Time-resolved optical mammography and its preliminary clinical results.

We have been developing an optical mammography prototype consisting of a multi-channel time-resolved spectroscopy system for breast cancer screening. The system utilizes the time-correlated single photon counting method, and the detector modules and the signal processing circuits were custom-made to obtain a high signal to noise ratio and high temperature stability with a high temporal resolution. Pulsed light generated by a Ti: Sapphire laser was irradiated to the breast, and the transmitted light was collected by optical fibers placed on the surface of a hemispherical gantry filled with an optical matching fluid. To reconstruct a 3D image of the breast, we employed a method using a time-resolved photon path distribution based on the assumption that scattering and absorption are independent of each other. We verified the possibility of human breast imaging by using a three-dimensional phantom model, which provides a simulation of human breast cancer, in the gantry. The clinical study was also started in January 2007. In a comparative study with conventional modalities, the breast cancers were detected as regions of optically higher absorption. Moreover, the results suggest that optical mammography is useful in monitoring the effects of chemotherapy.

Effects of five-tryptophan mutations on structure, stability and function of Escherichia coli dihydrofolate reductase.

To elucidate the roles of tryptophan residues in the structure, stability, and function of Escherichia coli dihydrofolate reductase (DHFR), its five tryptophan residues were replaced by site-directed mutagenesis with leucine, phenylalanine or valine (W22F, W22L, W30L, W47L, W74F, W74L, W133F, and W133V). Far-ultraviolet circular dichroism (CD) spectra of these mutants reveal that exciton coupling between Trp47 and Trp74 strongly affects the peptide CD of wild-type DHFR, and that Trp133 also contributes appreciably. No additivity was observed in the contributions of individual tryptophan residues to the fluorescence spectrum of wild-type DHFR, Trp74 having a dominant effect. These single-tryptophan mutations induce large changes in the free energy of urea unfolding, which showed values of 1.79-7.14 kcal/mol, compared with the value for wild-type DHFR of 6.08 kcal/mol. Analysis of CD and fluorescence spectra suggests that thermal unfolding involves an intermediate with the native-like secondary structure, the disrupted Trp47-Trp74 exciton coupling, and the solvent-exposed Trp30 and Trp47 side chains. All the mutants except W22L (13%) retain more than 50% of the enzyme activity of wild-type DHFR. These results demonstrate that the five tryptophan residues of DHFR play important roles in its structure and stability but do not crucially affect its enzymatic function.

High pressure NMR reveals active-site hinge motion of folate-bound Escherichia coli dihydrofolate reductase.

A high-pressure (15)N/(1)H two-dimensional NMR study has been carried out on folate-bound dihydrofolate reductase (DHFR) from Escherichia coli in the pressure range between 30 and 2000 bar. Several cross-peaks in the (15)N/(1)H HSQC spectrum are split into two with increasing pressure, showing the presence of a second conformer in equilibrium with the first. Thermodynamic analysis of the pressure and temperature dependencies indicates that the second conformer is characterized by a smaller partial molar volume (DeltaV = -25 mL/mol at 15 degrees C) and smaller enthalpy and entropy values, suggesting that the second conformer is more open and hydrated than the first. The splittings of the cross-peaks (by approximately 1 ppm on (15)N axis at 2000 bar) arise from the hinges of the M20 loop, the C-helix, and the F-helix, all of which constitute the major binding site for the cofactor NADPH, suggesting that major differences in conformation occur in the orientations of the NADPH binding units. The Gibbs free energy of the second, open conformer is 5.2 kJ/mol above that of the first at 1 bar, giving an equilibrium population of about 10%. The second, open conformer is considered to be crucial for NADPH binding, and the NMR line width indicates that the upper limit for the rate of opening is 20 s(-)(1) at 2000 bar. These experiments show that high pressure NMR is a generally useful tool for detecting and analyzing "open" structures of a protein that may be directly involved in function.

Single amino acid substitutions in flexible loops can induce large compressibility changes in dihydrofolate reductase.

To address the effects of single amino acid substitutions on the flexibility of Escherichia coli dihydrofolate reductase (DHFR), the partial specific volume (v(o)) and adiabatic compressibility (beta(s)(o)) were determined for a series of mutants with amino acid replacements at Gly67 (7 mutants), Gly121 (6 mutants), and Ala145 (5 mutants) located in three flexible loops, by means of precise sound velocity and density measurements at 15 degrees C. These mutations induced large changes in v(o) (0.710-0.733 cm(3). g(-1)) and beta(s)(o) (-1.8 x 10(-6)-5.5 x 10(-6) bar(-1)) from the corresponding values for the wild-type enzyme (v(o)=0.723 cm(3). g(-1), beta(s)(o) = 1.7 x 10(-6) bar(-1)), probably due to modifications of internal cavities. The beta(s)(o) value increased with increasing v(o), but showed a decreasing tendency with the volume of the amino acid introduced. There was no significant correlation between beta(s)(o) and the overall stability of the mutants determined from urea denaturation experiments. However, a mutant with a large beta(s)(o) value showed high enzyme activity mainly due to an enhanced catalytic reaction rate (k(cat)) and in part due to increased affinity for the substrate (K(m)), despite the fact that the mutation sites are far from the catalytic site. These results demonstrate that the flexibility of the DHFR molecule is dramatically influenced by a single amino acid substitution in one of these loops and that the flexible loops of this protein play important roles in determining the enzyme function.

Acetonitrile-protein interactions: amino acid solubility and preferential solvation.

The solubility of amino acids and the preferential solvent interaction of hen-egg lysozyme in acetonitrile (AN)-water mixtures (<60 w/v% AN) were investigated by means of densimetric and refractometric methods at 25 degreesC. The free energy of transfer from water to aqueous AN was negative for most nonpolar side-chains of amino acids and positive for the peptide group, the extent being comparable to those for methanol and ethanol systems. Addition of AN to an aqueous solvent was thus suggested to weaken the hydrophobic interaction and to enhance the peptide-peptide hydrogen bond therein leading to the denaturation of proteins. A parallel examination by circular dichroism confirmed that the conformation of lysozyme (pH 3) remains native in aqueous AN up to 40% but changes to the helix-rich form at higher AN concentrations. At all solvent compositions up to 50% AN (pH 3), however, lysozyme was preferentially hydrated probably due to a local salting-out of the AN molecules from the charges on the protein surface, indicating the increase of the chemical potential of the protein. These results are discussed in relation to the role of AN as an eluting organic solvent in reverse-phase chromatography.

Effects of point mutations at the flexible loop alanine-145 of Escherichia coli dihydrofolate reductase on its stability and function.

To elucidate the role of a flexible loop (residues 142-149) in the stability and function of Escherichia coli dihydrofolate reductase, alanine-145 in this loop was substituted by site-directed mutagenesis with ten amino acids (Glu, Phe, Gly, His, Ile, Leu, Arg, Ser, Thr, and Val). The amount of three mutant proteins (A145E, A145I, and A145L) in cells was too small to allow the measurement of circular dichroism (CD) spectra and urea unfolding. The CD spectra of other seven mutants were identical with those of the wild-type DHFR, indicating that the native conformation of DHFR was not affected by the mutations. The free energy change of unfolding by urea decreased with an increase in the hydrophobicity of amino acid residues introduced, A145T>A145R>A145G>=A145S>=A145H>A145V++ +>wild-type>=A145F. The steady-state kinetic parameters for the enzyme reaction, Km and ksub, were only slightly influenced by the mutations. These results suggest that site 145 in the flexible loop plays an important role in the stability but has little or no effect on the native structure and function of this enzyme. The characteristics of the mutations are discussed in comparison with those of mutations at site 67 [Ohmae et al. (1996) J. Biochem. 119, 703-710] and at site 121 [Gekko et al. (1994) J. Biochem. 116, 34-41] in two other flexible loops.

Nonadditive effects of double mutations at the flexible loops, glycine-67 and glycine-121, of Escherichia coli dihydrofolate reductase on its stability and function.

The structure, stability, and enzymatic function of dihydrofolate reductase (DHFR) from Escherichia coli are influenced by point mutations at sites 67 and 121 in two flexible loops [Gekko et al. (1994) J. Biochem. 116, 34-41; Ohmae et al. (1996) J. Biochem. 119, 703-710]. In the present study, eight double mutants at sites 67 and 121 (G67V/G121S, G67V/G121A, G67V/G121C, G67V/G121D, G67V/G121V, G67V/G121H, G67V/G121L, and G67V/G121Y) were constructed in order to identify interactions between the two sites of DHFR. The far-ultraviolet circular dichroism spectra of double mutants were clearly different from those of the respective single mutants, with significant changes being observed for three mutants, G67V/G121A, G67V/G121L, and G67V/G121S. The Gibbs free energy change of urea unfolding of double mutants could not be expressed by the sum of those of the respective single mutants except for G67V/G121H. The steady-state kinetic experiments showed that the effect of double mutations manifests itself not in Km but in k(cat), and the transition-state stabilization energy for G67V/G121A, G67V/G121C, and G67V/G121L is not equal to the sum of those for the single mutants. These results indicate that the additivity rule essentially does not hold for these double mutants, and that long-range interactions occur between sites 67 and 121, even though they are separated by 27.7 A. This is evidence that the flexible loops play important roles in the stability and function of this enzyme through structural perturbations, in which a small alteration in local atomic packing due to amino acid substitution is cooperatively magnified over almost the whole molecule.

Remyelination in the rat dorsal funiculus following demyelination by laser irradiation.

Excimer laser (KrF excimer laser, 248 nm wavelength) was used to damage cellular components in the dorsal funiculus at the lumbar level (L2) of the rat spinal cord. An open lesion was not found at the irradiation site on the spinal cord. However, the cytological examination revealed that cellular components were damaged to the depth of 200-500 microm from the pial surface. The characteristic feature was that at the border of the lesion, many axons remained naked but intact after their myelin sheaths had been completely disintegrated. Such naked axons were subsequently remyelinated by mature or immature glial cells. Mature oligodendrocytes, while retaining their cytoplasmic processes connected with the myelin sheaths of unaffected axons, extended new cytoplasmic processes on nearby naked axons and made new myelin sheaths around them. In contrast, 7 days after the irradiation, numerous immature glial cells appeared in association with naked axons, and some of them were differentiated into oligodendrocytes forming thin myelin sheaths on naked axons. These findings suggest that demyelinated axons can cause the proliferation and probably dedifferentiation of the oligodendrocyte lineage. The use of lasers provides a unique experimental model of demyelination and remyelination in the central nervous system of adult mammals.

Acid and thermal unfolding of Escherichia coli dihydrofolate reductase.

The acid and thermal unfolding of Escherichia coli dihydrofolate reductase (DHFR) were studied by means of circular dichroism (CD) and fluorescence spectroscopy. There existed at least one intermediate around pH 4 in the acid unfolding process at 15 degrees C, in which the tertiary structure was disrupted before unfolding of the secondary structure. The fluorescence energy transfer from intrinsic tryptophan residues to 1-anilinonaphthalene-8-sulfonate suggested the disruption of the tertiary structure around some tryptophan residues of the intermediate. The thermal unfolding process at pH 7.0 also involved at least one intermediate having a disrupted tertiary structure and a folded secondary structure. The three-state thermodynamic analysis showed that the intermediate in thermal unfolding was less stable by 1.8 kcal/mol than the native state. The similarity of the far-ultraviolet CD spectra of acid and thermally unfolded forms suggests that both types of unfolding produce the same structure, which may be a molten globule intermediate such as that in the folding kinetics of DHFR. The acid and thermal unfolding were depressed in the presence of KCl due to stabilization of the native form.

Effects of point mutations at the flexible loop glycine-67 of Escherichia coli dihydrofolate reductase on its stability and function.

To elucidate the role of a flexible loop (residues 64-72) in the stability and function of Escherichia coli dihydrofolate reductase, glycine-67 in this loop was substituted by site-directed mutagenesis with seven amino acids (Ala, Cys, Asp, Leu, Ser, Thr, and Val). The circular dichroism spectra suggested that the confirmation of the native structure was affected by the mutations in both the presence and absence of NADPH. The free energy change of unfolding by urea decreased in the order of G67A > G67S > or = wild-type > or = G67D > G67T > G67C > or = G67L > G67V. The steady-state kinetic parameters for the enzyme reaction, Km and kcat, were only slightly influenced, but the rate of the hydride transfer reaction was significantly changed by the mutations, as revealed by the deuterium isotope effect on the enzyme activity. These results suggest that site 67 in the flexible loop, being very far from the active site, plays an important role in the stability and function of this enzyme. The characteristics of the mutations were discussed in terms of the modified flexibility of the native structure, compared with the results of mutations at site 121 in another flexible loop.

A large compressibility change of protein induced by a single amino acid substitution.

The adiabatic compressibility (beta s) was determined, by means of the precise sound velocity and density measurements, for a series of single amino acid substituted mutant enzymes of Escherichia coli dihydrofolate reductase (DHFR) and aspartate aminotransferase (AspAT). Interestingly, the beta s values of both DHFR and AspAT were influenced markedly by the mutations at glycine-121 and valine-39, respectively, in which the magnitude of the change was proportional to the enzyme activity. This result demonstrates that the local change of the primary structure plays an important role in atomic packing and protein dynamics, which leads to the modified stability and enzymatic function. This is the first report on the compressibility of mutant proteins.