A photoacoustic calorimetry study of horse carboxymyoglobin on the 10-nanosecond time scale.

The development of a photoacoustic calorimeter with a time resolution of 10 ns is presented, and the dynamics of the enthalpy and volume changes found in the photodissociation of CO from horse carboxymyoglobin are examined. With this enhanced time resolution a new transient species, the lifetime of which is 29 ns at 20 degrees C, is observed in the ligand dissociation process.

Thin-layer microcalorimetric studies of oxygen and carbon monoxide binding to hemoglobin and myoglobin.

A thin-layer gas-solution microcalorimeter has been developed to study the binding reactions of gaseous ligands with ligand binding macromolecules. We have measured the enthalpy of binding oxygen and carbon monoxide to horse myoglobin, human hemoglobin A0 and sperm whale myoglobin in phosphate buffer at pH 7.6, with the enzyme reducing system of Hayashi. Reactions of human hemoglobin were also done under various buffer conditions in order to elucidate the Bohr effect. These binding reactions were found not to exhibit a detectable enthalpy change over the temperature range of 10 degrees C to 25 degrees C. The enzyme reducing system was shown to react with oxygen in a manner that releases a substantial amount of heat. This problem was corrected by using a minimum amount and by placing the buffer and enzyme system in the reference cell effectively cancelling the oxygen enzyme reaction heat as well as the heat of gas dissolution. It was also demonstrated that glucose-6-phosphate, one of the reducing system components, in 50 mM concentrations can influence the heat of binding oxygen and carbon monoxide to hemoglobin. This effect was shown to be absent in the myoglobins and also with hemoglobin at glucose-6-phosphate concentrations less than 5 mM.

Oxygen binding constants and stepwise enthalpies for human and bovine hemoglobin at pH 7.6.

A high-precision thin-layer gas-solution microcalorimeter has been developed to study the binding reactions of gaseous ligands with ligand-binding macromolecules in a manner analogous to that of the Gill thin-layer optical apparatus [Doleman & Gill (1976) Anal. Biochem. 87, 127]. We have generated differential heat-binding curves of oxygen binding to human and bovine hemoglobin in phosphate buffer at pH 7.6, with the enzyme-reducing system of Hayashi et al. [(1973) Biochim. Biophys. Acta 310, 309]. Experiments were conducted at a number of different temperatures in order to expand the data field, allowing for separation of enthalpy and free energy parameters. This type of experimental analysis makes no assumptions of optical linearity between the various heme groups and reveals that the triply ligated species is measurably significant for both human and bovine hemoglobin. It was also determined that the concentration of doubly ligated species of bovine hemoglobin is relatively low. The experiments indicate that the reactions for both hemoglobins are enthalpy-driven for oxygen stepwise additions 1, 2, and 4 while being entropy-driven for step 3. Human hemoglobin oxygen-binding experiments were also performed with the Gill thin-layer optical apparatus under solution conditions identical to those used in the calorimeter. The experiments revealed that if optical linearity is assumed, the overall third equilibrium constant is negative or near zero. This indicated that either the optical cell's performance is much poorer than the thin-layer calorimeter or there is an appreciable nonlinear optical effect.

Eccentric and concentric force-velocity relationships of the quadriceps feimoris muscle.

Most functional activities utilize all three types of muscle contraction. The purpose of this study was to examine concentric and eccentric force-velocity relationships of the knee extensors of 30 young, healthy females at seven velocities between 30 and 210 degrees /sec using the Kinetic Communicator. The average force produced by the quadriceps during three concentric and three eccentric contractions was calculated at each velocity. The force-velocity relationships were graphed and analyzed using linear regression techniques. Results showed that the mean slope of the combined linear regression lines of concentric data was -0.55, which is significantly different from a zero slope. This indicates that concentric force of the knee extensors decreases as velocity increases. The mean slope of the combined linear regression lines of the eccentric data was -0.04, indicating no significant change in eccentric force with an increase in velocity. It appears, therefore, that in the knee extensors of healthy, young females, concentric force decreases as velocity increases to 210 degrees /sec, while eccentric force remains the same. Both concentric and eccentric work are often emphasized in strength training programs. It is, therefore, important for professionals involved in the rehabilitation or training of patients and athletes to be aware of differences between eccentric and concentric force-velocity relationships. J Orthop Sports Phys Ther 1992;16(2):82-86.

Photoacoustic calorimetric study of the conversion of rhodopsin and isorhodopsin to lumirhodopsin.

The enthalpy and volume changes for the conversion of rhodopsin and isorhodopsin to lumirhodopsin have been investigated by time-resolved photoacoustic calorimetry. The conversion of rhodopsin to lumirhodopsin is endothermic by 3.9 +/- 5.9 kcal/mol and is accompanied by an increase in volume of 29.1 +/- 0.8 mL/mol. The lumirhodopsins produced from rhodopsin and isorhodopsin are energetically equivalent.

A photoacoustic calorimetric study of horse myoglobin.

The dynamics of the enthalpy and volume changes for the photodissociation of CO from horse myoglobin has been studied by time-resolved photoacoustic calorimetry which measures the dynamics of enthalpy and volume changes on the nanosecond time scale. The role of the Lys 45 salt bridge in the ligand dissociation is discussed.

Role of the arginine-45 salt bridge in ligand dissociation from sperm whale carboxymyoglobin as probed by photoacoustic calorimetry.

The dynamics of the enthalpy and volume changes found in the photodissociation of CO from sperm whale carboxymyoglobin and two site-directed mutants in which arginine-45 is replaced by glycine and asparagine are examined by photoacoustic calorimetry. An intermediate is observed whose lifetime at 20 degrees C is 700 ns. The enthalpy of the intermediate increases by approximately 7 kcal/mol upon replacing arginine-45 with either asparagine or glycine. These observations support recent proposals that an arginine-45 salt bridge is broken upon ligand dissociation.

Time-resolved photoacoustic calorimetry: probing the energetics and dynamics of fast chemical and biochemical reactions.

Time-resolved photoacoustic calorimetry is a new experimental technique that measures the dynamics of enthalpy changes on the time scale of nanoseconds to microseconds for reactions initiated by absorption of light. When the reaction is carried out in water, it is also possible to obtain the dynamics of the corresponding volume changes. This method has been applied to a variety of biochemical, organic, and organometallic reactions.

A time-resolved photoacoustic calorimetry study of the dynamics of enthalpy and volume changes produced in the photodissociation of carbon monoxide from sperm whale carboxymyoglobin.

The dynamics of the enthalpy and volume changes produced in the photodissociation of carbon monoxide from sperm whale myoglobin is investigated by time-resolved photoacoustic calorimetry. The enthalpy and volume changes for the formation of the geminate pair, which occurs within 50 ns of photolysis, are delta H = -2.2 +/- 2.8 kcal/mol and delta V = -10.0 +/- 1.0 mL/mol relative to carboxymyoglobin. The enthalpy and volume changes associated with formation of deoxymyoglobin and solvated carbon monoxide, formed with a half-life of 702 +/- 31 ns at 20 degrees C, are delta H = 14.6 +/- 3.4 kcal/mol and delta V = 5.8 +/- 1.0 mL/mol relative to carboxymyoglobin.

Picosecond absorption studies on rhodopsin and isorhodopsin in detergent and native membrane.

Picosecond transient absorption spectra of rhodopsin and isorhodopsin were measured at room temperature with a double-beam laser spectrophotometer after excitation at 355 nm. Photolysis studies were performed on rhodopsin solubilized in two different detergents (digitonin and 3-[(3-cholamidopropyl)dimethylammonio]-1-propanesulfonate). The resulting rhodopsin/bathorhodopsin absorption difference spectra were measured at times from 35 ps to 250 ns following photoexcitation. Rhodopsin and isorhodopsin in native disk membrane were studied after suspension in 75% glycerol. Isorhodopsin was prepared by photoisomerizing rhodopsin in disk membrane at 77 K. Transient spectra obtained from the visual pigments in native membrane were of a quality approaching that obtained from detergent-solubilized rhodopsin. The batho intermediate derived from isorhodopsin was spectrally the same as that generated by rhodopsin photolysis and was produced with a quantum yield higher than had been predicted on the basis of other studies.

Primary intermediates in the photochemical cycle of bacteriorhodopsin.

Picosecond studies of the primary photochemical events in the light-adapted bacteriorhodopsin, bR570, indicate that the first metastable intermediate K610 is formed with a rise time of 11 ps. Difference spectra obtained at 50 ps after excitation show that K610 is the same species as that trapped in low temperature glasses. A precursor species (S) of the K610 intermediate has been observed which is red shifted with respect to K610 and is formed within the 6-ps time width of the excitation pulse. The formation of the precursor has no observable thermal dependence between 298 degrees and 1.8 degrees K. The formation of K610 has a very low thermal barrier and at very low temperatures, the rate of formation becomes practically temperature independent which is characteristic of a tunneling process. The rate of formation becomes practically temperature independent which is characteristic of a tunneling process. The rate of formation of K610 has a moderate deuterium isotope effect of kH/kD approximately 1.6 at 298 degrees K and 2.4 at 4 degrees K. The mechanism for formation of K610 is found to involve a rate-limiting proton transfer which occurs by tunneling at low temperatures.