Differential scanning calorimetric investigation of pea chloroplast thylakoids and thylakoid fractions.

High sensitivity differential scanning calorimetry (DSC) was employed to study the thermal denaturation of components of pea chloroplast thylakoid membranes. In contrast to previous reports utilizing spinach thylakoids, several transitions are reversible, and deconvolution of the calorimetric curves indicates nine transitions in both first and second heating scans, but overlapping transitions obscure at least three transitions in the first heating scans of control thylakoids. Glutaraldehyde fixation increases the denaturation temperature of several transitions which is consistent with a reported increase in thermal stability of thylakoid function due to fixation. Acidic pH treatment has little effect on the DSC curves, although it has been reported to have a significant effect on membrane structure. Separation of grana from stroma thylakoids indicates that components responsible for transitions centered at approximately 56, 73, 77, and 91 degrees C are predominantly or exclusively associated with grana thylakoids, whereas components responsible for transitions centered at approximately 63 and 81 degrees C are predominantly associated with stroma thylakoids. A broad transition centered at 66 degrees C is associated with grana thylakoids, whereas a sharp transition at the same temperature is due to a component associated with stroma thylakoids. Evidence obtained by washing treatments suggests the latter transition originates from the denaturation of the thylakoid ATPase (CF1). Analysis of the calorimetric enthalpy values indicates most components of the grana thylakoids denature irreversibly at high temperature, whereas components associated with the stroma thylakoids have a considerable degree of thermal reversibility.

Intercalation binding of 6-substituted naphthothiopheneamides to DNA: enthalpy and entropy components.

N-(3-dimethylaminopropyl)naphtho[2,1-b]thiophene-4-carboxamide and the 6-substituted methoxy, methyl, fluoro, chloro, bromo, trifluoromethyl, and cyano derivatives have been shown to bind to DNA via intercalation with binding constants in the 35-900 X 10(3) range at 25 degrees C, pH 7, and [Na+] = 0.019M. Both electron-donating and -withdrawing substituents enhance intercalation binding, but the binding affinity is most enhanced by the cyano substituent. Calorimetric titrations for calf thymus DNA differ dramatically from those reported for ethidium [Hopkins et al. (1990) Biopolymers Vol. 29, pp. 449-459]. Apparent enthalpy parameters (delta HB) for intercalation are constant only at low coverage of sites and become much more positive as saturation is approached. In the plateau region, delta HB values for the parent and the cyano-, fluoro-, chloro-, and bromo-substituted compounds are nearly the same (approximately -5.9 kcal/mol). For the methyl- (-6.8 kcal/mol) and methoxy- (-7.5 kcal/mol) substituted compounds, the delta HB values are more exothermic than that for the unsubstituted compound, whereas delta HB for the trifluoromethyl compound is approximately 1 kcal/mol less exothermic. The corresponding delta SB values, corrected for mixing effects, are in the 7-15-cal/deg/mol range and are approximately linearly related to delta HB if the cyano derivative is excluded.

Effect of growth temperature on folding of carbamoylphosphate synthetases of Salmonella typhimurium and a cold-sensitive derivative.

The properties of homogeneous preparations of carbamoylphosphate synthetase (CPSase) from wild-type Salmonella typhimurium and a cold-sensitive derivative grown at different growth temperatures were examined. For the cold-sensitive mutant, the affinity for glutamine of the form of CPSase synthesized at 20 degrees C was lower than that of the form of the enzyme synthesized at 37 degrees C, regardless of the assay temperature. Thus, the cold sensitivity of the mutant reflects an effect of temperature on the synthesis of the enzyme rather than the activity of the folded enzyme. The two forms also differed in sensitivities to polyclonal antibodies as well as denaturational enthalpies. The combined results support the hypothesis that carAB mutations conferring cold sensitivity identify amino acid residues that are critical in the folding of CPSase. Quite unexpectedly, certain kinetic properties of cloned parent CPSase were also dependent on the growth temperature, although to a much lesser extent than those of the cold-sensitive mutant. The specific activity of wild-type CPSase synthesized at 15 degrees C was 60% of that synthesized at 37 degrees C. Further, CPSase synthesized at 15 degrees C was less thermostable than the enzyme synthesized at 37 degrees C; the difference in stability (delta G) is estimated to be 4,500 cal mol-1. Thus, variation of temperature within the physiological range for growth influences the folding and consequently the properties of CPSase from wild-type S. typhimurium.

NMR, calorimetric, spin-label, and optical studies on a trifluoromethyl-substituted styryl molecular probe in dimyristoylphosphatidylcholine vesicles and multilamellar suspensions: a model for location of optical probes.

NMR, calorimetric, and optical spectroscopic studies have been performed on a trifluoromethyl-substituted styryl molecular probe bound to vesicles and multilamellar suspensions formed from dimyristoylphosphatidylcholine (DMPC). In the fluorine NMR spectrum at 35 degrees C there are two partially resolved resonances, but these collapse to an apparently single resonance at temperatures above 60 degrees C. However, a line-shape analysis is not consistent with exchange between two sites on an NMR time scale, and the two resonances are assumed to be due to probe sites in the inner and outer leaflets of the vesicles. Two fluorescence lifetimes, each associated with one of these sites, characterize the decay curves for the molecular probe bound to DMPC vesicles. The shift reagent Eu(FOD)3 and several nitroxide spin labels covalently bound to lipophilic structures strongly attenuate the lower frequency component of the fluorine NMR spectrum and also shift the other resonance to higher frequencies. The effect of two spin labels on the probe fluorine T2 relaxation time has been used to estimate the distance between the spin label unpaired electron and the trifluoromethyl group. The location of the spin label site in the membrane was determined from the effect of the unpaired electron on the lipid 13C linewidths. A model for the location of the probe in the bilayer was developed from the above information and refined using molecular mechanics calculations on a probe-DMPC lipid complex. The long axis of the probe parallels the bilayer normal; the styryl-group portion of the optical chromophore is located slightly below the glycerol backbone, and the remainder of the chromophore extends well into the hydrophobic region of the bilayer. Therefore, the optical properties of the probe should not be significantly influenced by alterations of the membrane surface charge density. Parameters derived from DSC studies in the gel-to-lipid crystal phase transition of DMPC are extremely sensitive to the probe. Even at 0.0001 mol fraction of probe, the transition is substantially broadened, and the delta H for the transition has increased, just as one predicts for the formation of a tight complex described above.

Temperature dependence of enthalpy changes for ethidium and propidium binding to DNA: effect of alkylamine chains.

Calorimetric titrations have been performed on the binding of ethidium and propidium to calf thymus DNA at temperatures in the 15-60 degrees C range. Enthalpy changes (delta HB) derived from these experiments performed with the new Omega reaction calorimeter have a precision of +/- 0.10 kcal/mol or less at all temperatures. For ethidium (a monocation), delta HB varies little with temperature, and the heat capacity change (delta CP) for the binding reaction derived from these parameters is 10 cal/deg/mol. In contrast, delta HB changes from -6.5 to -8.1 kcal/mol for DNA binding of propidium (a dication due to a charged amine group at the end of an alkyl chain attached to the phenanthridine ring nitrogen), and delta CP is -57 cal/deg/mol. At 21 degrees C a plot of delta HB vs mole ratio is curved downward for propidium in the 0.08-0.25 range, whereas the same plot at 45 degrees C is a straight line from 0.05 to 0.15 and sharply downward thereafter. Similar plots for ethidium follow the latter pattern between 25 and 50 degrees C. These observations and our analyses of delta HB and delta SB are consistent with the hypothesis that the location in the DNA complex and the rotational motion of the alkylamine chain change substantially over the temperature range in this study. Only near 50 degrees C is delta HB equal for the binding of these two cations to DNA, and caution must be used in analyses of enthalpic effects when the temperature dependence for delta HB is not available.

The effect of potential-sensitive molecular probes on the thermal phase transition in dimyristoylphosphatidylcholine preparations.

Differential scanning calorimetry (DSC) has been employed to determine the effect of five commonly employed extrinsic potential-sensitive probes on phase transitions of multilamellar suspensions of L-alpha-dimyristoylphosphatidylcholine (DMPC). At mol% values of less than five, the effect of these probes on the excess heat capacity curve in the vicinity of the gel to liquid crystal phase transition can be described by an equation based on the formation of ideal solutions in both phases. Even at up to 4 mol%, these dyes only moderately reduce the enthalpy change associated with this transition, but cause a marked decrease in the size of the cooperative unit parameter. The excess heat capacity profile for diS-C3-(5) is represented by the ideal solution equation, even at 12 mol%, whereas the suspensions with the other probes present at this level have profiles covering large temperature ranges. Multiple peaks appear at the higher levels for the negatively charged oxonols V and VI, and merocyanine 540, a result consistent with the presence of well-defined microdomains or even phase separation. The enthalpy change associated with the transition near 15 degrees C involving packing in the headgroup region is decreased significantly, indicating that the probes probably affect the lipid headgroup conformation, even at low levels. The cyanine probe diS-C3-(5) causes the heat capacity profile of small unilamellar vesicles to be transformed very rapidly into one similar to that of the vortexed lipid preparations, presumably by a dye-mediated vesicle fusion process, enhanced by the surface location of this probe. All our results are consistent with diS-C3-(5) being located on the surface of the bilayer in both phases, but a penetration of the other probes into the hydrocarbon region, at least in the liquid crystal phase.

Error analysis in titration microcalorimetry of biochemical systems.

A simplified method for titrations of biochemical systems is described as well as extensive error propagation through the data analysis. This work uses a Tronac Model 450 isoperibol titration calorimeter. Sample volumes of 2 ml are used and total heats of less than 5 mcal can be routinely measured. The binding of 3'-CMP to bovine pancreatic ribonuclease A is used to illustrate the methods. The binding enthalpy can be determined with a standard deviation of 1.5% and the free energy with a standard deviation of 2 to 3%.

An optimized differential heat conduction solution microcalorimeter for thermal kinetic measurements.

Heat conduction calorimeters are widely used in the biological sciences, but baseline instability, low resolution, electrical noise and motion artifacts have limited their utility. Two main sources of noise, baseline fluctuation or drift and a motion artifact, were traced to amplifier drift, a small (0.015 degrees C) gradient within the constant temperature cylinder, and the method of installing the thermopiles. The addition of heaters to the top and bottom of the cylinder reduced the gradient to approximately 0.003 degrees C and greatly reduced the slow component of the motion artifact. The drift error was reduced by proper mounting of the amplifier and its external components and the enclosure of the calorimeter in a temperature-controlled box. An R-C model of the heat flow in the calorimeter was developed which was employed to discover several means of increasing sensitivity without increasing the rise-time of the calorimeter. Analysis, also based on the model, showed that variations in the air gap between the cell and cell holder can be a major source of error when the calorimeter is used to investigate the kinetics of a chemical reaction. This analysis also showed that the time for the heat to flow through the solution in the cell can be the dominant factor in determining the rise-time of the instrument. The heat conduction calorimeter described here has improved characteristics: a baseline stability of 200 nJ x s-1 (peak-to-peak) over a 48 h period; a resolution of 200 nJ x s-1; a sensitivity of 6.504 +/- 0.045 J x V-1 x s-1 referred to the sensor output; and a rise-time of 122 s for the 10-90% response.