Pseudoguaianolides from the flowers of Parthenium hysterophorus.

Chemical investigation on the flowers of Parthenium hysterophorus has resulted in the isolation of four new pseudoguaianolides, hysterones A-D along with the known compounds, parthenin, coronopilin, 2beta-hydroxycoronopilin and tetraneurin-A. The structures of the new compounds were established by interpretation of their spectral (1D and 2D NMR) data. The X-ray crystallographic analysis of hysterones A and C was also carried out.

Structure-activity studies of antitumor agent irofulven (hydroxymethylacylfulvene) and analogues.

Many analogues of the antitumor agent irofulven have been readily prepared by replacing the allylic hydroxyl with a variety of nucleophiles. Analogues of acylfulvene (the precursor to irofulven) were also prepared by Michael reaction with acrolein. The toxicity of the analogues was determined, as well as preclinical antitumor activity. Several analogues exhibited good activity in mouse xenografts. Structural requirements for activity are discussed.

Sesquiterpenes from the basidiomycete Omphalotus illudens.

A new sesquiterpene, omphadiol (4), has been isolated from cultures of Omphalotus illudens. Several known compounds, including illudosin (1), were also obtained. Structures were determined using MS, NMR, and X-ray techniques.

Preparation and biological activity of amino acid and peptide conjugates of antitumor hydroxymethylacylfulvene.

The primary hydroxyl group in hydroxymethylacylfulvene, a potent antitumor drug, is readily replaced by thiols including cysteine, N-acetylcysteine, homocysteine, and glutathione. Best yields are obtained when reaction is carried out in the presence of dilute sulfuric acid. A variety of sulfur-containing analogues have been prepared, and their toxicity to tumor cells was examined.

Efficacy of MGI 114 (HMAF) against the MRP+ metastatic MV522 lung carcinoma xenograft.

This study is part of an effort to evaluate efficacy of the novel agent MGI 114 (HMAF) against tumors resistant to conventional chemotherapeutic agents. MGI 114 is a novel semisynthetic anticancer agent currently in chemotherapeutic phase II trials to evaluate activity against various solid tumors. Previous studies indicate MGI 114 was active against human MDR1/gp170+ solid tumor xenografts. Recent evidence suggests overexpression of the MRP protein may also be clinically relevant to development of drug resistance in solid tumors. We evaluated the efficacy of MGI 114 against a human MRP+ lung carcinoma xenograft. Parent MV522 lung carcinoma cells were transfected with a MRP cDNA expression vector and resistant cells selected by exposure to vinblastine (30-fold resistance). Analysis of resistant clones indicated 20- to 40-fold increases in expression of both MRP mRNA and MRP protein. Administration of MGI 114 at the maximum tolerated dose (7 mg/kg, 5 x/week for 3 weeks) to MRP tumor-bearing mice demonstrated this novel agent was active against MRP+ tumors and significantly extended their lifespan (p<0.001). In contrast, other cytotoxic agents had minimal activity against this MRP+ xenograft. These results indicate MGI 114 should retain activity in vivo against MRP+ tumor types. The development of this MRP+ xenograft model, in conjunction with the parent MV522 and MDR1/gp170+ xenograft models, will be useful for screening new classes of agents for activity against multidrug-resistant tumors.

Anti-leukemic action of the novel agent MGI 114 (HMAF) and synergistic action with topotecan.

The illudin derivative MGI 114 (6-hydroxymethylacylfulvene or HMAF) is currently in phase II chemotherapeutic clinical trials for a variety of solid tumors. The illudins were originally thought to be potentially useful agents for myeloid leukemias, because hematopoietic tumor cells were markedly sensitive whereas normal bone marrow progenitors were relatively resistant to the cytotoxic effects of illudins. Due to the marked preclinical efficacy of MGI 114 against a variety of solid tumor xenografts, the current phase II human trials are restricted to solid tumor (breast, lung, colon, ovarian, pancreas, prostate, etc) malignancies. The present studies were undertaken to evaluate the efficacy of MGI 114 in the HL60/MRI myeloid leukemia xenograft. In addition, because of the reported synergistic cytotoxic activity between MGI 114 and the topoisomerase I inhibitor topotecan towards pediatric human tumor cell lines, we tested the activity of MGI 114 and topotecan combinations against HL60 cells in vitro and the HL60/MRI myelocytic xenograft. Our results indicate that MGI 114 at maximum tolerated doses (MTD) of 7 mg/kg, five times per week for 3 weeks does display anti-myeloid leukemic properties in the HL60/MRI xenograft model which exceeds activity noted with other conventional agents (TGI > 70%). A marked therapeutic synergistic action was observed with MGI 114 and topotecan combinations of (1/2) MTD of each agent producing complete tumor remission in 50% of animals, without development of excessive or additive toxicity in animals. These results support further in vitro and clinical investigation into both the anti-myeloid leukemic activity of MGI-114, and the cooperative pharmacologic interaction noted between MGI-114 and topoisomerase I inhibitors. Leukemia (2000) 14, 136-141.

Characterization of MGI 114 (HMAF) histiospecific toxicity in human tumor cell lines.

PURPOSE: The acylfulvenes are a class of antitumor agents derived from the fungal toxin illudin S. One acylfulvene derivative, MGI 114 (HMAF), demonstrates marked efficacy in xenograft carcinoma models when compared to the parent acylfulvene or related illudin compounds. The maximum tolerated dose (MTD) of the two analogs in animals, however, is similar. To help elucidate the basis of the increased therapeutic efficacy of MGI 114, we determined the in vitro cytotoxicity, cellular accumulation and DNA incorporation of this drug and compared the results with those from the parent acylfulvene analog. METHODS: The cytotoxicity of acylfulvene analogs was tested in vitro against a variety of tumor cell lines. Radiolabeled MGI 114 was used for cellular accumulation and DNA incorporation studies. RESULTS: MGI 114 retained relative histiospecific toxicity towards myeloid leukemia and various carcinoma cell lines previously noted with the parent acylfulvene compound. Markedly fewer intracellular molecules of MGI 114 were required to kill human tumor cells in vitro as compared to the parent acylfulvene, indicating that MGI 114 was markedly more toxic on a cellular level. At equitoxic concentrations, however, the incorporation of MGI 114 into genomic tumor cell DNA was equivalent to that of acylfulvene. Analysis of cellular accumulation of MGI 114 into tumor cells revealed a lower Vmax for tumor cells, and a markedly lower Vd for diffusion accumulation as compared to acylfulvene. CONCLUSIONS: The addition of a single methylhydroxyl group to acylfulvene to produce MGI 114 results in a marked increase in cytotoxicity in vitro towards tumor cells as demonstrated by the reduction in IC50 values. There was a corresponding decrease in the number of intracellular molecules of MGI 114 required to kill tumor cells, but no quantitative alteration in covalent binding of the drugs to DNA at equitoxic concentrations. This indicates that cellular metabolism plays a role in the in vitro cytotoxicity of MGI 114. The equivalent incorporation into genomic DNA at equitoxic doses suggests that DNA damage produced by acylfulvene and MGI 114 is equivalent in regard to cellular toxicity and ability to repair DNA. This increased cellular toxicity, together with the decrease in diffusion rate, may explain the increased therapeutic efficacy of MGI 114 as compared to the parent acylfulvene analog.

Metabolism of antitumor hydroxymethylacylfulvene by rat liver cytosol.

Acylfulvenes are a potent class of antitumor agents derived from illudin S, a fungal sesquiterpene. Illudin S possesses antitumor activity but has a poor therapeutic index. Acylfulvene is 100-fold less toxic against human lung adenocarcinoma cells than illudin S, but inhibits tumor growth in human xenografts, opposite to illudin S. An analog of acylfulvene, MGI 114 (hydroxymethylacylfulvene), shows much greater efficacy, producing complete tumor regression in xenograft models. MGI 114 is currently in phase II clinical trials. Cytotoxicity of MGI 114, like that of illudin S, is believed to involve both chemical reaction and enzymatic reduction. Enzymatic reduction by a cytosolic NADPH-dependent enzyme (from rat liver) produced an aromatic metabolite similar to that formed from illudin S. However, the reaction occurred more slowly. In addition, four new metabolites were isolated, two hydroxylated derivatives and two in which the primary allylic hydroxyl was replaced by hydride. All retained the reactive centers of the parent MGI 114.

Discovery and development of sesquiterpenoid derived hydroxymethylacylfulvene: a new anticancer drug.

Hydroxymethylacylfulvene (HMAF, MGI 114) is derived from the sesquiterpene illudin S by treatment with dilute sulfuric acid and excess paraformaldehyde. It is less cytotoxic than illudin S but exhibits much greater selectivity in toxicity to malignant cells compared to normal cells. HMAF is believed to undergo bioreductive activation in vivo. It is now being tested in human clinical phase II trials against solid tumors.

Metabolism of antitumor acylfulvene by rat liver cytosol.

Illudins are novel compounds from which a potent class of antitumor agents, called acylfulvenes, have been synthesized. The model illudin, illudin S, has marked in vitro and in vivo toxicity but displays a poor therapeutic index. The toxicity of illudin S is believed to involve a combination of enzymatic reduction and chemical reaction. Enzymatic reduction by a cytosolic NADPH-dependent enzyme produces an aromatic metabolite, as does reaction with thiols. Acylfulvene is formed from illudin S by reverse Prins reaction. Acylfulvene is 100-fold less toxic in vitro and in vivo than illudin S but possesses marked antitumor efficacy in vivo, thus displaying opposite properties from illudin S. For this reason we investigated the in vitro metabolism of acylfulvene. Incubation of acylfulvene with NADPH and rat liver cytosol yielded two metabolites. One metabolite, the aromatic product, is similar to that obtained with illudin S in this in vitro system and was anticipated. The other metabolite, the hydroxylated product, was not expected and no corresponding metabolite for illudin S could be detected. The production of this hydroxylated metabolite from acylfulvene may explain, in part, the increased antitumor activity of novel acylfulvenes as compared with the illudins.

Efficacy of MGI 114 (6-hydroxymethylacylfulvene, HMAF) against the mdr1/gp170 metastatic MV522 lung carcinoma xenograft.

Illudins are a novel class of agents with a chemical structure entirely different from current chemotherapeutic agents. A new semisynthetic derivative, MGI 114 (NSC 683,863, 6-hydroxymethyl-acylfulvene, HMAF), is markedly effective in a variety of lung, breast and colon carcinoma xenograft models. This analogue, MGI 114, is currently in phase I human clinical trials, and is scheduled for two different phase II trials. To determine if MGI 114 could be effective in vivo against mdr tumour cells, we generated an mdr1/gp170-positive clone of the metastatic MV522 human lung carcinoma line by transfecting a eukaryotic expression vector containing the cDNA encoding for the human gp170 protein. This MV522/mdr1 daughter line retained the metastatic ability of parental cells. The parental MV522 xenograft is mildly responsive in vivo to mitomycin C and paclitaxel, as evidenced by partial tumour growth inhibition and a small increase in life span, whereas MV522/mdr1 xenografts were resistant to these agents. In contrast to mitomycin C and paclitaxel, MGI 114 produced xenograft tumour regressions in 32 of 32 animals and completely eliminated tumours in more than 30% of MV522/mdr1 tumour-bearing mice. Thus, MGI 114 should be effective in vivo against mdr1/gp170-positive tumours.

Characterization of acylfulvene histiospecific toxicity in human tumor cell lines.

PURPOSE: Acylfulvene derivatives demonstrate marked efficacy in xenograft carcinoma models as compared with the parent illudin compounds. To elucidate the increased therapeutic efficacy of acylfulvene analogs, we compared them with the illudin compounds in terms of their in vitro cytotoxicity, cellular accumulation and DNA incorporation. METHODS: The cytotoxicity of various acylfulvene analogs was tested in vitro against a variety of tumor cell lines. Radiolabelled acylfulvene analog was prepared and used for cellular accumulation and DNA incorporation studies. RESULTS: The prototype acylfulvene analog retained selective histiospecific toxicity towards myeloid leukemia and various carcinoma cell lines. In vitro killing of tumor cells by acylfulvene required up to a 30-fold increase in molecules per cell, as compared with illudin S, indicating that acylfulvene was less toxic on a cellular level. At equitoxic concentrations, acylfulvene incorporation into genomic tumor cell DNA was equivalent to illudin S suggesting that cellular metabolism has a role in acylfulvene cytotoxicity. Analysis of cellular accumulation of acylfulvene into tumor cells revealed a markedly higher Vmax for tumor cells, and a lower Vd for diffusion accumulation into other cells. CONCLUSIONS: The combination of higher Vmax and lower Vd may explain the increased in vivo efficacy of acylfulvene.

Preclinical antitumor activity of 6-hydroxymethylacylfulvene, a semisynthetic derivative of the mushroom toxin illudin S.

6-Hydroxymethylacylfulvene (HMAF; MGI 114) is a novel semisynthetic antitumor agent derived from the sesquiterpene mushroom toxin illudin S. In vitro cytotoxicity determinations produced IC50 concentrations (concentrations required for 50% inhibition of growth) ranging from 160 nM in sensitive MCF-7 human mammary carcinoma cells to 17 microM in relatively insensitive murine B16 melanoma cells. In vivo antitumor activity was consistent with in vitro sensitivity. HMAF was very effective in human tumor xenograft models, including MX-1 breast carcinoma, MV522 lung adenocarcinoma, and HT-29 colon carcinoma, but not murine B16 melanoma or P388 leukemia. Excellent responses were observed in animals bearing MX-1 tumors administered i.v. or i.p. doses of 3-7.5 mg/kg daily for 5 days, with complete regression recorded in 29 of 30 animals administered i.v. HMAF. Extensive tumor shrinkage was also observed with MV522, and significant tumor growth inhibition was obtained with HT-29 when animals received 5 daily i.p. doses ranging from 3.75 to 7.5 mg/kg. Complete regressions were also observed in individual animals with MV522 and HT-29. The excellent activity of HMAF in several human solid tumor xenografts, including the more refractory MV522 and HT-29 models, warrants the further investigation of this novel agent in clinical trials.

Characterization of cellular accumulation and toxicity of illudin S in sensitive and nonsensitive tumor cells.

Illudins are novel low molecular weight natural products cytotoxic to human tumor cells in vitro. Illudin-derived analogs are effective against experimental human cancers nonresponsive to conventional anticancer agents. It is not known why some illudin analogs are more efficacious in vitro and in vivo than other analogs. Therefore, the in vitro cytotoxicity of the parent compound illudin S towards tumor cells was characterized using radiolabeled drug. Two cell lines sensitive at nanomolar concentrations using only a 15-min exposure period displayed a saturable, energy-dependent accumulation of illudins with relatively low K(m) and high Vmax values. A nonsensitive cell line, requiring millimolar concentrations to achieve in vitro toxicity, showed minimal illudin uptake with higher K(m) and lower Vmax values. No release of radioactivity could be demonstrated from tumor cells, indicating that there was no efflux of illudin S (or metabolites) from these cells. The number of intracellular illudin S molecules required to kill 50% of cells of different tumor cell lines varied from 78000 to 1114000 molecules per cell and was correlated with the 2-h IC50 value determined using a colony-forming assay. Illudin S was cytotoxic to a variety of multidrug-resistant tumor cell lines regardless of whether resistance was mediated by gp170/mdrl, gp180/MRP, GSHTR-pi, topoisomerase I, topoisomerase II, increased DNA repair capacity, or alterations in intracellular thiol content. Information obtained in this study could be used to design clinical phase I trials and to develop analogs with improved therapeutic indexes.

Recent developments in the field of plant steroid hormones.

Brassinolide and related brassinosteroids are a novel group of steroids which appear to be ubiquitous in plants. There is compelling evidence, particularly from recent genetic studies, that these steroids are essential for normal plant growth and development. Synthesis of brassinosteroids and aspects of their biochemistry are reviewed.

(Hydroxymethyl)acylfulvene: an illudin derivative with superior antitumor properties.

Reaction of the fungal sesquiterpene illudin S with excess paraformaldehyde in dilute H2SO4 gives (hydroxymethyl)acylfulvene. The primary allylic hydroxyl thus formed can undergo very facile replacement by a variety of nucleophiles. (Hydroxymethyl)acylfulvene (MGI.114) was more toxic than a precursor, acylfulvene, but less toxic than the parent compound illudin S to HL 60 cells.

A brassinosteroid-insensitive mutant in Arabidopsis thaliana exhibits multiple defects in growth and development.

Brassinosteroids are widely distributed plant compounds that modulate cell elongation and division, but little is known about the mechanism of action of these plant growth regulators. To investigate brassinosteroids as signals influencing plant growth and development, we identified a brassinosteroid-insensitive mutant in Arabidopsis thaliana (L.) Henyh. ecotype Columbia. The mutant, termed bri1, did not respond to brassinosteroids in hypocotyl elongation and primary root inhibition assays, but it did retain sensitivity to auxins, cytokinins, ethylene, abscisic acid, and gibberellins. The bri1 mutant showed multiple deficiencies in developmental pathways that could not be rescued by brassinosteroid treatment including a severely dwarfed stature; dark green, thickened leaves; males sterility; reduced apical dominance; and de-etiolation of dark-grown seedlings. Genetic analysis suggests that the Bri1 phenotype is caused by a recessive mutation in a single gene with pleiotropic effects that maps 1.6 centimorgans from the cleaved, amplified, polymorphic sequence marker DHS1 on the bottom of chromosome IV. The multiple and dramatic effects of mutation of the BRI1 locus on development suggests that the BRI1 gene may play a critical role in brassinosteroid perception or signal transduction.

A role for brassinosteroids in light-dependent development of Arabidopsis.

Although steroid hormones are important for animal development, the physiological role of plant steroids is unknown. The Arabidopsis DET2 gene encodes a protein that shares significant sequence identity with mammalian steroid 5 alpha-reductases. A mutation of glutamate 204, which is absolutely required for the activity of human steroid reductase, abolishes the in vivo activity of DET2 and leads to defects in light-regulated development that can be ameliorated by application of a plant steroid, brassinolide. Thus, DET2 may encode a reductase in the brassinolide biosynthetic pathway, and brassinosteroids may constitute a distinct class of phytohormones with an important role in light-regulated development of higher plants.

Efficacy of HMAF (MGI-114) in the MV522 metastatic lung carcinoma xenograft model nonresponsive to traditional anticancer agents.

Illudin analogs are cytotoxic to a variety of multidrug resistant cell lines, and display an unusual toxicity towards DNA helicase-deficient cell lines. Earlier illudin analogs demonstrated efficacy in several xenograft models, including a metastatic MV522 lung cancer model, resistant to conventional anticancer agents. These illudin analogs prolonged life span as compared to conventional agents, but did not induce complete remission of primary tumors. In vitro screening studies identified a semisynthetic derivative, hydroxymethylacylfulvene (HMAF, MGI-114), with increased selective cytotoxicity towards carcinoma cells. The HMAF analog was markedly effective in the experimental MV 522 metastasizing lung carcinoma xenograft system, a model refractory to treatment with existing anticancer agents. Treatment with paclitaxel, doxorubicin, or cisplatin failed to significantly inhibit primary tumor growth or prolong life span of MV522 tumor-bearing animals. Treatment with mitomycin C at the LD20 increased life span in surviving animals up to 61% (p = 0.04). Treatment with HMAF induced primary tumor regression in all animals and increased life span greater than 150% (p < 0.001). Thus, administration of HMAF inhibited development of lung metastasis in a model refractory to treatment with conventional anticancer agents. These results support further evaluation of HMAF as a therapeutic agent for treatment of solid tumors such as adenocarcinoma of the lung.

Acylfulvenes, a new class of potent antitumor agents.

Acylfulvene, derived from the sesquiterpene illudin S by treatment with acid (reverse Prins reaction), is far less reactive to thiols than illudin S. However, it is reduced readily to an aromatic product, in the same way as illudin S. This may explain its greatly improved therapeutic index compared to that of the parent compound.