukemia Cells

The major actions of nucleoside analogs such as arabinosylcytosine (ara-C) and fludarabine occurs after their incorporation into DNA, during either replication or repair synthesis. The metabolic salvage and DNA incorporation of the normal nucleoside, deoxycytidine, is functionally compartmentalized toward repair synthesis in a process regulated by ribonucleotide reductase. The aim of this study was to investigate the metabolic pathways by which nucleoside analogs that do (fludarabine, gemcitabine) or do not (ara-C) affect ribonucleotide reductase are incorporated into DNA in proliferating human leukemia cells. Using alkaline density-gradient centrifugation to separate repaired DNA from replicating DNA and unreplicated parental DNA strands, approximately 60% of ara-C nucleotide in DNA was incorporated by repair synthesis in CCRF-CEM cells; the remainder was incorporated by replication. In contrast, fludarabine and gemcitabine, nucleosides that inhibit ribonucleotide reductase and decreased deoxynucleotide pools, were incorporated mainly within replicating DNA. Hydroxyurea also depleted deoxynucleotide pools and increased the incorporation of ara-C into DNA by replicative synthesis. Stimulation of DNA repair activity by UV irradiation selectively enhanced the incorporation of all nucleosides tested through repair synthesis. These findings suggest that the pathways by which therapeutically useful nucleoside analogs are incorporated into DNA are affected by cellular dNTP pools from de novo synthesis and by the relative activities of DNA repair and replication. The antitumor activity of these drugs may be enhanced by combination with either ribonucleotide reductase inhibitors to increase their incorporation into replicating DNA or with agents that induce DNA damage and evoke the DNA repair process.

Anti-tumor mechanisms of 3'-ethynyluridine and 3'-ethynylcytidine as RNA synthesis inhibitors: development and characterization of 3'-ethynyluridine-resistant cells

To discover the mechanisms of anti-tumor action of 3'-ethynyluridine (EUrd) and 3'-ethynylcytidine (ECyd), we established an EUrd-resistant variant from human fibrosarcoma HT-1080 cells. The cells were cross-resistant to ECyd. Uridine/cytidine kinase activity diminished in the resistant cells. The incorporation of EUrd and ECyd into the RNA fraction in the resistant cells was less than that of the parental cells. EUrd-triphosphate inhibited RNA synthesis by human RNA polymerase II. The results led us to conclude that EUrd and ECyd are phosphorylated by uridine/cytidine kinase to 5'-triphosphates, and that their triphosphates might inhibit RNA polymerase.

Chemotherapeutic purine analogs alter the level of interferon-beta mRNA induced by poly I-poly C in cultured osteosarcoma cells

The purine nucleoside analogs fludarabine, 2-chlorodeoxyadenosine, and 2'-deoxycoformycin exhibit impressive activity in lymphoproliferative malignancies of adults and children. Their mechanism of action is not clear. Studies have suggested that their use is associated with significant myelosuppression, immunosuppression, and in some circumstances, increased infection with viral and opportunistic pathogens. Because interferons (IFNs) are known to have immunomodulatory activity as well as potent antiproliferative and antiviral activity, we examined whether the chemotherapeutic purine nucleoside analogs alter interferon-beta (IFN-B) gene expression in MG63 in human osteosarcoma cells. Northern blot analysis showed a dose-dependent inhibition of IFN-B mRNA accumulation in response to a known inducer (Poly I-Poly C) all three purine analogs. Hybridization analysis also revealed that inhibition of IFN-beta mRNA accumulation by the purine analogs is not a result of decreased mRNA stability. Further analysis of gene expression by PCR differential display indicated that the effect of the purine analogs was restricted to only a limited number of inducible genes. The data suggest that these molecules alter the signaling process involved in regulating the expression of specific genes, including IFN-beta. These findings predict that the use of purine nucleoside analogs may reduce IFN production in vivo and thereby abrogate host defenses against infectious pathogens.

Encapsulation, metabolism and release of 2-fluoro-ara-AMP from human erythrocytes

2-Fluoro-ara-AMP (fludarabine phosphate) is a purine analogue with anti-neoplastic activity in lymphoproliferative malignancies. Fludarabine phosphate activity and toxicity is schedule-dependent; multiple daily administrations (for five days) are more effective than single dose. We have encapsulated fludarabine phosphate in human erythrocytes and found that it is slowly released as fludarabine for more than four days. Encapsulated fludarabine phosphate does not affect erythrocyte metabolism and is rapidly converted by erythrocyte enzymes both to fludarabine with a Km of 0.4 mM and a Vmax of 20 nmol/min per g hemoglobin and to fludarabine diphosphate and triphosphate. The apparent Km for fludarabine monophosphate in the phosphorylation reaction was 0.4 mM and the Vmax 40 nmol/min per g hemoglobin. In the phosphorylation of 2-fluoro-ara-AMP to the di- and triphosphate derivatives, ATP was the phosphate donor with apparent Km of 0.12 and 1.0 mM, respectively. During incubations of 2-fluoro-ara-AMP-loaded erythrocytes at 37 degrees C fludarabine was found in equilibrium between the erythrocyte and the culture medium suggesting that permeation of the erythrocyte membrane is not rate-limiting. Thus, fludarabine phosphate-loaded erythrocytes might be used as a slow-delivery system for fludarabine administration in the treatment of lymphoid malignancies.

Fludarabine as a modulator of cisplatin activity in human tumour primary cultures and established cell lines

The potential of the purine analogue fludarabine (9-beta-D-arabinofuranosyl-2-fluoroadenine-5' monophosphate) as a modulator of cisplatin cytotoxicity was investigated in four established cell lines and 20 primary cultures of human melanoma and ovarian cancer. Tumour cells were exposed to fludarabine and cisplatin, alone or in combination, for 4 h. Fludarabine did not affect the growth of ovarian cancer cell lines, whereas it induced a marked and dose-dependent inhibition of proliferation in melanoma cell lines. In primary cultures of both histotypes, the purine analogue did not induce appreciable antiproliferative effects. Combined cisplatin-fludarabine treatment caused additive effects in all established cell lines. Conversely, a synergistic effect of the combination was seen in 5 of 10 melanoma and 4 of 10 ovarian cancer primary cultures, with a dose-modifying factor ranging from 2.1 to 3.9 for melanomas and from 4.0 to 7.5 for ovarian cancers, respectively. In the remaining cultures, the interaction between fludarabine and cisplatin was additive. The alkaline filter elution analysis performed on primary cultures showed that the synergistic interaction between the two drugs was paralleled by an increase in the extent and persistence of the cisplatin-induced DNA interstrand crosslinks. Our results indicate that fludarabine can enhance cisplatin cytotoxic activity in human tumour primary cultures from ovarian cancer and malignant melanoma. Such an effect may be partially due to an interference by fludarabine on cisplatin-induced DNA adduct metabolism and repair.

Inhibition of the 3' --> 5' exonuclease of human DNA polymerase epsilon by fludarabine-terminated DNA

Incorporation of the anticancer drug fludarabine (9-beta-D-arabinofuranosyl-2-fluoroadenine 5'-monophosphate; F-ara-AMP) into the 3'-end of DNA during replication causes termination of DNA strand elongation and is strongly correlated with loss of clonogenicity. Because the proofreading mechanisms that remove 3'-F-ara-AMP from DNA represent a possible means of resistance to the drug, the present study investigated the excision of incorporated F-ara-AMP from DNA by the 3' --> 5'-exonuclease activity of DNA polymerase epsilon from human leukemia CEM cells. Using the drug-containing and normal deoxynucleotide oligomers (21-base) annealed to M13mp18(+) DNA as the excision substrates, we demonstrated that DNA polymerase epsilon was unable to effectively remove F-ara-AMP from the 3'-end of the oligomer. However, 3'-terminal dAMP and subsequently other deoxynucleotides were readily excised from DNA in a distributive fashion. Kinetic evaluation demonstrated that although DNA polymerase epsilon has a higher affinity for F-ara-AMP-terminated DNA (Km = 7.1 pM) than for dAMP-terminated DNA of otherwise identical sequence (Km = 265 pM), excision of F-ara-AMP proceeded at a substantially slower rate (Vmax = 0.053 pmol/min/mg) than for 3'-terminal dAMP (Vmax = 1.96 pmol/min/mg). When the 3'-5' phosphodiester bond between F-ara-AMP at the 3'-terminus and the adjacent normal deoxynucleotide was cleaved by DNA polymerase epsilon, the reaction products appeared to remain associated with the enzyme but without the formation of a covalent bond. No further excision of the remaining oligomers was observed after the addition of fresh DNA polymerase epsilon to the reaction. Furthermore, the addition of DNA polymerase alpha and deoxynucleoside triphosphates to the excision reaction failed to extend the oligomers. After DNA polymerase epsilon had been incubated with 3'-F-ara-AMP-21-mer for 10 min, the enzyme was no longer able to excise 3'-terminal dAMP from a freshly added normal 21-mer annealed to M13mp18(+) template. We conclude that the 3' --> 5' exonuclease of human DNA polymerase epsilon can remove 3'-terminal F-ara-AMP from DNA with difficulty and that this excision results in a mechanism-mediated formation of "dead end complex."

FLAG (fludarabine, cytarabine, G-CSF) as a second line therapy for acute lymphoblastic leukemia with myeloid antigen expression: in vitro and in vivo effects

Thirteen consecutive adult patients with primary refractory (n = 5) or relapsed (n = 8) acute lymphoblastic leukemia (ALL) were treated by an induction schedule (FLAG) consisting of Fludarabine (30 mg/sqm/d) plus high dose Cytarabine (HD-ara-C: 2 g/sqm/d) (d 1-5) and G-CSF (from d O to polymorphonuclear recovery). Patients achieving complete remission (CR) were administered a second FLAG course as consolidation and were then submitted to an individualized program of post-remission therapy, depending on the patient's age and performance status. CR was achieved in 8/12 evaluable cases (67%). The median CR duration was 22.5 w. CR attainment was significantly related to the co-expression of lymphoid and myeloid antigens. ALL/My+ patients achieved CR in 6/6 evaluable cases vs. 2/6 for ALL/My+. In vitro 3H ara-C incorporation into cellular DNA resulted significantly increased by Fludarabine (in 7/9 tested cases) and, furthermore, by the association of Fludarabine G-CSF in 5 evaluable ALL/My+ cases; in contrast, no effect of G-CSF addition to Fludarabine was observed in 4 ALL/My. Myelosuppression was observed in all patients: the median time to neutrophils > 0.5 x 10(9)/1 was 16.3 d (range 13-22) and 16.2 d (range 9-29) to platelets > 20 x 10(9)/1. Nonhematological toxicity was minimal. In conclusion, FLAG is an active and tolerable combination in refractory ALL, particularly in cases with myeloid antigen expression where G-CSF appears to improve efficacy, probably increasing ara-C incorporation into the DNA of leukemic cells.

Natural killer cell activity in chronic lymphocytic leukemia patients treated with fludarabine

Fludarabine, the 5'-monophosphate of 9-beta-D-arabinofuranosyl-2- fluoroadenine (FaraAMP), is effective in the treatment of chronic lymphocytic leukemia (CLL) and has been demonstrated to increase natural killer (NK) cell lytic activity (NKa) in humans and mice. To determine the effect of FaraAMP on NK cells in CLL, we analyzed NKa toward K562 targets after in vitro incubation with FaraAMP and after in vivo exposure to fludarabine. Pretreatment analysis of peripheral blood from 12 CLL patients (9 untreated) revealed: median number of NK cells 500/microliter (range 290-1160); median NKa lytic unit30/10(6) cells (range 5-80). These results were similar to those from healthy adult donors. After exposure to 3, 30 or 300 microM FaraAMP, the median maximum stimulation index (NKa FaraAMP/NKa) was 1.2 (range 0.9-1.5), within the range observed in normal adults. FaraA also stimulated NKa in vitro toward autologous CLL cells in two of five patients as measured by a dye-exclusion assay. In three patients following three or more treatment courses of fludarabine (30 mg/m2 per day for 5 days) the NK cell number and NKa were maintained near pretreatment values. Phenotypic analysis of the peripheral mononuclear cells in 34 consecutive CLL patients revealed a marked reduction in CD5/CD20 and CD4 cell numbers after three courses of fludarabine with less effect on CD8 and CD56 cells. These results indicate that fludarabine spares NK cells and may stimulate NKa in some CLL patients.

Mechanisms for the anti-hepatitis B virus activity and mitochondrial toxicity of fialuridine (FIAU)

Fialuridine (FIAU) is a thymidine nucleoside analog with activity against various herpesviruses and hepatitis B virus (HBV) in vitro and in vivo. In a clinical evaluation for its use as a treatment for chronic HBV infection, long term (HBV) in vitro and in vivo. In a clinical evaluation for its term oral administration of FIAU resulted in severe multi-organ toxicity characterized by a delayed onset and refractory lactic acidosis. These clinical manifestations led to the hypothesis that the toxicity of FIAU was mediated through mitochondrial dysfunction, possibly as a result of the inhibition of mitochondrial DNA polymerase gamma and/or incorporation of FIAU into mitochondrial DNA. In addition to describing the anti-HBV activity of FIAU, this review discusses results from in vitro experiments carried out by various laboratories in an effort to evaluate and understand more fully the mitochondrial toxicity of FIAU.

Purine nucleoside therapy of low-grade follicular lymphoma

Low-grade follicular lymphomas, follicular small cleaved and follicular mixed, generally follow an indolent but progressive course. Although available therapies induce responses, continuous relapse occurs. In investigating potential therapeutic regimens, researchers have sought regimens that will result in a postchemotherapy survival plateau rather than a pattern of continuous relapse. The newer, purine analogs, 2'-deoxycoformycin, fludarabine, and 2-chlorodeoxyadenosine have shown activity in the low-grade B-cell lymphomas, especially with the follicular histologic subtype. Response rates in studies of previously untreated patients approach 100%. The newer purine analogs are emerging as an important treatment approach for indolent B-cell lymphomas, but the impact on survival remains to be assessed.

The nuclear matrix as a site of anticancer drug action

Many nuclear functions, including the organization of the chromatin within the nucleus, depend upon the presence of a nuclear matrix. Nuclear matrix proteins are involved in the formation of chromatin loops, control of DNA supercoiling, and regulation and coordination of transcriptional and replicational activities within individual loops. Various structural and functional components of the nuclear matrix represent potential targets for anticancer agents. Alkylating agents and ionizing radiation interact preferentially with nuclear matrix proteins and matrix-associated DNA. Other chemotherapeutic agents, such as fludarabine phosphate and topoisomerase II-active drugs, interact specifically with matrix-associated enzymes, such as DNA primase and the DNA topoisomerase II alpha isozyme. The interactions of these agents at the level of the nuclear matrix may compromise multiple nuclear functions and be relevant to their antitumor activities.

Purine analogues in the management of lymphoproliferative diseases

Three analogues of the purine 2-deoxyadenosine are available for the treatment of low grade lymphoproliferative disorders: pentostatin, cladribine and fludarabine. They have some common features in their mode of action, but differ both in their detailed pharmacology and the extent to which they have activity against specific lymphoid malignancies. Studies defining the scope of these drugs as single agents are now being followed by plans to exploit their potential synergy with other agents and clinically to define useful combination therapies.

Key issues in the treatment of chronic lymphocytic leukaemia (CLL)

The outcome of the treatment of chronic lymphocytic leukaemia (CLL) has improved little over the past 30 years. The recent introduction of purine analogues, particularly fludarabine, may change this situation. These agents are highly effective and generally well tolerated. They raise the possibility of improved disease-free survival and allow appropriate patients to be considered for bone marrow transplantation (BMT). Randomised clinical trials are needed to establish the roles of purine analogues and other novel agents in improving the survival of CLL patients. These trials should use consistent diagnostic and assessment criteria to allow for the clinical heterogeneity of CLL.

Effect of intra-peritoneal fludarabine on rat spinal cord tolerance to fractionated irradiation

The effect of fludarabine (9-beta-D-arabinosyl-2-fluoroadenine-5'- monophosphate), an adenine nucleoside analogue, on the tolerance of the spinal cord to fractionated irradiation was studied in a rat model. Anesthetized female Fisher 344 rats received irradiation to 2 cm of the cervical spine with a telecobalt unit (dose rate 1.14 Gy/min). Radiation was administered in two, four or eight fractions spread over a 48-h period with or without fludarabine. Animals assigned to combined therapy received two daily intraperitoneal injections of fludarabine (150 mg/kg) given 3 h prior to the first daily radiation fraction. It was found that fludarabine reduced the iso-effect dose required to induce leg paresis at 9 months after irradiation for all fractionation schedules. Dose modification factors of 1.23, 1.29 and greater than 1.27 were obtained for two, four and eight fractions, respectively. Fitting the data with the direct analysis method of Thames et al. with an incomplete repair model [18] showed that the potentiating effect of fludarabine may be mediated through reduction in the number of 'tissue-rescuing units' (InK). Alpha and beta values were slightly but not significantly decreased, whereas the alpha/beta ratio was unchanged. These features suggest that fludarabine did not significantly inhibit cellular repair processes but rather reduced the spinal cord tolerance by a fixed additive toxic effect on the same target cells. In rodent models, the combination of fludarabine and fractionated radiation has previously been found to yield a therapeutic gain, i.e., the drug enhanced tumor response to a greater extent than it reduced normal tissue tolerance.(ABSTRACT TRUNCATED AT 250 WORDS)

Fludarabine- and gemcitabine-induced apoptosis: incorporation of analogs into DNA is a critical event

The nucleoside analogs fludarabine and gemcitabine inhibit cellular DNA synthesis by two different mechanisms: (1) direct termination of DNA strand elongation after the triphosphate of each drug is incorporation into DNA; and (2) indirect inhibition of DNA synthesis by decreasing cellular dNTPs through inhibition of ribonucleotide reductase. The present study demonstrated that incorporation of the analogs into DNA is critical for the cytotoxic action of these drugs in human T lymphoblastoid CEM cells. S phase cells, which actively incorporated the analogs into DNA, were most sensitive to the cytotoxic action of these compounds. A relatively short-term (5-24 h) cessation of cellular DNA synthesis without analog incorporation was not sufficient to cause cell death. The drug-treated cells died through apoptosis characterized by generation of internucleosomal DNA fragmentation and apoptotic morphology. Induction of high molecular mass (50-500 kb) DNA fragmentation was also observed in cells undergoing apoptosis; this type of DNA degradation was strongly correlated with the analog-induced cell death process. Inhibition of the analog incorporation into DNA by aphidicolin blocked both types of DNA fragmentation and apoptotic morphology, indicating the essential role of analog incorporation into DNA in drug-induced cell death.

Fludarabine improves the therapeutic ratio of radiotherapy in mouse tumors after single-dose irradiation

PURPOSE

Fludarabine, an adenine nucleoside analogue, and an effective inhibitor of chromosome repair, was previously shown to synergistically enhance radiation-induced regrowth delay in three murine tumors. The purpose of this study was to assess whether fludarabine can increase the therapeutic ratio of radiotherapy in murine tumors, that is, to increase local tumor control without significantly modifying the radiation-induced normal tissue response.

METHODS AND MATERIALS

Mice bearing 8-mm tumors in the right thigh (SA-NH sarcoma and MCA-K mammary carcinoma) were given 800 mg/kg fludarabine IP 3 h or 24 h before single doses of photon irradiation. Local tumor control was assessed by the TCD50 assay 100 days after treatment. Acute normal tissue toxicity was assessed in the skin (degree of epilation 30 days after irradiation) and in the jejunum (crypt regeneration assay), and late normal tissue toxicity was assessed by a leg contracture assay 120 days after treatment.

RESULTS

In both tumors and with both drug schedules, fludarabine enhanced radiation-induced local tumor control (dose modification factors (DMF) of 1.24 (95% confidence limits 1.19-1.31) and 1.26 (95% confidence limits 1.20-1.32) for SA-NH, and 1.38 (95% confidence limits 1.25-1.50) and 1.35 (95% confidence limits 1.22-1.16) for MCA-K tumors). When given 3 h before radiation, fludarabine offered a slight protection from skin toxicity (DMF = 0.83, 95% confidence limits 0.77-0.86) but enhanced jejunum toxicity (DMF = 1.53). When fludarabine was given 24 h before irradiation, the reverse trend was observed (DMF = 1.11 (95% confidence limits 1.07-1.16) and 0.89, respectively). No enhancement of leg contracture was observed for either fludarabine schedule.

CONCLUSION

The data presented here demonstrate that fludarabine can potentiate local tumor control induced by single-dose irradiation. While jejunum sensitization limited the relative effectiveness when fludarabine was administered 3 h before irradiation, a therapeutic ratio greater than one was always achieved when fludarabine was given 24 h before irradiation.

Treatment of refractory T-cell chronic lymphocytic leukemia with purine nucleoside analogues

This report describes two cases of T-cell chronic lymphocytic leukemia (T-CLL) treated with purine nucleoside analogues. One patient had CD8+, CD3+ large granular lymphocytosis (LGL) producing transfusion-dependent anemia and was refractory to chemotherapy. Treatment with four cycles of fludarabine produced a clinical complete remission and a molecular genetic partial remission that has been durable for > 15 months. The other patient had CD4+ T-prolymphocytic leukemia and was unresponsive to both fludarabine and 2-chlorodeoxyadenosine. Further trials of these agents are warranted in T-CLL, especially the LGL variant.

Fludarabine phosphate. A new anticancer drug with significant activity in patients with chronic lymphocytic leukemia and in patients with lymphoma

Fludarabine phosphate is a purine antimetabolite approved for use in the management of patients with chronic lymphocytic leukemia. Fludarabine works primarily by inhibiting DNA synthesis. The compound also possesses lymphocytotoxic activity with preferential activity toward T-lymphocytes. Initial preclinical studies demonstrated antitumor activity with fludarabine against L1210 murine leukemia. In phase I studies, myelosuppression was identified as the dose-limiting toxicity in patients with solid tumors and fatal neurotoxicity as the dose-limiting toxicity in adult patients with acute hematologic malignancies. The recommended dose and schedule was determined to be 18-25 mg/m2/d for five days, repeated every 28 days. Unlike preclinical studies, phase II trials showed a lack of significant effect when fludarabine was given to patients with solid tumors. However, phase II investigations have confirmed the efficacy of fludarabine in lymphoid malignancies, including non-Hodgkin's lymphoma, mycosis fungoides, prolymphocytic leukemia, and chronic lymphocytic leukemia. The place of fludarabine in the management of leukemias in children is under investigation. Early results indicate an unusual degree of antitumor activity when the agent is used in combination chemotherapy for patients with refractory disease. Fludarabine is an effective antitumor agent in the management of lymphoid malignancies. Studies are ongoing to more completely define the role of fludarabine in these malignancies as well as in the pediatric leukemias. Additional studies evaluating the activity of fludarabine as an immunomodulator are warranted, due to the lymphocytotoxic properties associated with this agent.

Fludarabine inhibits DNA replication: a rationale for its use in the treatment of acute leukemias

Fludarabine is a prodrug that must enter cells and be phosphorylated to the nucleoside triphosphate, F-ara-ATP, to elicit biological activity. F-ara-ATP serves as an inhibitory alternative substrate in several key processes involved in DNA synthesis. The enzymes required in DNA synthesis and affected by F-ara-ATP are ribonucleotide reductase, DNA primase, DNA polymerases, 3'-5' exonuclease activity of DNA polymerases delta and epsilon, and DNA ligase I. The action of fludarabine on DNA replication provides a compelling rationale to use this agent for leukemias where target cells are actively synthesizing DNA, for example acute myelogenous leukemia. Additionally, the role of F-ara-ATP to potentiate the activity of deoxycytidine kinase makes it an appropriate candidate to use in combination with other nucleoside analogs which require deoxycytidine kinase for their activation. The present article reviews the effect of fludarabine on enzymes involved in DNA synthesis and the role of fludarabine in combination with arabinosylcytosine for the treatment of diseases other than indolent leukemias.

Cellular pharmacology of fludarabine triphosphate in chronic lymphocytic leukemia cells during fludarabine therapy

The pharmacology of fludarabine triphosphate (F-ara-ATP) in leukemic lymphocytes was studied during a phase II trial of fludarabine in 24 patients with chronic lymphocytic leukemia (CLL). Fludarabine was given as a 30-min i.v. infusion at a dose of 25 or 30 mg/m2 daily for 5 days. The concentrations of F-ara-ATP, the active metabolite of fludarabine, were determined in leukemic lymphocytes at intervals up to 24 hr after the first infusion. A median peak concentration of 19 microM (range, 6-52 microM) was generally reached 4 hr after the beginning of the infusion. No significant relationship was observed between clinical response and the median peak level of F-ara-ATP or the retention of F-ara-ATP in leukemic lymphocytes. In vitro incubation of CLL cells with the parent nucleoside of fludarabine, arabinosyl-2-fluoroadenine (F-ara-A), indicated that F-ara-ATP accumulated in a linear fashion in response to the product of the F-ara-A concentration times the duration of incubation. Exposing cells longer with lower F-ara-A concentrations or shorter with higher F-ara-A concentrations resulted in similar intracellular levels of F-ara-ATP as long as the products of fludarabine concentration and time of exposure were equal. These results and the fact that the fludarabine dose rate currently administered is well tolerated suggest that it may be the optimal dose rate for F-ara-ATP accumulation in CLL cells.

Fludarabine for treatment of adult acute myelogenous leukemia

The success of fludarabine as a single agent for therapy of chronic lymphocytic leukemia suggested its use in other leukemias such as adult acute myelogenous leukemia. Because doses that are tolerated in the clinic were not effective in the treatment of acute myelogenous leukemia, our approach was to combine low dose fludarabine with other active agents such as arabinosylcytosine (ara-C). This is also based on the rationale that fludarabine pretreatment modulates the metabolism of ara-C resulting in potentiation of the accumulation of its triphosphate. Improved response rates and clinical efficacy of this combination further suggested combining this couplet with DNA damaging agents, because the active triphosphates of both these analogs inhibit replication and repair processes of DNA synthesis.

Protection against fludarabine neurotoxicity in leukemic mice by the nucleoside transport inhibitor nitrobenzylthioinosine

Fludarabine phosphate (F-ara-AMP, Fludara) is rapidly converted in the circulation to fludarabine (F-ara-A) and is among the most effective single agents in the treatment of chronic lymphocytic leukemia. Although current treatment protocols are well tolerated, severe neurotoxicity was a consequence of high-dose F-ara-AMP regimens used in early phase I trials against adult acute leukemia. The present study showed that in mice implanted with leukemia L1210, fatal neurotoxicity, which initially manifested as hind-limb paralysis, was a consequence of high-dose F-ara-AMP treatment. However, the incidence of neurotoxicity was reduced by the coadministration of NBMPR-P, the 5'-phosphate of nitrobenzylthioinosine, a potent inhibitor of the es equilibrative nucleoside transport (NT) system. NBTGR-P, the 5'-phosphate of nitrobenzylthioguanosine (also a potent NT inhibitor) similarly prevented F-ara-AMP neurotoxicity in this experimental system. Treatment with F-ara-AMP/NBMPR-P combinations was more effective with respect to the fractional yield of "cured" mice than were the same treatment regimens without NBMPR-P.

Metabolism and action of purine nucleoside analogs

Recent investigations have identified many new purine nucleoside analogs that act as antimetabolites. This article focuses on the metabolism and mechanisms of action of tiazofurin, 3-deazaguanosine, neplanocin A, arabinosyladenine in combination with inhibitors of adenosine deaminase, arabinosyl-2-fluoroadenine, and 2-chloro-2'-deoxyadenosine, drugs that are either currently being evaluated in clinical trials or are close to that stage. The diverse metabolic requirements for activation, unique mechanisms of action, and differential biological activities of these compounds are characterized and evaluated for prospective therapeutic application.