Here we show that, as a consequence of binding the drug trifluoperazine, a major conformational movement occurs in Ca(2+)-calmodulin (CaM). The tertiary structure changes from an elongated dumb-bell, with exposed hydrophobic surfaces, to a compact globular form which can no longer interact with its target enzymes. It is likely that inactivation of Ca(2+)-CaM by trifluoperazine is due to this major tertiary-structural alteration in Ca(2+)-CaM, which is initiated and stabilized by drug binding. This conformational change is similar to that which occurs on the binding of Ca(2+)-CaM to target peptides. Two hydrophobic binding pockets, created by amino acid residues adjacent to Ca(2+)-coordinating residues, form the key recognition sites on Ca(2+)-CaM for both inhibitors and target enzymes.
Xanthatin and xanthinosin, 2 sesquiterpene lactones isolated from the burs of Xanthiun strumarium L. (cocklebur), showed moderate to high in vitro cytotoxic activity in the human cancer cell lines WiDr ATCC (colon), MDA-MB-231 ATCC (breast), and NCI-417 (lung). Xanthatin and xanthinosin were purified as the result of a multi-screening bioassay-guided study of wild plant species of the family Asteraceae, collected from various sites in Saskatchewan, Canada. Seventy-five extracts at a single concentration of 100 microg/mL were evaluated for in vitro cytotoxicity to the human cancer cell lines used. The chloroform extract of Carduus nutans L. (nodding thistle) aerial parts (IC50, 9.3 microg/mL) and the hexane extract of Echinacea angustifolia DC. (narrow-leaved purple coneflower) root (IC50, 4.0 microg/mL) were moderately to highly cytotoxic to the lung cancer cell line. The chloroform extracts of X. strumarium L. burs and Tanacetum vulgare L. (tansy) aerial parts exhibited the highest cytotoxicity for all cell lines tested; their IC50 values, obtained from multidose testing, ranged from 0.1 to 6.2 microg/mL (X. strumarium) and from 2.4 to 9.1 microg/mL (T. vulgare). Further purification of the chloroform fraction of X. strumarium yielded xanthatin and xanthinosin in high yields. This is the first time that these compounds have been reported in the burs of X. strumarium. Their IC50 values are also reported herein.
The purpose of this presentation is to review pertinent literature pertaining to the role of divalent cations and calmodulin in regulating growth of nonneoplastic and neoplastic cells and to examine the anticancer efficacy of some calmodulin inhibitors. Although normal eukaryotic cell replication and proliferation is closely controlled by a complex system of endogenous substances, it is likely that the coordination of purposeful interactions between these substances is the ultimate responsibility of two groups of cellular components, namely the divalent cations Ca2+ and Mg2+ and the versatile intracellular Ca2+-binding protein calmodulin (CaM). When free Ca2+ enters normal cells, it acts as a positive signal for proliferation; this action appears to be specifically associated with the late G1 phase, just prior to DNA synthesis. This period is designated G1/S and is considered to contain Pardee's "restriction point." Reduction of extracellular Ca2+ concentrations between physiological levels (1-0.1 mM) results in gradually reduced rates of cell proliferation; at Ca2+ concentrations of 0.1 mM or less, normal cell proliferation is reversibly inhibited. Since an extracellular concentration of about 0.7 mM Mg2+ is required for Ca2+ to initiate cell replication, it has been proposed that Ca2+ and Mg2+ act in concert via a common mechanism, however, in contrast to Ca2+, Mg2+ appears to be required throughout the entire cell cycle. Intracellular Ca2+ can activate CaM which, in turn, can modulate various cellular processes that affect cell proliferation, including cyclic nucleotide metabolism, protein phosphorylation, polyamine metabolism, prostaglandin metabolism, Ca2+ transport, DNA synthesis, and microtubular function including mitosis.(ABSTRACT TRUNCATED AT 250 WORDS)
The effects of anticalmodulin agents, namely trifluoperazine (TFP) and two naphthalene sulfonamide derivatives (W-7 and W-13), were tested on the growth of a human breast cancer cell line (MDA-MB-231) using a soft agar clonogenic assay. The results of this in vitro study reveal that TFP, W-7, and W-13 had the ability to inhibit the colony formation from this cell line. The inhibitory effect was greater when the cancer cells were exposed to these agents continuously than when the cells were exposed to the drugs for 1 h. The IC50 values for TFP, W-7, and W-13 in continuous exposure were about 18, 30, and 38 microM, respectively, whereas the corresponding values for 1-h exposure were 50, 53, and 70 microM, respectively. These findings suggest that anticalmodulin agents can inhibit the growth of human cancer cells at relatively low concentrations in vitro. Whether effective antitumor concentrations of these drugs can be achieved in vivo remains a subject for further study.
1. Guanylate cyclase of every fraction studied showed an absolute requirement for Mn2+ ions for optimal activity; with Mg2+ or Ca2+ reaction was barely detectable. Triton X-100 stimulated the particulate enzyme much more than the supernatant enzyme and solubilized the particulate-enzyme activity. 2. Substantial amounts of guanylate cyclase were recovered with the washed particulate fractions of cardiac muscle (63-98%), skeletal muscle (77-93%), cerebral cortex (62-88%) and liver (60-75%) of various species. The supernatants of these tissues contained 7-38% of total activities. In frog heart, the bulk of guanylate cyclase was present in the supernatant fluid. 3. Plasma-membrane fractions contained 26, 21, 22 and 40% respectively of the total homogenate guanylate cyclase activities present in skeletal muscle (rabbit), cardiac muscle (guinea pig), liver (rat) and cerebral cortex (rat). In each case, the specific activity of this enzyme in plasma membranes showed a five- to ten-fold enrichment when compared with homogenate specific activity. 4. These results suggest that guanylate cyclase, like adenylate cyclase, and ouabain-sensitive Na+ + K+-dependent ATPase (adenosine triphosphatase), is associated with the surface membranes of cardiac muscle, skeletal muscle, liver and cerebral cortex; however, considerable activities are also present in the supernatant fractions of these tissues which contain very little adenylate cyclase or ouabain-sensitive Na+ + K+-dependent ATPase activities.
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