Nuclear deoxyribonucleic acid polymerase. Further observations on the structure and properties of the enzyme from human KB cells.

At low ionic strength KB cell DNA polymerase N1 forms large aggregates of a size comparable to those of DNA polymerase C. However, in contrast to polymerase C, the polymerase N1 aggregate: (a) retains the distinctive features of the polymerase N1 monomer, specifically its relative insensitivity to salt and to p-hydroxymercuribenzoate, and its pI of 9.3; and (b) is quantitatively converted to the polymerase N1 monomer form at appropriate ionic strength. It is important to recognize that since both polymerase N1 and polymerase C undergo salt-dependent association-dissociation reactions, attempts to distinguish these clearly indedependent polymerase species on the basis of size criteria can be very misleading. This is particularly true in relatively impure enzyme fractions that are generally isolated from eukaryotic tissue sources in low ionic strength buffers. We had earlier reported (Wang, T. S.-F., Sedwick, W. D., and Korn, D. (1974) J. Biol. Chem. 249,841-850; Sedwick, W. D., Wang, T. S.-F., and Korn, D. (1972) J. Biol. Chem. 247,5026-5033; Sedwick, W. D., Wang, T. S.-F., and Korn, D. (1974) Methods Enzymol. 29, 89-102) that DNA polymerase N1 could not utilize homoribopolymer templates. We have re-examined this question with a modified and more stringent method of product assay, and we show here that a greater than or equal 95% homogeneous preparation of polymerase N1 can copy the primer-template (A)n-(dT)-/16 at about one-half the rate that it copies activated DNA under optimum incubation conditions.     

Initiation of Bacillus subtilis Ribonucleic Acid Polymerase on Deoxyribonucleic Acid from Bacteriophages 2C, φ29, T4, and Lambda

Ribonucleic acid (RNA) synthesis primed by bacteriophage T4 or lambda deoxyribonucleic acid (DNA) with Bacillus subtilis RNA polymerase is severely inhibited by high ionic strength. In contrast, RNA synthesis on B. subtilis bacteriophage 2C, SPO1, or phi29 DNA is only moderately affected under similar conditions. The basis of this inhibition lies in the inability of the enzyme to initiate RNA chains with adenosine triphosphate or guanosine triphosphate (ATP, GTP). Binding to templates and the rate of catalysis in high salt after initiation do not seem to be affected. Incorporation of gamma-(32)P-ATP and GTP under a variety of conditions suggests that the specificity of B. subtilis RNA polymerase is different from that of the Escherichia coli enzyme and that it recognizes few promoters on T4 and lambda DNA. Although B. subtilis RNA polymerase initiates RNA chains primarily with ATP or GTP, initiations with pyrimidines can occur on DNA molecules in which hydroxymethyluracil replaces thymine. RNA synthesis on denatured DNA does not seem to be inhibited by high ionic strength, and on native T4 or lambda DNA the inhibition of initiation at constant ionic strength is inversely but not linearly proportional to the ionic radii of cations used to stabilize bihelical DNA to denaturation.     

Studies of the binding of Escherichia coli RNA polymerase to DNA. V. T7 RNA chain initiation by enzyme-DNA complexes

Initiation of T7 RNA chains by Escherichia coli RNA polymerase-T7 DNA complexes has been followed using incorporation of λ-³²P-labeled ATP and GTP to determine the relation between the enzyme binding sites and RNA chain initiation sites on the T7 genome. If the period of RNA synthesis is limited to less than two minutes, the stoichiometry of RNA chain initiation can be measured in the absence of chain termination and re-initiation. About 70% of the RNA polymerase holoenzyme molecules in current enzyme preparations are able to rapidly initiate a T7 RNA chain. The ratio of ATP- to GTP-initiated T7 RNA chains is not altered by variations in the number of enzyme molecules added per DNA, nor by alterations in the ionic conditions employed for RNA synthesis. This suggests that RNA chain initiation sites are chosen randomly through binding of RNA polymerase to tight (class A) binding sites on T7 DNA.     

W-reactivation of phage lambda in recF, recL, uvrA, and uvrB mutants of E. coli K-12.

Summary Assay conditions are described which permit detection of cryptic temperature sensitive RNA polymerases in vitro. RNA polymerase was prepared from fifteen different temperature sensitive mutants of Salmonella typhimurium chosen at random from a larger group isolated by localized mutagenesis and uridine suicide techniques. The dependence of enzyme activity on temperature, ionic strength and pH was studied in vitro. Assays at higher ionic strength (0.23 M) and temperature (50°C) distinguish three classes of mutants (Table 2). Activity of seven mutant RNA polymerases (called Class 1) under these conditions was 1% to 5% that of the parental RNA polymerase. Five mutant RNA polymerases (called Class 2) had 18% to 64% of the parental activity and three were not distinguishable from the parental enzyme under these conditions. Mixing experiments showed that the defect in Class 1 mutant enzymes is a property of the enzymes and not due to a diffusible inhibitor. In one case the lesion was shown to reside in the core enzyme. Class 1 mutant RNA polymerases were shown to be irreversibly inactivated during the assay at higher temperature and ionic strength. This suggests that the Class 1 enzymes may be more thermolabile than the wild type enzyme or may fail to be protected from thermal denaturation by formation of a ternary complex with template and product. We conclude that the method used to isolate these mutants (Young et al., 1976) and the assay described here (Table 2) are efficient ways to isolate and detect temperature sensitive RNA polymerase mutants of Salmonella typhimurium.     

Correlation between hysteresis and allosteric properties for phosphofructokinase from Ascaris suum

The Ascaris suum phosphofructokinase exhibits hysteretic transitions in the time course for fructose 6-phosphate (F6P) phosphorylation in addition to allosteric properties when assayed at pH values below 8. Conditions that enhance hysteretic changes also enhance cooperative interactions and thus there appears to be a link between hysteresis and cooperativity. Initiation of reaction with either F6P or phosphofructokinase results in a pronounced lag, while initiation of the reaction with MgATP results in a burst at pH values below 8. Under conditions in which a lag is evident, increasing the concentration of F6P in the assay decreases the lag, while under conditions where a burst is evident, increasing the concentration of MgATP in the assay decreases the burst. The lag is enzyme-dependent going to a limiting value at high enzyme concentration, while the burst is enzyme-independent. As the pH increases, the Hill coefficient for F6P decreases from a pH-independent value of 3 at low pH to a value of 1 above pH 8. Over the same pH range, the burst rate increases to a point that it is too fast to measure at pH 8 (that is, the time course is linear). Finally, at pH 6.9, the saturation curve for F6P becomes more cooperative with the Hill coefficient equal to 3 above 4 mM MgATP. Data are interpreted in terms of the model suggested for the rabbit skeletal muscle phosphofructokinase (Frieden, C., Gilbert, H. R., and Bock, P.E. (1976) J. Biol. Chem. 251, 5644-5647) in which MgATP binds preferably to an inactive tetrameric enzyme form in which a group with a pK of 6.8 is protonated and F6P binds preferably to the unprotonated active tetrameric form.     

Temperature and ionic strength dependence of the subunit interactions in vertebrate skeletal myosin. A comparison of the interaction between the alkali light and heavy chains of mammalian and avian myosin

The stability of the interaction of A1 in myosin and subfragment 1 isolated from fast-twitch mammalian and avian muscles with respect to temperature and ionic strength has been examined. This was done by determining the extent of exchange of the endogenous free A1 light chain into these proteins from the two species. Whereas the extent of exchange at 37 degrees C into mammalian S1, occurring after 60 min, is about 80% of the theoretically expected amount at physiological ionic conditions, the level of exchange observed with the avian S1 is significantly lower. However, close to the theoretical limit is observed for the avian S1 when exchange is done at 43 degrees C which is close to average avian body temperature. A similar dependence with temperature is observed in the case of exchanges into avian myosin. In the case of mammalian myosin, 50% of the theoretical exchange is observed at 37 degrees C under physiological ionic strength, whereas the level of exchange observed under these conditions with the avian protein is much lower in agreement with recent observations (Waller, G. S., and Lowey, S. (1985) J. Biol. Chem. 260, 14368-14373; Pastra-Landis, S. C., and Lowey, S. (1986) J. Biol. Chem. 261, 14811-14816). If, however, the exchanges are done at 43 degrees C in physiological ionic strength, significant extents of exchange can be observed in avian myosin. These results suggest that at physiological ionic and temperature conditions relevant for the source of myosin and S1 being investigated, the alkali light chains are in dynamic equilibrium between free and heavy chain associated states. Therefore, the failure to observe alkali light chain exchange in avian myosin at 37 degrees C appears to be related to the higher temperature stability of its interaction with the heavy chain.     

Mechanism of the conformational transition of melittin.

It is known that, while melittin at micromolar concentrations is unfolded under conditions of low ionic strength at neutral pH, it adopts a tetrameric alpha-helical structure under conditions of high ionic strength, at alkaline pH, or at high peptide concentrations. To understand the mechanism of the conformational transition of melittin, we examined in detail the conformation of melittin under various conditions by far-UV circular dichroism at 20 degrees C. We found that the helical conformation is also stabilized by strong acids such as perchloric acid. The effects of various acids varied largely and were similar to those of the corresponding salts, indicating that the anions are responsible for the salt- or acid-induced transitions. The order of effectiveness of various monovalent anions was consistent with the electroselectivity series of anions toward anion-exchange resins, indicating that the anion binding is responsible for the salt- or acid-induced transitions. From the NaCl-, HCl-, and alkaline pH-induced conformational transitions, we constructed a phase diagram of the anion- and pH-dependent conformational transition. The phase diagram was similar in shape to that of acid-denatured apomyoglobin [Goto, Y., & Fink, A.L. (1990) J. Mol. Biol. 214, 803-805] or that of the amphiphilic Lys, Leu model polypeptide [Goto, Y., & Aimoto, S. (1991) J. Mol. Biol. 218, 387-396], suggesting a common mechanism of the conformational transition. The anion-, pH-, and peptide concentration-dependent conformational transition of melittin was explained on the basis of an equation in which the conformational transition is linked to proton and anion binding to the titratable groups.