Correction: Duncan, K.R., Suzuki, Y.J. Vitamin E Nicotinate. Antioxidants 2017, 6, 20.

In the original version of our article [1], three lines were omitted from the α-tocopherol and α-tocopheryl nicotinate structures in Figure 1 during the manuscript processing[...].

Subdiaphragmatic Vagotomy With Pyloroplasty Ameliorates the Obesity Caused by Genetic Deletion of the Melanocortin 4 Receptor in the Mouse.

Background/Objectives: We tested the hypothesis that abolishing vagal nerve activity will reverse the obesity phenotype of melanocortin 4 receptor knockout mice (Mc4r-/-). Subjects/Methods: In two separate studies, we examined the efficacy of bilateral subdiaphragmatic vagotomy (SDV) with pyloroplasty in the prevention and treatment of obesity in Mc4r-/- mice. Results: In the first study, SDV prevented >20% increase in body weight (BW) associated with this genotype. This was correlated with a transient reduction in overall food intake (FI) in the preventative arm of the study. Initially, SDV mice had reduced weekly FI; however, FI normalized to that of controls and baseline FI within the 8-week study period. In the second study, the severe obesity that is characteristic of the adult Mc4r-/- genotype was significantly improved by SDV with a magnitude of 30% loss in excess BW over a 4-week period. Consistent with the first preventative study, within the treatment arm, SDV mice also demonstrated a transient reduction in FI relative to control and baseline levels that normalized over subsequent weeks. In addition to the accompanying loss in weight, mice subjected to SDV showed a decrease in respiratory exchange ratio (RER), and an increase in locomotor activity (LA). Analysis of the white fat-pad deposits of these mice showed that they were significantly less than the control groups. Conclusions: Altogether, our data demonstrates that SDV both prevents gain in BW and causes weight loss in severely obese Mc4r-/- mice. Moreover, it suggests that an important aspect of weight reduction for this type of monogenic obesity involves loss of signaling in vagal motor neurons.

Vitamin E Nicotinate.

Vitamin E refers to a family of compounds that function as lipid-soluble antioxidants capable of preventing lipid peroxidation. Naturally occurring forms of vitamin E include tocopherols and tocotrienols. Vitamin E in dietary supplements and fortified foods is often an esterified form of α-tocopherol, the most common esters being acetate and succinate. The vitamin E esters are hydrolyzed and converted into free α-tocopherol prior to absorption in the intestinal tract. Because its functions are relevant to many chronic diseases, vitamin E has been extensively studied in respect to a variety of diseases as well as cosmetic applications. The forms of vitamin E most studied are natural α-tocopherol and the esters α-tocopheryl acetate and α-tocopheryl succinate. A small number of studies include or focus on another ester form, α-tocopheryl nicotinate, an ester of vitamin E and niacin. Some of these studies raise the possibility of differences in metabolism and in efficacy between vitamin E nicotinate and other forms of vitamin E. Recently, through metabolomics studies, we identified that α-tocopheryl nicotinate occurs endogenously in the heart and that its level is dramatically decreased in heart failure, indicating the possible biological importance of this vitamin E ester. Since knowledge about vitamin E nicotinate is not readily available in the literature, the purpose of this review is to summarize and evaluate published reports, specifically with respect to α-tocopheryl nicotinate with an emphasis on the differences from natural α-tocopherol or α-tocopheryl acetate.

ICI D1694, a quinazoline antifolate thymidylate synthase inhibitor that is a potent inhibitor of L1210 tumor cell growth in vitro and in vivo: a new agent for clinical study.

N-(5-[N-(3,4-dihydro-2-methyl-4-oxoquinazolin-6-ylmethyl)-N- methylamino]-2-thenoyl)-L-glutamic acid (ICI D1694) is a water-soluble, folate-based thymidylate synthase (TS) inhibitor designed to be a less toxic and more potent analogue of the clinically tested N10-propargyl-5,8-dideazafolic acid. Inhibition of isolated L1210 TS by ICI D1694 is mixed noncompetitive (although tending toward competitive), with a Ki of 62 nM (Kies = 960 nM). The synthetic gamma-polyglutamates are up to 2 orders of magnitude more potent as inhibitors of TS; e.g., the tetraglutamate (glu4) has a Ki of 1.0 nM (Kies = 15 nM). Although inhibitory activity of ICI D1694 toward rat liver dihydrofolate reductase was similar to that of TS (Ki = 92 nM; competitive inhibition) the polyglutamate derivatives did not show enhanced activity. ICI D1694 was also a very potent inhibitor of L1210 cell growth (50% inhibitory activity = 8 nM). L1210 growth inhibition was not observed in the presence of thymidine, consistent with TS being the locus of action. Folinic acid antagonized L1210 growth inhibition in a competitive fashion such that the highest folinic acid concentration used (25 microM) increased the 50% inhibitory activity 6000-fold. When given as a 4-h delayed "rescue", folinic acid was much less effective in antagonizing growth inhibition. These observations are consistent with folinic acid competing with ICI D1694 for uptake into the cell and/or intracellular polyglutamation. The L1210:1565 cell line, which has greatly impaired reduced-folate/methotrexate transport and thus is resistant to methotrexate, was significantly cross-resistant to ICI D1694 (121-fold), suggesting that ICI D1694 is dependent on this uptake mechanism for good cytotoxic potency in L1210 cells. L1210 cells that were incubated for 4 h with 0.1 microM 3H-ICI D1694 accumulated approximately 1.5 microM intracellular 3H, and the high performance liquid chromatography analysis of the cell extracts demonstrated that 96% of the 3H was associated with the ICI D1694 polyglutamate fractions (principally glu4). Upon resuspension in drug-free medium for 24 h, approximately 75% of the cellular 3H was retained, this being the higher polyglutamate pool (glu4-6). In mice, after a single bolus injection of 10 mg/kg of ICI D1694, TS was inhibited greater than 80% for 24 h in ascitic L1210:NCI cells (as measured by the rate of 3H release from [5-3H]deoxyuridine). ICI D1694 cured the L1210:ICR ascitic tumor in mice at 0.4 mg/kg daily for 5 days (maximum tolerated dose, approximately 50 mg/kg).(ABSTRACT TRUNCATED AT 400 WORDS)

Characterisation of chondroitin/dermatan sulphate proteoglycans synthesised by rat mammary myoepithelial and fibroblastic cell lines.

Chondroitin sulphate proteoglycans were isolated from the culture medium of rat mammary gland fibroblast (Rama 27) and myoepithelial (Rama 401) cell lines which had been labelled with [35S]sulphate. Chromatography on Sepharose CL-4B indicated that the Rama 401 proteoglycan was larger than the Rama 27 proteoglycan (Kav values 0.47 and 0.56, respectively). Treatment of the proteoglycans with alkaline NaBH4 yielded chondroitin sulphate chains with average M(r) values of 37,000 (Rama 401) and 21,000 (Rama 27). Structural analysis of the glycosaminoglycan chains indicated that both were co-polymers of chondroitin and dermatan sulphate although there were differences in the amounts and distribution of the disaccharide repeating units. The M(r) values of the core proteins, determined by immunoblotting, were about 43,000 and 46,000 (Rama 27) and 44,500 (Rama 401). Using an antibody to chondroitin sulphate proteoglycan in immunofluorescence experiments, the proteoglycan was demonstrated on the surface of both cell lines. Rama 27 cells additionally possessed an extensive fibrous extracellular matrix which also stained with the antibody. Staining of sections of lactating mammary gland suggested that the proteoglycan was present in the basement membrane as well as the stromal connective tissue. The presence of chondroitin sulphate proteoglycan in the basement membrane was confirmed by ultrastructural immunolocalisation.

Cellular pharmacology and in vivo activity of a new anticancer agent, ZD9331: a water-soluble, nonpolyglutamatable, quinazoline-based inhibitor of thymidylate synthase.

ZD9331 is a drug that was developed from a potent class of water-soluble, C7-methyl-substituted, quinazoline-based inhibitors of thymidylate synthase (TS) that are transported into cells via a saturable, carrier-mediated system (reduced folate carrier, or RFC) but are not substrates for folylpolyglutamate synthetase. ZD9331 is the gamma-tetrazole analogue of 2-desamino-2, 7-dimethyl-N10-propargyl-2'fluoro-5,8-dideaza folate (ZM214888), with a TS Ki of approximately 0.4 nM. ZD9331 exhibits potent growth inhibitory and cytotoxic activity; e.g., IC50 for the inhibition of human W1L2 lymphoblastoid cell line was 7 nM. The addition of thymidine to the culture medium increased the IC50 in W1L2 cells >10, 000-fold, demonstrating the high specificity of the drug for TS. ZD9331 is transported into cells predominantly via the RFC. Accordingly, it competes with methotrexate (MTX) and folinic acid for cellular uptake and has reduced activity against two cell lines with low expression of the RFC (L1210:1565 and CEM/MTX). In addition, a cell line with acquired resistance to ZD9331 displays reduced uptake of both ZD9331 and MTX. A mouse cell line (L1210:RD1694), with acquired resistance to ZD1694 due to reduced folylpolyglutamate synthetase activity, was not significantly cross-resistant to ZD9331. The flux through TS, as measured by 3H release from 5-[3H]deoxyuridine, was rapidly inhibited when cells were incubated with ZD9331. However, because ZD9331 cannot form polyglutamates, TS activity recovered rapidly once cells were placed in drug-free medium. The minimum curative dose of ZD9331 in the i.m. L5178Y TK-/- tumor model was approximately 3 mg/kg when given by 24-h continuous infusion, and it was 25-50 mg/kg when given by a single i.p. or i.v. injection. ZD9331 had antitumor activity against the L5178Y TK+/- tumor when administered by 7-day continuous infusion; growth delays of more than 5 days (and some cures) were seen at doses of 25-50 mg/kg/day. At higher doses, significant weight loss (gastrointestinal toxicity) and myelosuppression (neutropenia and thrombocytopenia) were observed, suggesting that these may be dose-limiting toxicities in the Phase I clinical studies.

Combination of raltitrexed with other cytotoxic agents: rationale and preclinical observations.

Agents for use in combination therapy should be effective as monotherapy in the tumour type of interest, have different mechanisms of action or pharmacology, and preferably non-overlapping toxicity profiles. Raltitrexed is effective as monotherapy in a number of tumour types, but it is hoped that combining it with other cytotoxic agents will lead to enhanced efficacy. Raltitrexed and 5-fluorouracil (5-FU) are specific and non-specific inhibitors, respectively, of thymidylate synthase, a critical enzyme in the de novo synthesis of DNA. Preclinical studies have indicated that raltitrexed and 5-FU have an incompletely overlapping spectrum of antitumour activity and may have additive or synergistic effects on colon carcinoma cells. These interactions are schedule-dependent (raltitrexed should precede 5-FU). Pre-treatment of colon carcinoma cells with raltitrexed has also been shown to increase intracellular levels of phosphoribosyl pyrophosphate resulting in increased incorporation of 5-FU nucleotides into RNA. Raltitrexed has a different mechanism of action from two other new agents active in colorectal cancer, irinotecan and oxaliplatin, and tumours are therefore not necessarily cross-resistant. Short pre-exposure of colon carcinoma cells to the irinotecan active metabolite, 7-ethyl-10-hydroxy-camptothecin (SN-38), prior to exposure to raltitrexed has consistently resulted in synergistic cell kill, whereas the reverse sequence is antagonistic. Preliminary results indicate that equitoxic doses of raltitrexed and cisplatin, or oxaliplatin, are antagonistic in two colon carcinoma cell lines. However, because there are major difficulties in translating preclinical drug combination results to the clinical settings, these results should be interpreted with caution.

Relationships between resistance to cisplatin and antifolates in sensitive and resistant tumour cell lines.

Possible relationships between tumour resistance to cisplatin and the folate-based thymidylate synthase (TS) inhibitors, CB3717 and ZD1694 (tomudex), have been investigated in vitro using a panel of tumour cell lines (predominantly human ovarian), either parental or possessing acquired resistance to cisplatin or ZD1694. Across eight parent human tumour cell lines, ZD1694 was the most potent drug (mean IC50 of 1.9 x 10(-8) M), being over 250 times as potent as its prototype CB3717 (mean IC50 of 4.8 x 10(-6) M). In five pairs of acquired cisplatin-resistant human tumour cell lines (three ovarian, one cervical and one testicular) which encompass all of the main known mechanisms of platinum drug resistance, ZD1694, CB3717 and the DHFR inhibitor, methotrexate, all exhibited non-cross-resistance. The cervical line, HX/155cisR, showed collateral sensitivity to ZD1694, CB3717, 5-fluorouracil (FUra) and fluorodeoxyuridine (FdUrd). One cell line, A2780cisR, showed a low level of cross-resistance to FUra (resistance factor, RF, of 1.5) and FdUrd (RF of 3.8). A2780cisR, in common with two other cisplatin-resistant lines, did not possess elevated TS activity compared with its parent. Cisplatin retained activity in four acquired ZD1694-resistant cell lines (encompassing reduced folate transport, elevated TS and defective polyglutamation mechanisms of resistance). Furthermore, combinations of ZD1694 with each of the platinum-based drugs, cisplatin, carboplatin and the recently introduced orally administrable, JM216, all showed additive growth inhibitory effects by median effect analysis. These data suggest that the tumour inhibitory properties of the recently introduced highly potent TS inhibitor, ZD1694, and cisplatin, and, moreover, their respective mechanisms of resistance, do not overlap. Therefore, these drugs may be considered for combination in the clinic.

ZD1694 (Tomudex): a new thymidylate synthase inhibitor with activity in colorectal cancer.

ZD1694 (Tomudex) is a new antifolate which is a specific inhibitor of thymidylate synthase (TS). Evidence suggests that ZD1694 has a spectrum of activity that only partially overlaps with 5-fluorouracil (modulated with leucovorin) against colon tumours in vitro. Potent cytotoxic activity is dependent upon active uptake into cells via the reduced folate/methotrexate cell membrane carrier (RFC) and subsequent metabolism to polyglutamated forms (tri, tetra and pentaglutamates). These polyglutamates are approximately 60-fold more active as TS inhibitors and are not effluxed readily from cells. Extensive polyglutamation also occurs in various mouse tissues (e.g. small intestinal epithelium, liver and kidney), resulting in high tissue/plasma drug ratios which persist for a prolonged period. ZD1694 has antitumour activity in mice, although the high plasma thymidine in this species complicates: (1) the interpretation of therapeutic index; (2) tumour types in which activity is likely to be observed; and (3) translation of doses and schedules for clinical evaluation. ZD1694 entered clinical study and has completed Phase I and II evaluation, with activity observed in several tumour types. Appreciable activity in the Phase II colorectal study (29% objective response rate on interim analysis) led to the current Phase III study, randomised against 5-fluorouracil/leucovorin.

Quinazoline antifolate thymidylate synthase inhibitors: gamma-linked L-D, D-D, and D-L dipeptide analogues of 2-desamino-2-methyl-N10-propargyl-5,8-dideazafolic acid (ICI 198583).

The syntheses of gamma-linked L-D, D-D, and D-L dipeptide analogues of 2-desamino-2-methyl-N10-propargyl-5,8-dideazafolic acid (ICI 198583) are described. The general methodology for the synthesis of these molecules involved the preparation of the dipeptide derivatives employing solution phase peptide synthesis followed by condensation of the dipeptide free bases with the appropriate pteroic acid analogue via diethyl cyanophosphoridate (DEPC) activation. In the final step, tert-butyl esters were removed by trifluoroacetic acid (TFA) hydrolysis. Z-L-Glu-OBut-gamma-D-Ala-OBut, for example, was prepared from alpha-tert-butyl N-(benzyloxycarbonyl)-L-glutamate and tert-butyl D-alaninate via isobutyl-mixed anhydride coupling. The Z-group was removed by catalytic hydrogenolysis and the resulting dipeptide free base condensed with 2-desamino-2-methyl-N10-propargyl-5,8-dideazapteroic acid via DEPC coupling. Finally, tert-butyl esters were removed by TFA hydrolysis to give ICI 198583-gamma-D-Ala. The compounds were tested as inhibitors of thymidylate synthase and L1210 cell growth. Good enzyme and growth inhibitory activity were found with gamma-linked L-D dipeptides, the best examples being the Glu-gamma-D-Glu derivative 35 (Ki = 0.19 nM, L1210 IC50 = 0.20 +/- 0.017 microM) and the Glu-gamma-D-alpha-aminoadipate derivative 39 (Ki = 0.12 nM, L1210 IC50 = 0.13 +/- 0.063 microM). In addition, ICI 198583 L-gamma-D-linked dipeptides were resistant to enzymatic degradation in mice.

Design and synthesis of Cyclopenta[g]quinazoline-based antifolates as inhibitors of thymidylate synthase and potential antitumor agents(,).

Following the development of raltitrexed, the synthesis of nonpolyglutamatable inhibitors of TS that do not use the reduced folate carrier (RFC) for cellular entry should provide compounds which overcome mechanisms of resistance to folate-based inhibitors of TS that are associated with decreased/altered folylpolyglutamate synthetase (FPGS) expression and/or an impaired RFC. Examination of a computer graphics model of the humanized Escherichia coli TS enzyme with quinazoline inhibitors of TS, such as 1 bound in the active site of the enzyme, suggested that conformational restriction introduced by bridging the C9 with C7 to form a pentacycle may be beneficial for binding to TS. That led to the synthesis of a series of potent cyclopenta[g]quinazoline-based inhibitors of the enzyme in which the glutamyl residue associated with classical antifolates was replaced with a variety of glutamate-derived ligands; the most potent inhibitor being the L-Glu-gamma-D-GluT(alpha) derivative 7j. In the mouse L1210:1565 cell line (mutant RFC), the majority of these compounds had activity equal or only slightly greater compared with the parental L1210 cell line, indicating a reduced dependence on the RFC for cellular uptake in the L1210 cell line.

Quinazoline antifolates thymidylate synthase inhibitors: lipophilic analogues with modification to the C2-methyl substituent.

Modification of the potent thymidylate synthase (TS) inhibitor 1-[[N-[4-[N-[(3,4-dihydro-2-methyl-4-oxo-6-quinazolinyl)methyl]-N- prop-2-ynylamino]benzoyl]amino]methyl]-3-nitrobenzene (4a) has led to the synthesis of quinazolinone antifolates bearing functionalized alkyl substituents at C2. A general synthetic route was developed which involved coupling the appropriate 1-[[N-[4-(alkylamino)benzoyl)amino]methyl]-3-nitrobenzene 20-22 with a 6-(bromomethyl)-2-(acetoxymethyl)-3,4-dihydro-4-oxoquinazoline 9 or 10. Replacement of the 2-acetoxy group by a chlorine atom followed by the displacement of the halogen of 25a-c by various nucleophiles led to compounds 26-40. Good TS (IC50 < 1 microM) and growth inhibition (IC50 0.1-1 microM) were found with most of these new antifolates. TS inhibitors in this series do not apparently require the reduced folate carrier (RFC) for cell entry (they most likely penetrate the cell membrane by passive diffusion) and are not polyglutamated. N, O, S, Cl, and CN as well as large amino and mercapto substituents were tolerated by the enzyme. The simultaneous incorporation of 7-methyl and 2'-F substituents gave a series of highly potent agents inhibiting cell growth at concentrations < 1 microM (24, 27bc; 30-32b, 35b). The incorporation of suitable C2 substituents has overcome the decrease in aqueous solubility observed with lipophilic quinazoline antifolates. This is best illustrated by compound 31a, where up to a 54-fold increase in solubility has been achieved by the incorporation of an N-methylpiperazine nucleus into the C2-methyl group of 4a.

Design and synthesis of potent non-polyglutamatable quinazoline antifolate thymidylate synthase inhibitors.

The synthesis is described of a series of analogues of the potent thymidylate synthase (TS) inhibitor, N-[4-[N-[(3,4-dihydro-2, 7-dimethyl-4-oxo-6-quinazolinyl)methyl]-N-prop-2-ynylamino]-2-f luorob enzoyl]-L-glutamic acid (4, ZM214888), in which the glutamic acid moiety is replaced by homologous amino acids and alpha-amino acids where the omega-carboxylate is replaced by acylsulfonamides and acidic heterocycles. In general these modifications when compared to 4 gave compounds with increased potency as inhibitors of isolated TS and as cytotoxic agents against murine tumor cell lines. The new compounds require transport by the reduced folate carrier for entry into cells but are not converted intracellularly into polyglutamated species. Agents with this profile are expected to show activity against tumors that are resistant to classical antifolates due to low expression of folylpolyglutamate synthetase. The analogue (S)-2-[4-[N-[(3,4-dihydro-2, 7-dimethyl-4-oxo-6-quinazolinyl)methyl]-N-prop-2-ynylamino]-2-f luorob enzamido]-4-(1H-1,2,3,4-tetrazol-5-yl)butyric acid (35, ZD9331) has been selected as a clinical development candidate and is currently undergoing phase I studies.

Folate-based inhibitors of thymidylate synthase: synthesis and antitumor activity of gamma-linked sterically hindered dipeptide analogues of 2-desamino-2-methyl-N10-propargyl-5,8-dideazafolic acid (ICI 198583).

In an effort to synthesize inhibitors of thymidylate synthase (TS) that do not undergo polyglutamation, a series of gamma-linked sterically hindered dipeptide analogues of 2-desamino-2-methyl-N10-propargyl-5,8-dideazafolic acid (ICI 198583) was prepared. A methyl, ethyl, or propargyl group was incorporated into the gamma-glutamyl amide bond of gamma-linked L,L dipeptide derivatives of ICI 198583, such as ICI 198583-gamma-L-Glu. In addition, steric bulk was introduced on either side of the gamma-glutamyl bond of ICI 198583-gamma-L-Glu or ICI 198583-gamma-L-Ala. The resulting dipeptide analogues, e.g., ICI 198583-gamma-MeGlu and ICI 198583-gamma-Aib, were apparently stable to in vivo hydrolysis but poorer inhibitors of TS and L1210 cell growth. However, introduction of 7-Me, 2'-F substitution into the quinazoline nucleus gave significant improvement in the inhibitory activity against thymidylate synthase. Compounds 28-30, the 7-Me, 2'-F derivatives of ICI 198583-gamma-MeGlu, ICI 198583-gamma-EtGlu, and ICI 198583-gamma-PgGlu, respectively, were potent inhibitors of TS (K(iapp) = 0.21-1.1 nM) and L1210 cell growth (IC50 = 0.05-0.34 microM) and were similar to that seen with the most potent gamma-linked L,D dipeptide derivatives of ICI 198583 previously synthesized. Furthermore, the low cross-resistance ratios for the L1210:R(D1694)/L1210 cell line indicated that 28-30 do not undergo polyglutamation.

Quinazoline antifolate thymidylate synthase inhibitors: replacement of glutamic acid in the C2-methyl series.

The synthesis of a series of analogues of the potent thymidylate synthase (TS) inhibitor N-[4-[N-[(3,4-dihydro-2-methyl-4-oxo-6- quinazolinyl)methyl]-N-prop-2-ynylamino]benzoyl]-L-glutamic acid (ICI 198583, 1) is described in which the glutamic acid residue has been replaced by other alpha-amino acids. Most of these analogues were prepared by coupling of tert-butyl-4-(prop-2-ynylamino)benzoate (37) with 6-(bromomethyl)-3,4-dihydro-2-methyl-4-oxoquinazoline (34) followed by deprotection of the tert-butyl ester to the acid and azide-mediated coupling to the appropriate amino acid or amino acid ester. In cases where the amino acid ester was unreactive with the acid azide, a modification was used in which the quinazolinone moiety was protected as its 3-(pivaloyloxy)methyl derivative. This permitted the generation of the more reactive acid chloride of the p-aminobenzoate unit. In general these modifications result in compounds that have equivalent potency to 1 as inhibitors of isolated TS except where the amino acid lacks a lipophilic alpha-substituent. These compounds appear to require the reduced folate carrier (RFC) for transport into cells, but since they are not converted intracellularly into polyglutamated forms, they have a lower level of cytotoxicity compared to 1. The removal of the alpha-carboxylic acid has given a second set of analogues of 1 which contain simple alkyl amide, benzyl, substituted benzyl, and heterocyclic benzyl amide derivatives. These are considerably less potent than 1 as TS inhibitors but display 1-10 microM cytotoxicities due to the fact that they do not require RFC transport and can presumably readily enter cells by passive diffusion through the cell membrane. Molecular modeling and NMR studies indicated that the incorporation of, respectively, 7-methyl and 2'-fluoro substituents would favor the optimum conformation of these molecules for interaction with the TS enzyme. Accordingly, these substituents were incorporated into selected examples to give the series of analogues 47-55. These all show enhanced (approximately 10-fold) inhibition of TS compared to their unsubstituted counterparts. In the substituted benzylamides (51, 52) and heterocyclic benzyl amides (53-55) the ability to enter cells by passive diffusion results in highly potent (< 1 microM) cytotoxic agents.

Kinetic characteristics of ICI D1694: a quinazoline antifolate which inhibits thymidylate synthase.

The thymidylate synthase (TS) inhibitor ICI D1694 (N-(5-[N-(3,4-dihydro-2-methyl-4-oxoquinazolin-6-ylmethyl)-N -methylamino]-2 - thenoyl)-S-glutamic acid) is a structural analogue of the substrate N5,N10-methylenetetrahydrofolate (5,10-CH2FH4) and is currently under clinical evaluation as a treatment for cancer. The compound is shown here to be a mixed non-competitive inhibitor of TS from murine leukemia (L1210) cells when 5,10-CH2FH4 is varied. This result suggests formation of an inactive complex between TS, 5,10-CH2FH4 and the inhibitor. Thus, binding to only one of the two active sites on the TS homodimer may be sufficient to prevent catalysis fully. Treatment of L1210 cells with ICI D1694 is known to cause intracellular accumulation of the tetraglutamate derivative which is shown here to have a 60-fold higher affinity for TS. The IC50 for inhibition of L1210 cell growth is below the Ki value of ICI D1694 for L1210 TS but above that of the tetraglutamate. The formation of polyglutamates and concentration of drug inside cells, therefore, seem to be responsible for biological activity.

Cellular pharmacokinetics of ZD1694 in cultured human leukaemia cells sensitive, or made resistant, to this drug.

We have analysed the cellular metabolism of a novel thymidylate synthase (TS) inhibitor, ZD1694, in MOLT-3 and K562 human leukaemia cell lines sensitive to or made resistant to ZD1694 by continuous exposure of the cells to ZD1694 with stepwise escalation of the drug concentration. The initial cellular uptake of [3H]ZD1694 was greater in K562 cells than in MOLT-3 cells and the drug accumulated approximately 3-fold more in the former cells following incubation with 0.1 microM ZD1694 at 37 degrees C for 24 h. TS and dihydrofolate reductase activities were not significantly different between the two cell lines. After a 30-min incubation with the drug at 37 degrees C, 85% of the total drug (2.3 pmol/mg protein) in K562 cells was found as tri- to pentaglutamates, whereas MOLT-3 cells accumulated less drug in this time (0.83 pmol/mg protein) and polyglutamates of chain length greater than triglutamate were not found to a significant extent. When the incubation time was extended to 24 h, the polyglutamate profile in K562 cells was progressively shifted towards those of long glutamate chain length and 59% of the total cellular drug (204 pmol/mg protein) was identified as the penta form. In contrast, even distribution between tri- and pentaglutamate was observed in MOLT-3 cells. Total cellular polyglutamates were approximately 3-fold higher in K562 cells than in MOLT-3 cells, and this may explain the 2.5-fold difference in the sensitivity to ZD1694 between the two cell lines. Continuous exposure of MOLT-3 and K562 cells to ZD1694 up to 1 microM or 0.1 microM resulted in 1600- and 4200-fold resistant sublines, respectively (MOLT-3/ZD1694.C and K562/ZD1694.C). The resistant MOLT-3 cells showed a markedly lower cellular accumulation and poor retention of [3H]ZD1694 with no significant change of initial drug uptake by 10 min and with a little increase of TS activity. HPLC analysis demonstrated that more than 90% of the 3H co-eluted with the monoglutamate (parent drug) in the resistant MOLT-3 cells, indicating extremely diminished polyglutamation in the cells. On the other hand, cellular uptake of [3H]ZD1694 was extensively impaired in K562/ZD1694.C cells and cellular accumulation of the drug was only 2.5% of that in the parent cells following 24 h incubation with the drug. Neither an increase of TS or dihydrofolate reductase activity nor a change in the polyglutamate formation profile was observed in the resistant K562 cells. These results indicate that the cellular ability to produce the polyglutamate metabolites of ZD1694 must influence the sensitivity of the tumour cells to this drug, and development of mechanisms involved in the ZD1694 resistance may relate to the intrinsic biochemical properties of the cells.

Thymidylate synthase inhibitors: the in vitro activity of a series of heterocyclic benzoyl ring modified 2-desamino-2-methyl-N10-substituted-5,8-dideazafolates.

Heterocyclic para-aminobenzoate modifications of 2-desamino-2-methyl-5,8-dideazafolic acid and a series of its N10-substituted analogs have produced a number of interesting compounds that have enabled a deeper understanding of the biochemical events required for activity in this class of antimetabolite. There is a relationship that has become apparent between compound potency and both uptake via the reduced-folate carrier and FPGS substrate activity. Rapid cellular uptake and metabolism of polyglutamate forms that are approximately 100-fold more potent as inhibitors of TS can translate a modest TS inhibitor such as ICI D1694 into a very potent inhibitor of cell growth (approximately 500- and approximately 10-fold more potent than CB3717 or ICI 198583, respectively). Polyglutamation may therefore act as an almost essential activation step and ICI D1694 may be highly specific for tumors expressing both the reduced-folate carrier and FPGS. Polyglutamation of folate analogs also leads to drug retention which may play a major role in the pharmacodynamics of TS inhibition by ICI D1694 in vivo. Current studies with 3H-ICI D1694 are aimed at demonstrating metabolism to polyglutamates in tumor cells. The serious toxic limitations of CB3717, i.e., liver and kidney toxicities, are not seen with ICI D1694 reflecting the good water solubility of the drug compared with CB3717. The toxicities observed in mice are however to hematological tissues and are due to its TS inhibitory effects. Thus ICI D1694 may elicit toxicities in man more typical of an antimetabolite than of CB3717. The clinical evaluation of ICI D1694 may further our understanding of the role that metabolism to polyglutamates may have in therapeutic activity.

The role of the reduced-folate carrier and metabolism to intracellular polyglutamates for the activity of ICI D1694.

The uptake of ICI D1694 into L1210 cells is very rapid and evidence strongly suggests that transport is via the reduced-folate/MTX cell membrane carrier (RFC); for example a cell line with a greatly impaired RFC is highly resistant to ICI D1694. Polyglutamates can be found intracellularly within a few minutes, so that experiments initially designed to measure transport were actually measuring transport and polyglutamation. After 30mins, in normal serum-containing tissue culture medium, the concentration of polyglutamates (di, tri and tetra) exceeded that of the parent drug 6-fold. Studies where cells were resuspended in drug-free medium demonstrated that the parent drug and its diglutamate could readily leave the cell. Folinic acid could markedly decrease the polyglutamation of ICI D1694, but had to be given simultaneously with the drug as a 4hr delayed rescue was less effective because substantial polyglutamation had already occurred. This effect was translated into considerable antagonism for cell growth inhibition by simultaneous folinic acid. The importance of the metabolism of ICI D1694 to polyglutamates to its potent cytotoxic activity is demonstrated by compounds related in structure to ICI D1694 but with different properties for the RFC and FPGS. For example, 2-desamino-2-methyl-N10-propargyl-5,8-dideazafolate (ICI 198583) owes its less potent cytotoxic activity to its poorer FPGS substrate activity (Km 40 microM compared with 1.3 microM for ICI D1694). Replacing the 2-methyl of either compound with amino, which appears to prevent use of the RFC, has a deleterious effect on growth inhibitory activity presumably by limiting the transport of the parent compounds into the cells, thereby slowing the rate of polyglutamate formation. Again a single change to another part of the molecule, that is methylation of the 7-position can have serious consequences on cytotoxic potency, particularly for the ICI D1694 molecule. The 7-methylated compounds are apparently poor or non-substrates for FPGS and therefore retain activity against a cell line unable to polyglutamate antifolates. These same compounds are only slightly affected by coincubation with folinic acid in L1210 tissue culture, consistent with the failure of these compounds to form intracellular polyglutamates. The results of short-exposure assays and in situ TS assays confirms that 7-methylation largely prevents the formation of a retained drug-form (polyglutamates), continuous exposure being necessary to maintain TS inhibition and cause a cytotoxic effect after removal of extracellular drug.(ABSTRACT TRUNCATED AT 400 WORDS)

Gamma-linked dipeptide analogues of 2-desamino-2-methyl-N10-propargyl-5,8- dideazafolate as antitumour agents.

Our search for water-soluble quinazoline TS inhibitors that are transported into cells via the RFC, but are not substrates for FPGS, led us to the synthesis of dipeptide analogues of ICI 198583 diglutamate. Although a number of dipeptide analogues were active against isolated TS and L1210 cells in vitro, lack of in vivo stability was a problem. This was circumvented by the synthesis of modified dipeptides where either the alpha-carboxyl of the second amino acid was removed (alpha'-COOH) e.g. -L-glu-GABA or where the second amino acid was the unnatural D-enantiomer e.g.-L-glu-D-glu. Further studies were performed with the -L-glu-D-glu and its 7-CH3, 2'F modified analogue, demonstrating that they use the RFC for cell entry but are not active through polyglutamate formation. The latter compound was tested against experimental tumour models and found to have good activity.