Antagonism of oestrogen action in human breast and endometrial cells in vitro: potential novel antitumour agents.

PURPOSE: There is a need to find novel oestrogen receptor (ER) ligands that antagonize oestrogen action in the reproductive tissues and would therefore have therapeutic potential in oestrogen-dependent tumours. We tested novel ER ligands in both breast and endometrial cells to profile agonism/antagonism in these oestrogen target reproductive tissues. METHODS: Novel analogues of the ER antagonist ICI 182,780 were synthesized and tested for their ability to inhibit gene expression dependent on oestrogen response elements (ERE) in human breast (MCF-7) and endometrial (Ishikawa) cell lines. This activity was correlated with inhibition of oestrogen-induced cell proliferation and ER binding. RESULTS: The sulphide analogue (compound 1) and sulphone analogue (compound 2) had no intrinsic ERE-dependent agonism in either breast cancer or endometrial cells in culture. All three compounds dose-dependently inhibited ERE-mediated oestrogen agonism. Moreover, these ER ligands inhibited oestrogen-stimulated proliferation of breast cancer and endometrial cells. ICI 182,780, compound 1 and compound 2 were all able to bind both isoforms of the ER (ER alpha and ER beta). In endometrial cells, the relative binding to ER beta correlated with the ERE-dependent antioestrogenic effect of these ligands, suggesting that in this tissue this receptor is the predominant isoform that determines antioestrogenic activity. CONCLUSIONS: The ability of these analogues of ICI 182,780 to inhibit oestrogen-stimulated transcriptional activity and cell proliferation suggests that these agents, in particular the sulphone analogue, have therapeutic potential in the treatment of breast cancer without exhibiting the unwanted oestrogenic effects in the endometrium.

In vitro and in vivo pharmacological characterization of SB 201993, an eicosanoid-like LTB4 receptor antagonist with anti-inflammatory activity.

Leukotriene B4 (LTB4) and 12-(R)-hydroxy-5,8,10,14-eicosatetraenoic acid (12-[R]-HETE) have been postulated to contribute to the pathophysiology of inflammatory diseases. SB 201993, (E)-3-[[[[6-(2-carboxyethenyl)-5-[[8-(4-methoxyphenyl)octyl] oxy]-2-pyridinyl] methyl] thio] methyl] benzoic acid, identified from a chemical series designed as ring-fused analogs of LTB4, was evaluated as an antagonist of LTB4- and 12-(R)-HETE-induced responses in vitro and for anti-inflammatory activity in vivo. SB 201993 competitively antagonized [3-H]-LTB4 binding to intact human neutrophils (Ki = 7.6 nM) and to membranes of RBL 2H3 cells expressing the LTB4 receptor (RBL 2H3-LTB4R; IC50 = 154 nM). This compound demonstrated competitive antagonism of LTB4- and 12-(R)-HETE-induced Ca2+ mobilization responses in human neutrophils (IC50s of 131 nM and 105 nM, respectively) and inhibited LTB4-induced Ca2+ mobilization in human cultured keratinocytes (IC50 = 61 nM), RBL 2H3-LTB4R cells (IC50 = 255 nM) and mouse neutrophils (IC50 = 410 nM). SB 201993 showed weak LTD4-receptor binding affinity (Ki = 1.9 microM) and inhibited 5-lipoxygenase (IC50 of 3.6 microM), both in vitro and ex vivo. In vivo, SB 201993 inhibited LTB4-induced neutrophil infiltration in mouse skin and produced dose-related, long lasting topical anti-inflammatory activity against the fluid and cellular phases of arachidonic acid-induced mouse ear inflammation (ED50 of 580 microg/ear and 390 microg/ear, respectively). Similarly, anti-inflammatory activity was also observed in the murine phorbol ester-induced cutaneous inflammation model (ED50 of 770 and 730 microg/ear, respectively, against the fluid and cellular phases). These results indicate that SB 201993 blocks the actions of LTB4 and 12-(R)-HETE and inhibits a variety of inflammatory responses; and thus may be a useful compound to evaluate the role of these mediators in disease models.

Effects of camptothecin analogues on DNA transformations mediated by calf thymus and human DNA topoisomerases I.

Camptothecin (CPT) and 10 structural analogues were studied to characterize their effects on specific rearrangements of DNA structure mediated by human and calf thymus DNA topoisomerases I. A 30 base pair DNA duplex containing a single high-efficiency topoisomerase cleavage site was incubated with each of the enzymes in the presence of the inhibitors. Individual inhibitors stabilized the covalent enzyme-DNA binary complex to different extents, as anticipated. However, for several of the inhibitors, the extent of ternary complex formation differed substantially for the human and calf thymus enzymes. In common with calf thymus topoisomerase I, the human enzyme was shown to mediate the rearrangement of branched, nicked, and gapped DNA substrates that constitute models for illegitimate recombination. However, some of these rearrangements proceeded with different rates and efficiencies in the presence of human topoisomerase I. When inhibition of three of the rearrangements by CPT analogues was studied, most of the analogues exhibited differential effects on a given transformation, depending on the source of the enzyme employed.

Differential effects of camptothecin derivatives on topoisomerase I-mediated DNA structure modification.

The effects of eleven camptothecin derivatives on calf thymus topoisomerase I-mediated cleavage of synthetic DNA duplex have revealed that the A ring of camptothecin is very important for its biochemical activity. Depending on the type, number, and location of substituents, highly active or inactive analogues were obtained. The persistence of CPT-induced topoisomerase I-DNA covalent binary complexes was investigated by using as substrates DNA containing several good topoisomerase I cleavage sites, or else a synthetic DNA duplex of defined structure with a single high-efficiency cleavage site. The ligation kinetics at a given topoisomerase I cleavage site were sometimes quite different in the presence of CPT derivatives whose structures were closely related. Even in the presence of a single CPT analogue, topoisomerase I-DNA covalent binary complexes underwent ligation with different kinetics, presumably reflecting a dependence on DNA sequences flanking the individual topoisomerase I cleavage sites. Individual camptothecin derivatives also exhibited a spectrum of inhibitory potentials in blocking the topoisomerase I-mediated rearrangement of branched, nicked, and gapped DNA duplex substrates; in some cases the potencies of inhibition observed in these assays for individual camptothecin analogues were quite different than those determined for stabilization of the unmodified DNA-topoisomerase I binary complex.

(E)-3-[6-[[(2,6-dichlorophenyl)thio]methyl]-3-(2-phenylethoxy)-2- pyridinyl]-2-propenoic acid: a high-affinity leukotriene B4 receptor antagonist with oral antiinflammatory activity.

An extensive structure-activity study based around the high-affinity leukotriene B4 (LTB4) receptor antagonist SB 201146 (1) led to the identification of (E)-3-[6-[[(2,6-dichlorophenyl)-thio]methyl]-3-(2-phenylethoxy)-2- pyridinyl]-2-propenoic acid (3). This compound displays high affinity for the human neutrophil LTB4 receptor (Ki = 0.78 nM), blocks LTB4-induced Ca2+ mobilization with an IC50 of 6.6 +/- 1.5 nM, and demonstrates potent oral and topical antiinflammatory activity in a murine model of dermal inflammation.

(E)-3-[[[[6-(2-carboxyethenyl)-5-[[8-(4- methoxyphenyl)octyl]oxy]-2-pyridinyl]-methyl]thio]methyl]benzoic acid and related compounds: high affinity leukotriene B4 receptor antagonists.

(E)-3-[[[[6-(2-Carboxyethenyl)-5-[[8-(4- methoxyphenyl)octyl]oxy]-2-pyridinyl]methyl]thio]methyl]benzoic acid (11, SB 201993) is a novel, potent LTB4 receptor antagonist. Compound 11 arose from a structure-activity study of a series of trisubstituted pyridines that demonstrated LTB4 receptor antagonist activity. The placement of an additional methylene unit in the sulfur containing chain linking the pyridine and benzoic acid moieties of lead compound 8 (K(i) = 80 nM) resulted in a greater than 10-fold increase in receptor affinity. Additionally, in this new series of compounds, the oxidation state of the sulfur was found to be critical to the activity, i.e., the sulfoxide and sulfone showed substantially lower affinity for the LTB4 receptor. Compound 11 competitively inhibits the binding of [3H]LTB4 to LTB4 receptors on human polymorphonuclear leukocytes with a Ki of 7.1 nM and blocks both the LTB4-induced calcium mobilization and the LTB4-induced degranulation responses in these cells with IC50 values of 131 and 271 nM, respectively. Compound 11 demonstrated oral LTB4 antagonist activity as well as topical antiinflammatory activity in the mouse.

Synthesis of structural analogs of leukotriene B4 and their receptor binding activity.

Structural analogs of leukotriene B4 (LTB4) were designed using a preferred conformation of LTB4 (1). Appending an aromatic ring scaffold between LTB4 carbons 7 and 11 led to quinoline analogs 3 and 15. A similar modification to the LTB4 structure between carbons 7 and 9 led to the pyridine analogs 41 and 46. The compounds of this study were evaluated in receptor binding assays using [3H]LTB4 and intact human DMSO differentiated U-937 cells. The first analog prepared, quinoline 3, displayed moderate potency in the LTB4 receptor binding assay (Ki = 0.9 microM). Modification of 3 by appending an aromatic ring between carbons 2 and 4 of the acid side chain produced a dramatic increase in receptor binding (15, Ki = 0.01 microM); a further improvement in receptor binding was achieved in the pyridine series (e.g., 41; Ki = 0.001 microM). The LTB4 receptor agonist/antagonist activity of the test compounds was determined using a functional assay that relies upon intracellular calcium mobilization induced by LTB4. Of the analogs prepared in this report only 47 demonstrated LTB4 receptor antagonist activity.

Trisubstituted pyridine leukotriene B4 receptor antagonists: synthesis and structure-activity relationships.

A series of trisubstituted pyridines have been prepared that exhibit in vitro leukotriene B4 (LTB4, 1) receptor antagonist activity. Previous disubstituted pyridines from these labs showed high affinity for the LTB4 receptor but demonstrated agonist activity in functional assays (e.g., 2, Ki = 1 nM). Compound 4, the initial lead compound of this new series, showed only modest affinity by comparison (Ki = 282 nM); however, 4 was a receptor antagonist with no demonstrable agonist activity up to 10 microM. Subsequent modifications of the lipid tail and aryl head group region led to the discovery of aniline 50 (SB 201146). This compound, also free of agonist activity, possesses high affinity for the LTB4 receptor (Ki = 4.7 nM).

Synthesis and LTB4 receptor antagonist activities of the naturally occurring LTB4 receptor antagonist Leucettamine A and related analogues.

The isolation and structure determination of the naturally occurring LTB4 receptor antagonist Leucettamine A (1) was recently reported. Herein we describe the synthesis of this natural product, the preparation of several analogues, and their effectiveness as antagonists of [3H]LTB4 binding to intact human U-937 cells. Total synthesis of Leucettamine A (1) is achieved by a convergent route which takes advantage of the elements of symmetry within the molecule. Syntheses of analogues of 1, which lacked the same degree of symmetry, are achieved by a different approach starting from alpha-amino acids. The natural product 1 inhibits [3H]LTB4 binding to its receptors on intact human U-937 cells with a Ki = 3.5 +/- 0.8 microM and is devoid of measurable agonist activity at the concentrations tested. 2-Amino imidazole analogues of 1 lacking the dioxolane groups were prepared. Generally these are significantly less potent than 1. However, one (26), designed on the basis of a putative structural overlay with LTB4, demonstrated potency comparable to that of the natural product (Ki = 2.4 +/- 0.2 microM).

Synthesis of water-soluble (aminoalkyl)camptothecin analogues: inhibition of topoisomerase I and antitumor activity.

Water-soluble analogues of the antitumor alkaloid camptothecin (1) were prepared in which aminoalkyl groups were introduced into ring A or B. Most of the analogues were prepared by oxidation of camptothecin to 10-hydroxycamptothecin (2) followed by a Mannich reaction to give N-substituted 9-(aminomethyl)-10-hydroxycamptothecins (4-12) or by subsequent modification of Mannich product 4 (13, 15, 17, 19, 21). Others were obtained by modification of the hydroxyl group of 2 (25,26) or by total synthesis (35,42,43). These analogues, as well as some of their synthetic precursors, were evaluated for inhibition of topoisomerase I, cytotoxicity, and antitumor activity. Although there was not a quantitative correlation between these assays, compounds that inhibited topoisomerase I were also cytotoxic and demonstrated antitumor activity in vivo. Further evaluation of the most active water-soluble analogue led to the selection of 9-[(dimethylamino)methyl]-10-hydroxycamptothecin (4, SK&F 104864) for development as an antitumor agent. In addition to its water solubility, ease of synthesis from natural camptothecin, and high potency, 4 demonstrated broad-spectrum activity in preclinical tumor models and is currently undergoing Phase I clinical trials in cancer patients.

Irreversible trapping of the DNA-topoisomerase I covalent complex. Affinity labeling of the camptothecin binding site.

Camptothecin (CPT) binds reversibly to, and thereby stabilizes, the cleavable complex formed between DNA and topoisomerase I. The nature of the interaction of CPT with the DNA-topoisomerase I binary complex was studied by the use of two affinity labeling reagents structurally related to camptothecin: 10-bromoacetamidomethylcamptothecin (BrCPT) and 7-methyl-10-bromoacetamidomethylcamptothecin (BrCPTMe). These compounds have been shown to trap the DNA-topoisomerase I complex irreversibly. Although cleavage of DNA plasmid mediated by topoisomerase I and camptothecin was reduced significantly by treatment with high salt or excess competitor DNA, enzyme-mediated DNA cleavage stabilized by BrCTPMe persisted for at least 4 h after similar treatment. The production of irreversible topoisomerase I-DNA cleavage was time-dependent, suggesting that BrCPTMe first bound noncovalently to the enzyme-DNA complex and, in a second slower step, alkylated the enzyme or DNA in a manner that prevented DNA ligation. The formation of a covalent linkage was supported by experiments that employed [3H]BrCPT, which was shown to label topoisomerase I within the enzyme-DNA complex. [3H]BrCPT labeling of topoisomerase I was enhanced greatly by the presence of DNA; very little labeling of isolated topoisomerase I or isolated DNA occurred. Even in the presence of DNA, [3H]BrCPT labeling of topoisomerase I was inhibited by camptothecin, suggesting that both CPT and BrCPT bound to the same site on the DNA-topoisomerase I binary complex. These studies provide further evidence that a binding site for camptothecin is created as the DNA-topoisomerase I complex is formed and suggest that the A-ring of camptothecin is proximate to an enzyme residue.

Modification of the hydroxy lactone ring of camptothecin: inhibition of mammalian topoisomerase I and biological activity.

Several camptothecin derivatives containing a modified hydroxy lactone ring have been synthesized and evaluated for inhibition of topoisomerase I and cytotoxicity to mammalian cells. Each of the groups of the hydroxy lactone moiety, the carbonyl oxygen, the ring lactone oxygen, and the 20-hydroxy group, were shown to be critical for enzyme inhibition. For example the lactol, lactam, thiolactone, and 20-deoxy derivatives did not stabilize the covalent DNA-topoisomerase I complex. With a few exceptions, those compounds that did not inhibit topoisomerase I were not cytotoxic to mammalian cells. Two cytotoxic derivatives that did not inhibit topoisomerase I were shown to produce non-protein-associated DNA single-strand breaks and are likely to have a different mechanism of action. One of these compounds was tested for antitumor activity and was found to be inactive. The present findings, as well as other reports that the hydroxy lactone ring of camptothecin is critical for antitumor activity in vivo, correlate with the structure-activity relationships at the level of topoisomerase I and support the hypothesis that antitumor activity is related to inhibition of this target enzyme.

Determination of carboxypeptidase A using N-acetyl-phenylalanyl-3-thiaphenylalanine as substrate: application to a direct serum assay.

N-Acetyl-L-phenylalanyl-L-3-thiaphenylalanine has been shown to be a substrate for carboxypeptidase A. Hydrolysis of the compound obeys Michaelis-Menten kinetics with a KM of 0.22 mM and a kcat of 6720 min-1 at 22 degrees C. A colorimetric assay, employing Ellman's reagent to detect the thiophenol released upon cleavage of the peptide, has been developed. The assay can be used for the direct determination of carboxypeptidase A in serum.

Synthesis of alpha-thiophenylglycine peptides. Novel peptide substrates useful in the study of microbial peptide transport.

The synthesis of peptides useful for the investigation of microbial peptide transport is reported. These peptides, L-alanyl-L-2-thiophenylglycine (Ala-alpha-TPG), L-alanyl-L-2-thiophenylglycyl-L-alanine (Ala-alpha-TPG-Ala) and L-alanyl-L-alanyl-L-2-thiophenylglycine (Ala-Ala-alpha-TPG), contain a phenylthio group attached to the alpha carbon of glycine.

Determination of leucine aminopeptidase using phenylalanyl-3-thia-phenylalanine as substrate.

The peptide mimetic L-phenylalanyl-L-3-thiaphenylalanine has been shown to facilitate a sensitive and simple determination of leucine aminopeptidase. A colorimetric assay, employing Ellman's reagent to detect the thiophenol released upon hydrolysis of the dipeptide, has been developed. Under the experimental conditions employed the substrate has a Km of 0.054 mM and a kcat of 5800 min-1 and can distinguish sharply between leucine aminopeptidase and aminopeptidase M.

Relative rates of transport of peptidyl drugs by Candida albicans.

A variety of peptide drugs are known to be active against Candida albicans; however, little is known about the transport of such agents into the target organism. To provide further information concerning transport of this type, we studied the uptake of two classes of small linear peptides: polyoxins which act intact within the cell and the m-fluorophenylalanyl (m-F-Phe) peptides which require peptidase cleavage to release m-F-Phe. Competition studies with a specific dipeptide detector (alanyl-alpha-thiophenylglycine) enabled us to determine Ki values of 2.6 microM for nikkomycin Z and 350 microM for polyoxin D. Rates of uptake of the peptidyl-nucleosides are approximately 30 times lower than those of the m-F-Phe peptides (apparent maximal velocities: nikkomycin Z, 62 pmol min-1 mg (dry weight) of cells-1; M-F-Phe alanine 1.3 nmol min-1 mg (dry weight) of cells-1). For both the m-F-Phe peptides and the peptidyl-nucleosides, the affinity of the drug for the transport system is an important determinant of its whole-cell activity.

Multiplicity of peptide permeases in Candida albicans: evidence from novel chromophoric peptides.

Evidence is presented for the presence of multiple peptide permeases in the eucaryotic organism Candida albicans. Instrumental in these studies were the peptides L-alanyl-L-2-thiophenylglycine (Ala-alpha-TPG) and L-alanyl-L-2-thiophenylglycyl-L-alanine (Ala-alpha-TPG-Ala), which contain thiophenol attached to the alpha-carbon of glycine. Subsequent to transport into the fungal cell, enzymatic hydrolysis of these peptides resulted in the release of free thiophenol, which was quantified by using Ellman reagent. Thiophenol release was shown to be directly correlated to peptide transport and hydrolysis, with transport being the rate-limiting step in intact cells. These peptides, whose uptake showed Michaelis-Menten kinetics, have been used to determine peptide uptake in C. albicans. In addition, we found that the intracellular peptidases can readily be assayed in permeabilized cells and that bestatin, an aminopeptidase inhibitor, inhibits all detectable peptidase activity. C. albicans 124 was able to transport and hydrolyze both Ala-alpha-TPG and Ala-alpha-TPG-Ala, whereas the mutant (124NIK5) was able to transport only the tripeptide. The intracellular peptidases of this mutant were unaffected. In wild-type C. albicans 124, oligopeptides were able to compete with uptake of Ala-alpha-TPG-Ala to a far greater extent than with that of Ala-alpha-TPG; dipeptides inhibited uptake of both Ala-alpha-TPG and Ala-alpha-TPG-Ala. These results provide complementary evidence for the existence of distinct transport systems.

A novel peptide delivery system involving peptidase activated prodrugs as antimicrobial agents. Synthesis and biological activity of peptidyl derivatives of 5-fluorouracil.

As an approach to the development of antimicrobial agents, a novel peptide carrier system was designed, based on the chemical instability of alpha-substituted glycine analogues, with the explicit intent of actively transporting therapeutically useful compounds into microbial cells. Peptides containing 5-fluorouracil (5-FU) linked to the peptide backbone were selected to test the feasibility of this new delivery system. These peptide conjugates were designed such that they would be substrates for both the microbial peptide permeases and peptidases. After entry into cells, enzymatic hydrolysis of the peptide generates an unstable alpha-(5-FU)-glycine that spontaneously decomposes to release 5-FU. The 5-FU-peptide conjugates were tested for antifungal (Candida albicans) and antibacterial (Escherichia coli) activity and were found to have antimicrobial activities comparable to free 5-FU. Noninhibitory peptides antagonized the antimicrobial activities of the 5-FU-peptide conjugates but not of free 5-FU, a result consistent with peptide transport mediated entry of the peptide conjugates into cells. Further support for this conclusion was provided by the finding that biological activities were dependent upon peptide stereochemistry.

Portage of various compounds into bacteria by attachment to glycine residues in peptides.

Synthetic di- and oligopeptides are described that contain nucleophilic moieties attached to the alpha carbon of a glycine residue. These peptides are accepted by the peptide transport systems of Escherichia coli (and other microorganisms) and are capable of being hydrolyzed by intracellular peptidases. After liberation of its amino group the alpha-substituted glycine is chemically unstable (although it is stable in peptide form) and decomposes, releasing the nucleophilic moiety. Thus, the combined result of peptide transport and peptidase action is the intracellular release of the nucleophile. Peptides containing glycine residues alpha-substituted with thiophenol, aniline, or phenol are used as models for this type of peptide-assisted entry and their metabolism by E. coli is described. Peptides of this type have broad applicability to the study of microbial physiology and the development of an additional class of antimicrobial agents.