Acridine orange binding to chromatin of individual cells and nuclei under different staining conditions. I. Binding capacity of chromatin.

A study was made to find the optimal conditions for titration of the strong acridine orange binding sites of DNA in situ by an equilibrium staining method. Low concentrations of dye (≈10^?6 M) and an equilibration time of about 1 h were found necessary. Chick erythrocyte nuclei were used as a model system to compare results of this equilibrium method with those of conventional staining. Before staining, nuclei were subjected to acid extraction and denaturation or to biological activation via cell hybridization. Qualitatively similar results were obtained with the two staining methods, but the equilibrium method circumvents the problems of dye-to-dye aggregation and differences in diffusion conditions, and thus gives more easily interpretable data and true quantitative information about the properties of chromatin in situ.     

Binding of brush border myosin I to phospholipid vesicles

The actin filament core within each microvillus of the intestinal epithelial cell is attached laterally to the plasma membrane by brush border (BB) myosin I, a protein-calmodulin complex belonging to the myosin I class of actin-based mechanoenzymes. In this report, the binding of BB myosin I to pure phospholipid vesicles was examined and characterized. BB myosin I demonstrated saturable binding to liposomes composed of anionic phospholipids, but did not associate with liposomes composed of only neutral phospholipids. The binding of BB myosin I to phosphatidylserine and phosphatidylglycerol vesicles reached saturation at 4-5 x 10(-3) nmol protein/nmol phospholipid, while the apparent dissociation constant was determined to be 1-3 x 10(-7) M. Similar to the free protein, membrane-associated BB myosin I bound F-actin in an ATP-sensitive manner and demonstrated actin-activated Mg-ATPase activity. Immunoblot analysis of peptides generated from controlled proteolysis of vesicle-bound BB myosin I provided structural information concerning the site responsible for the membrane interaction. Immunoblot staining with domain-specific mAbs revealed a series of COOH-terminal, liposome-associated peptides that were protected from digestion, suggesting that the membrane-binding domain is within the carboxy-terminal "tail" of the BB myosin I heavy chain.     

Binding of troponin I and the troponin I-troponin C complex to actin-tropomyosin. Dissociation by myosin subfragment 1

Troponin I (TnI) is the component of the troponin complex, TnI, TnC, TnT, that is responsible for inhibition of actomyosin ATPase activity. Using the fluorescence of pyrene-labeled tropomyosin (Tm), we probed the interaction of TnI and TnIC with Tm on the reconstituted muscle thin filament. The results indicate that TnI and TnIC(-Ca(2+)) bind specifically and strongly to actin-Tm with a stoichiometry of 1 TnI or 1 TnIC/1 Tm/7 actin, in agreement with previous results. The binding of myosin heads (S1) to actin-Tm at low levels of saturation caused TnI and TnIC to dissociate from actin-Tm. These results are interpreted in terms of the S1-binding state allosteric-cooperative model of the actin-Tm thin filament, closed/open. Thus, TnI and TnIC(-Ca(2+)) bind to the closed state of actin-Tm and their binding is greatly weakened in the S1-induced open state, indicating that they act as allosteric inhibitors. The fluorescence change and the stoichiometry indicate that the TnI-binding site is composed of regions from both actin and Tm probably in the vicinity of Cys 190.     

Cytofluorometric studies on conformation of nucleic acids in situ. I. Restriction of acridine orange binding by chromatin proteins.

Binding of the fluorochrome acridine orange (AO) to nucleic acids in situ is studied by automated cytofluorometry in two differentiating cell systems: Friend virus-transformed murine erythroleukemia induced to differentiate by dimethyl sulfoxide, and phytohemagglutinin-stimulated human lymphocytes. The specificity of the stain for deoxyribonucleic acid is discussed on the basis of data obtained by cell treatment with nucleases. Evidence is presented that in the case of Friend leukemia cells, but not phytohemagglutinin-stimulated lymphocytes, a significant change in the number of AO-intercalating sites in DNA occurrs during differentiation. These results suggest that changes in nuclear chromatin occurring during cell differentiation may be correlated, in some but not all systems, with changes in accessibility of DNA in situ to intercalating dyes. The role of divalent cations, especially Mg2+, in the conformation of nuclear chromatin and in modulation of the accessibility of nucleic acids to AO is discussed. The method provides a tool for the study of nucleic acid-protein interaction in situ, and in some cell systems it may be applicable as a marker for recognition of cell transformation, differentiation or neoplasia.     

Phosphorylation of brush border myosin I by protein kinase C is regulated by Ca(2+)-stimulated binding of myosin I to phosphatidylserine concerted with calmodulin dissociation.

Brush border myosin I from chicken intestine is phosphorylated in vitro by chicken intestinal epithelial cell protein kinase C. Phosphorylation on serine and threonine to a maximum of 0.93 mol of P/mol of myosin I occurs within an approximately 20 kDa region at the end of the COOH-terminal tail of the 119-kDa heavy chain. The effects of Ca2+ on myosin I phosphorylation by protein kinase C are complex, with up to 4-fold stimulation occurring at 0.5-3 microM Ca2+, and up to 80% inhibition occurring at 3-320 microM Ca2+. Phosphorylation required that brush border myosin I be in its phosphatidylserine vesicle-bound state. Previously unknown Ca2+ stimulation of brush border myosin I binding to phosphatidylserine vesicles was found to coincide with Ca2+ stimulation of phosphorylation. A myosin I proteolytic fragment lacking approximately 20 kDa of its tail retained Ca(2+)-stimulated binding, but showed reduced Ca(2+)-independent binding. Ca(2+)-dependent phosphatidylserine binding is apparently due to the concomitant phosphatidylserine-promoted, Ca(2+)-induced dissociation of up to three of the four calmodulin light chains from myosin I. Four highly basic putative calmodulin-binding sites in the Ca(2+)-dependent phosphatidylserine binding region of the heavy chain were identified based on the similarity in their sequence to the calmodulin- and phosphatidylserine-binding site of neuromodulin. Calmodulin dissociation is now shown to occur in the low micromolar Ca2+ concentration range and may regulate the association of brush border myosin I with membranes and its phosphorylation by protein kinase C.     

Polarographic studies of ion binding in solutions of pepsin. II. Binding of thallous ions

The results of the application of a modified polarographic method to the study of binding of thallous ions in solutions of pepsin are reported. Isoionic solutions of pepsin were converted by using a cation exchange resin to solutions of thallous pepsin. The extent of ion binding was obtained as in the case of cadmium pepsin by assuming that only free, i.e., unbound, ions contribute to the diffusion and migration currents, respectively. However, the relations used previously for computing the degree of ion binding have been refined on the basis of experience acquired in a parallel study of solutions of thallous acrylate and polyacrylate, respectively.     

Binding of myosin subfragment-1 to F-actin.

During a part of the hydrolytic cycle, myosin head (S1) carries no nucleotide and binds strongly to an actin filament forming a rigor bond. At saturating concentration of S1 in rigor, S1 is well known to form 1:1 complex with actin. However, we have provided evidence that under certain conditions S1 could also form a complex with 2 actin monomers in a filament (Andreev, O.A. & Borejdo, J. (1991) Biochem. Biophys. Res. Comm. 177, 350-356). This view was recently challenged by Carlier & Didry (Carlier, M-F. & Didry, D. (1992) Biochem. Biophys. Res. Comm. 183, 970-974) who interpreted our data by suggesting that F-actin underwent a simple depolymerization and implied that, when only actin in the F-form was scored, the real stoichiometry in our experiments was 1:1. We show here that under conditions of our experiments less than 8% of actin was depolymerized. Moreover, we have repeated the experiments in the presence of phalloidin and show that under these conditions too, when S1 was added slowly to a fixed concentration of F-actin, it formed a different complex with F-actin than when it was added quickly. This confirms our original conclusion that S1 can bind actin in two different ways and shows that depolymerization of F-actin is not responsible for this finding.     

Studies of adsorption for heavy metal ions and degradation of methyl orange based on the surface of ion-imprinted adsorbent

In order to prepare a novel adsorbent which can not only degrade organic compound, but also adsorb the heavy metal ions, immobilization of nanometer titanium dioxide on ion-imprinted chitosan carries was investigated. The amount of TiO₂, different kinds and amounts of dispersants, adding methods of TiO₂, different kinds of cross-linking agents and target metal ions are important factors influencing the degradation of Methyl Orange (MO) and the adsorption for Ni²⁺. When 15% amount of TiO₂ was added in preparation, the removal of MO was highly increased to nearly 90%, which was about eight times higher than that without TiO₂, at the same time, the effect of TiO₂ on the adsorption capacity was not obvious. The results show that in the presence of Ni²⁺ and MO, the MO could be removed effectively and the removal of MO reached 95.4%. At the initial concentration of Ni²⁺ of 200 mg/L, the adsorption capacity of Ni²⁺ reached 33 mg/g in the presence of MO.     

Modulation of the substrate binding sites of platelet myosin by actin.

The studies reported in this paper were undertaken to compare the steady-state kinetics of ATPase of purified platelet actomyosin and myosin free of actin. Actomyosin exhibits highly sigmoid kinetics with at least two interacting ATP or UTP binding sites. These studies were done at O.6 m KCl where actin and myosin are generally supposed to be dissociated in the presence of these nucleotides (M. Gallaghar, T. C. Detwiler, and A. Stracher, 1976, in Cell Motility (Goldman, R., Pollard, T., and Rosenbaum, J., eds.), Vol. 3, Part A, pp. 475–485 Cold Spring Harbor Laboratory, Cold Spring Harbor, N. Y.; A. Weber, 1969, J. Gen Physiol.53, 781–791). When the dissociation of platelet actomyosin was actually investigated by a sucrose density gradient technique under conditions which were similar to those of the steady-state kinetic experiments, only partial dissociation of actin from myosin was observed. This was especially true at low nucleotide concentrations where differences in the sigmoidicity of the saturation curves of actomyosin and actin-free myosin have been observed. These findings suggest that in platelet actomyosin, actin enhances the cooperativity of nucleotide binding sites of myosin by reducing the K_m for ATP or UTP. In contrast, the saturation curves of platelet myosin using either ATP or UTP as substrates are less sigmoidal and possess an intermediary plateau region, when analyzed by Hill and reciprocal plots, these data indicate both positive and negative cooperativity suggesting more than two substrate binding sites. Platelet myosin also hydrolyzed other nucleotides (the order of rates being ITP > UTP > UTP > ATP > CTP > GTP). The kinetics of ITP differed from that of ATP or UTP in that no plateau region was observed on the saturation curve. In addition, no cooperativity of ITP binding sites was seen at low substrate concentrations (up to 0.2 mm) but was instead observed at high ITP concentration. It is concluded that conformational changes in myosin induced by ITP may not be necessarily identical to those induced by ATP or UTP.     

Site-specific mutations in the myosin binding sites of actin affect structural transitions that control myosin binding.

We have examined the effects of actin mutations on myosin binding, detected by cosedimentation, and actin structural dynamics, detected by spectroscopic probes. Specific mutations were chosen that have been shown to affect the functional interactions of actin and myosin, two mutations (4Ac and E99A/E100A) in the proposed region of weak binding to myosin and one mutation (I341A) in the proposed region of strong binding. In the absence of nucleotide and salt, S1 bound to both wild-type and mutant actins with high affinity (K(d) < microM), but either ADP or increased ionic strength decreased this affinity. This decrease was more pronounced for actins with mutations that inhibit functional interaction with myosin (E99A/E100A and I341A) than for a mutation that enhances the interaction (4Ac). The mutations E99A/E100A and I341A affected the microsecond time scale dynamics of actin in the absence of myosin, but the 4Ac mutation did not have any effect. The binding of myosin eliminated these effects of mutations on structural dynamics; i.e., the spectroscopic signals from mutant actins bound to S1 were the same as those from wild-type actin. These results indicate that mutations in the myosin binding sites affect structural transitions within actin that control strong myosin binding, without affecting the structural dynamics of the strongly bound actomyosin complex.