Interaction of mithramycin with chromatin

Mithramycin (MTR) is an anti-cancer antibiotic that blocks the macromolecular biosynthesis via reversible interaction with DNA template in the presence of bivalent metal ion such as Mg2+. In absence of DNA, mithramycin forms two types of complexes with Mg2+, complex I (with 1:1 stoichiometry in terms of MTR: Mg2+) and complex II (with 1:2 stoichiometry in terms of MTR: Mg2+). In an eukaryotic system, the drug would interact with chromatin, a protein-DNA complex. We have employed the spectroscopic techniques such as absorption and fluorescence to study the interaction of MTR: Mg2+ complexes with rat liver chromatin. In this report, we have shown that the two types of ligands have different binding potentials with the same chromatin. This supports our proposition that complexes I and II, are different molecular species. We have also shown that the histone protein(s) reduce the binding potential and the number of available sites for both ligands.     

The influence of Mg++ and Zn++ on polypurine-polypyrimidine multistranded helices

We have studied by X-ray diffraction fibres of complexes of polypurine-polypyrimidine with divalent cations. In the presence of Mg++, poly(dC) and poly(dG) form a very stable triple helix at neutral pH, based on G-G-C triplexes, whereas Zn++ prevents its formation, both at neutral and acidic pH. The poly(dC) . poly(dG) complex with Zn++ is of the B form, but its X-ray diffraction pattern shows an unusual intensity distribution. This is probably due to the fact that counterions occupy defined positions on the helix. The A form has not been observed. With poly[d(A-G)].poly [d(C-T)] a different triple helical structure is formed, both with Zn++ and Mg++. Direct, X-ray diffraction evidence for these triple helices is provided here for the first time.     

Interactions of chromomycin A3 and mithramycin with the sequence d(TAGCTAGCTA)2

Anti-cancer antibiotics, chromomycin A3 (CHR) and mithramycin (MTR) inhibit DNA directed RNA synthesis in vivo by binding reversibly to template DNA in the minor groove with GC base specificity, in the presence of divalent cations like Mg2+. Under physiological conditions, (drug)2Mg2+ complexes formed by the antibiotics are the potential DNA binding ligands. Structures of CHR and MTR differ in their saccharide residues. Scrutiny of the DNA binding properties reveal significant differences in their sequence selectivity, orientation and stoichiometry of binding. Here, we have analyzed binding and thermodynamic parameters for the interaction of the antibiotics with a model oligonucleotide sequence, d(TAGCTAGCTA)2 to understand the role of sugars. The oligomer contains two potential binding sites (GpC) for the ligands. The study illustrates that the drugs bind differently to the sequence. (MTR)2Mg2+ binds to both sites whereas (CHR)2Mg2+ binds to a single site. UV melting profiles for the decanucleotide saturated with the ligands show that MTR bound oligomer is highly stabilized and melts symmetrically. In contrast, with CHR, loss of symmetry in the oligomer following its association with a single (CHR)2Mg2+ complex molecule leads to a biphasic melting curve. Results have been interpreted in the light of saccharide dependent differences in ligand flexibility between the two antibiotics.     

Control of mitochondrial Mg++-efflux]

Inorganic phosphate stimulates the release of Mg++ from liver mitochondria, depending on concentration; a concentration as low as 0.1 mM phosphate is already effective. The process is dependent on the electron transfer of the respiratory chain, and its rate is highest under conditions of endogenous respiration and with ascorbate and TMPD as substrates, respectively. The phosphate stimulated release of Mg++ is followed, with a pronounced delay, by a Ca++ efflux and a swelling of mitochondria. Addition of EGTA strongly reduced the rate of Mg++ liberation in the presence and absence of inorganic phosphate. Exogenous Ca++ is able to abolish the EGTA effect. ADP and ATP inhibit the phosphate stimulated release of Mg++. Phosphoenol pyruvate and free fatty acids enhance the rate of Mg++ and Ca++ efflux from the mitochondria. The results permit the conclusion that inorganic phosphate, Ca++ and various metabolites of the cell metabolism influence the Mg++ distribution between the extra- and intramitochondrial space, thus controlling the permeability of the mitochondrial inner membrane for monovalent cations.     

Interaction between antitumor antibiotic chromomycin A3 and Mg2+. I. Evidence for the formation of two types of chromomycin A3-Mg2+ complexes.

Chromomycin A3 (CHRA3) is an antitumor antibiotic which binds to Mg2+. In the present communication, we show, by means of equilibrium spectroscopic studies (such as absorption, fluorescence and circular dichroism), that two types of CHRA3-Mg2+ complexes (of 1:1 and 1.9:1 stoichiometries in terms of CHRA3:Mg2+, respectively) are formed depending on the concentrations of CHRA3 and Mg2+. The rate constant and activation energy for the formation of two complexes are different, thereby reinforcing the proposition that they are different molecular species. This observation is novel and significant in order to understand the anticancer property of the drug. It also provides explanation for earlier observations that site, affinity parameters and mode of interaction of the drug with DNA in the presence of Mg2+ depend on the relative concentration of Mg2+.     

Binding of mithramycin to DNA in the presence of second drugs

Comparative DNA equilibrium binding studies with mithramycin (MTR) and ethidium bromide in the presence and in the absence of second drugs were investigated by spectral titrations. Unusual curvatures (in contrast to those due to neighbor exclusion or anticooperativity) are found in the Scatchard plots of MTR-DNA titrations in the presence of netropsin, a minor-groove binder. Parallel studies with ethidium bromide indicate that although the presence of netropsin significantly reduces the binding ability of ethidium, no unusually curved Scatchard plots are obtained. The unusual curvature exhibited by the Scatchard plots of MTR titrations in the presence of netropsin indicates that the binding of netropsin greatly affects the MTR binding to DNA and can be simulated by an explicit incorporation of the second drug-DNA interaction in the binding formalism. Since netropsin is a minor-groove binder, its interference with the binding of MTR is in accord with the notion that MTR also binds at this groove. The observation of negligible effects on the DNA binding ability of MTR in the presence of either a major-groove or a phosphate group binder lends further support to this conclusion. Consistent with its guanine specificity, studies with synthetic polynucleotides suggest that MTR exhibits negligible affinity for poly(dA-dT).poly(dA-dT) or poly(dA).poly(dT).(ABSTRACT TRUNCATED AT 250 WORDS)     

Phosphorylation of the red blood cell membrane during the active transport of C++

The phosphorylation of red blood cell membrane fragments (RBCMF) during Ca++ transport was investigated. When red cell membrane fragments are incubated with [gamma-32P]ATP under the experimental condition which minimizes the phosphorylation of Na+-K+-ATPase, RBCMF are labeled in the presence of Mg++ without Ca++. When Ca++ is added, the labeling decreases due to dephosphorylation of RBCMF. The initial reaction of phosphorylation is reversed in the presence of excess ADP. The treatment of RBCMF with n-ethylmaleimide (NEM) does not interfere with the initial phosphorylation reaction, but blocks the dephosphorylation in the presence of Ca++. These data suggest that the enzymatic sequence of the Ca++ transport mechanism may be very similar to that of the Na+ transport mechanism.     

Effect of quinine on mitochondrial K+ and Mg++ flux

Quinine decreases rates of unidirectional K+ flux into and out of respiring rat liver mitochondria. K+ efflux is more sensitive to quinine than K+ influx. The data are consistent with the proposal that two separate mechanisms may mediate K+ influx, only one of which is sensitive to quinine. Effects on K+ flux of the stereoisomer quinidine are similar to effects of quinine. The smaller quinuclidine causes at most a slight inhibition of K+ efflux under the same conditions. Mg++ flux exhibits a pattern of inhibition by quinine similar to that of K+ flux. Mg++ efflux is more sensitive to quinine than is Mg++ influx. These and earlier findings indicate marked similarities between liver mitochondrial transport mechanisms for K+ and Mg++.     

Role of magnesium ion in the interaction between chromomycin A3 and DNA: binding of chromomycin A3-Mg2+ complexes with DNA.

Chromomycin A3 is an antitumor antibiotic which blocks macromolecular synthesis via reversible interaction with DNA template only in the presence of divalent metal ions such as Mg2+. The role of Mg2+ in this antibiotic-DNA interaction is not well understood. We approached the problem in two steps via studies on the interaction of (i) chromomycin A3 and Mg2+ and (ii) chromomycin A3-Mg2+ complex(es) and DNA. Spectroscopic techniques such as absorption, fluorescence, and CD were employed for this purpose. The results could be summed up in two parts. Absorption, fluorescence, and CD spectra of the antibiotic change upon addition of Mg2+ due to complex formation between them. Analysis of the quantitative dependence of change in absorbance of chromomycin A3 (at 440 nm) upon input concentration of Mg2+ indicates formation of two types of complexes with different stoichiometries and formation constants. Trends in change of fluorescence and CD spectroscopic features of the antibiotic in the presence of Mg2+ at different concentrations further corroborate this result. The two complexes are referred to as complex I (with 1:1 stoichiometry in terms of chromomycin A3:Mg2+) and complex II (with 2:1 stoichiometry in terms of chromomycin A3:Mg2+), respectively, in future discussions. The interactions of these complexes with calf thymus DNA were examined to check whether they bind differently to the same DNA. Evaluation of binding parameters, intrinsic binding constants, and binding stoichiometry, by means of spectrophotometric and fluorescence titrations, shows that they are different. Distinctive spectroscopic features of complexes I and II, when they are bound to DNA, also support that they bind differently to the above DNA. Measurement of thermodynamic parameters characterizing their interactions with calf thymus DNA shows that complex I-DNA interaction is exothermic, in contrast to complex II-DNA interaction, which is endothermic. This feature implies a difference in the molecular nature of the interactions between the complexes and calf thymus DNA. These observations are novel and significant to understand the antitumor property of the antibiotic. They are also discussed to provide explanations for the earlier reports that in some cases appeared to be contradictory.     

Effects of delta 9-tetrahydrocannabinol on testosterone production in vitro: influence of Ca++, Mg++ or glucose

The major psychoactive component of marihuana, delta 9-tetrahydrocannabinol (THC), influences testicular function. In the present experiments, the addition of THC to incubations of whole decapsulated mouse testes altered testosterone (T) production differentially, depending on the specific gonadotropin used, the dose of THC and/or the amount of divalent cation present in the media. In the presence of luteinizing hormone (LH; 10 ng/ml), and a dose of 25 micrograms THC/ml, T production was significantly decreased, compared to that by testes incubated with LH and vehicle at all Ca++ levels, except at 0.127 or 1.0 mM Ca++. The production of T by these paired testes exposed to either THC or vehicle (ethanol; ETOH), increased as Ca++ concentration approached physiological levels. In contrast, in the presence of follicle-stimulating hormone (FSH; 1 microgram/ml), THC-induced suppression of T production was significant in the absence of Ca++ from the media, and at 12.7 mM Ca++. However, it appeared that the levels of Ca++ did not differentially affect T production in the presence of FSH, whether or not THC was also added. In the presence of human chorionic gonadotropin (hCG; 12.5 mIU/ml), a lower dose of THC (25 ng/ml), stimulated T production at 0.25 to 1 mM Ca++, but had no effect as Ca++ reached 2.5 mM. Without additional Ca++ in the media, this dose of THC significantly reduced T secretion. In contrast, in the presence of hCG, a higher THC dose (25 micrograms/ml), suppressed T accumulation at 0.127, and from 1.0 to 12.7, but had no effect at 0.25 mM, or in the absence of Ca++. In the presence of hCG, the high 25 micrograms/ml dose of THC stimulated T production, in the absence of additional Mg++, and at 0.01 mM Mg++, but THC had no effect at 0.1 mM Mg++, but inhibited T production at 1.1 mM Mg++. In the presence of hCG, 25 micrograms THC/ml produced a consistent suppression of T production across glucose concentrations examined. These findings suggest that the mechanisms by which THC effects testicular steroidogenesis may involve Ca++- and/or Mg++-dependent processes. Differential requirements for these divalent cations by the gonadotropins may explain the interactive effects of THC with LH, hCG or FSH.     

Mg++-sensitivity of neuromuscular transmission in two crustaceans: correlation with blood Mg++ levels.

Neuromuscular transmission was measured in muscles of spider crabs (Hyas areneus) and lobsters (Homarus americanus). Solutions containing 40 and 10 mM/1 Mg++, which were approximately the same as those measured in the blood of Hyas and Homarus, respectively, were used to soak the preparations prior to testing. In Homarus, neuromuscular transmission was severely depressed by 40 mM Mg++. In spider crabs, neuromuscular transmission was not severely depressed. Although the amount of transmitter released by nerve impulses was reduced, total membrane depolarization during trains of impulses was not reduced because a compensating increase in muscle fiber membrane resistance occurred in Hyas preparations exposed to M Mg++. Hyas, but not Homarus, is physiologically adapted to function at relatively high blood Mg++ concentrations.     

Influence of calcium and magnesium deprivation on ovulation and ovum maturation in the perfused rabbit ovary

The role of calcium (Ca++) and magnesium (Mg++) in the ovulation process was studied using in vitro perfused rabbit ovaries. Ovaries were perfused with or without human chorionic gonadotropin (hCG) in Ca++/Mg++-free medium (M199) alone or combined with standard M199 to yield varying concentrations of Ca++ and/or Mg++. In all ovaries perfused with hCG, ovulatory efficiency was similar regardless of the concentration of Ca++ and/or Mg++. In ovaries perfused in Ca++/Mg++-free medium without hCG, ovulatory efficiency was similar to that in ovaries perfused with hCG. As Ca++/Mg++ levels were increased without hCG, ovulatory efficiency declined. Ovulation time was significantly accelerated in ovaries perfused in Ca++/Mg++-free medium with or without hCG. Most ovulated ova from ovaries perfused without hCG were immature. With hCG, degree of ovum maturity was directly related to ovulation time. Ovarian smooth muscle contractions were undetectable in 3 ovaries perfused in Ca++/Mg++-free M199 despite occurrence of ovulation. Smooth muscle contractions were recorded in 2 of 3 ovaries perfused in standard M199 with hCG. These results indicate: 1) Ca++/Mg++ exclusion results in rapid follicle rupture and immature ova; 2) oocyte maturation appears to be gonadotropin-dependent; 3) ovulation occurs in the absence of ovarian smooth muscle contractions during perfusion with Ca++/Mg++-free medium.     

The mechanisms of antibody-dependent killing mediated by lymphoid and myeloid cells are distinct based on different divalent cation requirements

To further understand the mechanism(s) of antibody-dependent cell-mediated cytotoxicity (ADCC) by various effector populations, we have examined the extracellular Ca++ and Mg++ requirements for ADCC performed by lymphocytes, monocytes, polymorphonuclear leukocytes and peritoneal macrophages. We have used the anti-Fc gamma R-bearing hybridoma cell lines (HC) as self directed targets for ADCC to analyse the triggering ability of each of the three defined Fc gamma R; Fc gamma RI, Fc gamma RII, and Fc gamma RIII. Lymphocyte killing of the anti-Fc gamma RIII bearing HC (HC 3G8) was Ca++ dependent, but Mg++ independent. In contrast, monocytes and PMN killed the anti-Fc gamma RI- (HC 32) and the anti-Fc gamma RII- (HC IV.3) bearing HC in a Mg++-dependent, Ca++-independent fashion. In addition, freshly prepared monocytes were able to kill HC 3G8 in a Mg++-dependent, Ca++-independent fashion, indicating that low levels of Fc gamma RIII may be functionally detected on monocytes. Peritoneal macrophages were able to kill all three of the anti-Fc gamma R bearing HC in a Mg++-dependent, Ca++-independent fashion. Thus, the same target is lysed by myeloid cells in the presence of Mg++ without Ca++ and by lymphoid cells in the presence of Ca++ without Mg++. These results suggest that at least two distinct mechanisms of ADCC exist that depend on the type of effector cell mediating antibody-dependent killing and not necessarily on the Fc gamma R type triggered.     

Attractant-induced changes and oscillations of the extracellular Ca++ concentration in suspensions of differentiating Dictyostelium cells

We used a Ca++-sensitive electrode to measure changes in extracellular Ca++ concentration in cell suspensions of Dictyostelium discoideum during differentiation and attractant stimulation. The cells maintained an external level of 3-8 microM Ca++ until the beginning of aggregation and then started to take up Ca++. The attractants, folic acid, cyclic AMP, and cyclic GMP, induced a transient uptake of Ca++ by the cells. The response was detectable within 6 s and peaked at 30 s. Half-maximal uptake occurred at 5 nM cyclic AMP or 0.2 microM folic acid, respectively. The apparent rate of uptake amounted to 2 X 10(7) Ca++ per cell per min. Following uptake, Ca++ was released by the cells with a rate of 5 X 10(6) ions per cell per min. Specificity studies indicated that the induced uptake of Ca++ was mediated by cell surface receptors. The amount of accumulated Ca++ remained constant as long as a constant stimulus was provided. No apparent adaptation occurred. The cyclic AMP-induced uptake of Ca++ increased during differentiation and was dependent on the external Ca++ concentration. Saturation was found above 10 microM external Ca++. The time course and magnitude of the attractant-induced uptake of external Ca++ agree with a role of Ca++ during contraction. During development the extracellular Ca++ level oscillated with a period of 6-11 min. The change of the extracellular Ca++ concentration during one cycle would correspond to a 30-fold change of the cellular free Ca++ concentration.     

The mode of Mg++ binding to oligonucleotides. Inner sphere complexes as markers for recognition?

Large changes of UV absorbance and CD spectra as well as specific relaxation processes with time constrants around 50 mus are found for the association of Mg++ with A(pa)n. The Mg++ binding constants strongly increase with increasing n. The relaxation data demonstrate that a large fraction of Mg++ bound to short A(pA)n forms inner sphere complexes (ISC), with H2O molecules from the inner hydration sphere of Mg++ exchanged against some site (s) of the oligomer. This fraction decreases from about 85% for A(pA)4 to less than 10% for A(pA)17. A parallel decrease is observed in the relative change of CD spectrum upon Mg++ binding from 77.5% for A(pA)4 to 13.4% for (pA)17. The rate of ISC formation decreases with increasing n suggesting some (probably sterical) hindrance effect at high n. The data support the conclusion that Mg++ favours the formation of outer sphere complexes with linear polynucleotides and require a special chain folding for ISC. Measurements of Mg++ binding to C(pC)5, U(pU)5, I(pI)5 and d[A(pA)5] did not give evidence for the formation of ISC, indicating that both specific base and sugar residues are required for ISC. These results suggest the possibility that Mg++ISC ARE USED FOR SPECific recognition of nucleic acid sequences.     

Differential interactions of antitumor antibiotics chromomycin A(3) and mithramycin with d(TATGCATA)(2) in presence of Mg(2+)

The antitumor antibiotics chromomycin A(3) (CHR) and mithramycin (MTR) are known to inhibit macromolecular biosynthesis by reversibly binding to double stranded DNA with a GC base specificity via the minor groove in the presence of a divalent cation such as Mg(2+). Earlier reports from our laboratory showed that the antibiotics form two types of complexes with Mg(2+): complex I with 1:1 stoichiometry and complex II with 2:1 stoichiometry in terms of the antibiotic and Mg(2+). The binding potential of an octanucleotide, d(TATGCATA)(2), which contains one potential site of association with the above complexes of the two antibiotics, was examined using spectroscopic techniques such as absorption, fluorescence, and circular dichroism. We also evaluated thermodynamic parameters for the interaction. In spite of the presence of two structural moieties of the antibiotic in complex II, a major characteristic feature was the association of a single ligand molecule per molecule of octameric duplex in all cases. This indicated that the modes of association for the two types of complexes with the oligomeric DNA were different. The association was dependent on the nature of the antibiotics. Spectroscopic characterization along with analysis of binding and thermodynamic parameters showed that differences in the mode of recognition by complexes I and II of the antibiotics with polymeric DNA existed at the oligomeric level. Analysis of the thermodynamic parameters led us to propose a partial accommodation of the ligand in the groove without the displacement of bound water molecules and supported earlier results on the DNA structural transition from B --> A type geometry as an obligatory requirement for the accommodation of the bulkier complex II of the two drugs. The role of the carbohydrate moieties of the antibiotics in the DNA recognition process was indicated when we compared the DNA binding properties with the same type of Mg(2+) complex for the two antibiotics.     

The Ca++ permeability of the apical membrane in neuromast hair cells

The mechanosensitivity of eel (Anguilla anguilla) neuromasts was measured by the impulse responses of single afferent nerve fibers to mechanical stimuli. It is dependent on the potential across the skin and on the ions in the water outside the apical membrane of the sensory cells. The mechanosensitivity decreases to zero when the skin is polarized by 10-100 mV cathodal DC (skin surface negative); it increases with increasing (10-60 mV) anodal DC and remains remarkably constant with higher polarization (Fig. 1). The mechanosensitivity increases with increasing concentrations of Ca++ outside the apical membrane of the sensory cells. Na+ and K+ have no influence. Addition of La , Co++, Mg++, D 600 and A-QA 39 inhibits the mechanosensitivity; the degree of inhibition varies with the inhibitor and the ratio [Ca++]/[inhibitor], indicating that the inhibition is competitive (Figs. 2, 3). We conclude that the apical membrane is specifically permeable to Ca++ ('late Ca channel') and that the inward receptor current through the apical membrane is carried by Ca++. Streptomycin also inhibits mechanosensitivity by competing with Ca++. With streptomycin, however, anodal polarization reduces, rather than increases, the mechanosensitivity (Fig. 4).(ABSTRACT TRUNCATED AT 250 WORDS)     

Evidence for the influence of the protein-phospholipid interface on sarcoplasmic reticulum Ca++ Mg++ ATPase activity.

Sarcoplasmic reticulum from the white hind leg muscle of the rabbit was examined with 31P nuclear magnetic resonance as a nonperturbing probe of phospholipid-protein interactions in the intact membrane. The phospholipids of the sarcoplasmic reticulum appear to inhabit two distinct environments: one very similar in behavior to pure phospholipid lamellar dispersions and the other immobilized by the protein in the membrane. Measurement of the population of the latter environment suggests that it is dependent on salt concentration and probably not due to the Ca++ Mg++ ATPase of the sarcoplasmic reticulum. This immobilization can be removed completely by papain proteolysis of the membrane protein, but only partially by trypsin treatment. The phospholipid composition of recombinants with the Ca++ Mg++ ATPase was varied in order to look for effects of the phospholipid-protein interface on enzymatic activity of the Ca++ Mg++ ATPase. Both transphosphatidylated phosphatidylethanolamine (from egg phosphatidylcholine) and bovine brain phosphatidylserine readily partitioned into the putative boundary layer, whereas under the same conditions soybean phosphatidylethanolamine was excluded. Only phosphatidylserine affected the activity of the enzyme, causing an inhibition that was proportional to the phosphatidylserine content, relative to phosphatidylcholine.