Magnetic circular dichroism studies on acid and alkaline forms of horseradish peroxidase.

The heme vicinities of the acid and alkaline forms of native (Fd(III)) horseradish peroxidase were investigated in terms of the magnetic circular dichroism (MCD) spectroscopy. The MCD spectrum of the acid form of native horseradish peroxidase was characteristic of a ferric high spin heme group. The resemblance in the MCD spectrum between the acid form and acetato-iron (III)protoporphyrin IX dimethyl ester suggests that the heme iron of the acid form has the electronic structure similar to that in a pentocoordinated heme complex. The MCD spectra of native horseradish peroxidase did not shown any substantial pH dependence in the pH range from 5.20 to 9.00. The MCD spectral change indicated the pK value for the equilibrium between the acid and alkaline forms to be 11.0 which agrees with the results from other methods. The alkaline form of native horseradish peroxidase at pH 12.01 exhibited the MCD spectrum of a low spin complex. The near infrared MCD spectrum suggests that the alkaline form of native horseradish peroxidase has a 6th ligand somehow different from a normal nitrogen ligand such as histidine or lysine. It implicates that the alkaline form has an overall ligand field strength of between the low spin component of metmyoglobin hydroxide and metmyoglobin azide.     

Low-temperature magnetic circular dichroism studies of the photoreaction of horseradish peroxidase compound I

Horseradish peroxidase (HRP) compound I is photolabile at all temperatures between room temperature and 4 K. The photoredox reaction has been studied in frozen glassy solutions by using optical absorption and magnetic circular dichroism spectra following photolysis of HRP compound I with visible-wavelength light at 4.2 and 77 K. The photochemical process is characterized as a concerted two-electron transfer reaction which results in the conversion of the Fe(IV) heme pi-cation radical species of HRP compound I into a low-spin Fe(III) heme species. This reaction occurs even when photolysis is carried out at 4.2 K. Spectra recorded between 4.2 and 80 K for the low-spin ferric hydroxide complex of HRP closely resemble the data measured for the photochemical product. The proposed mechanism for the photoreaction is (formula; see text) No evidence is found for the formation of an Fe(II) heme at these temperatures.     

Magnetic circular dichroism studies on the heme and tryptophan components of cytochrome c peroxidase

We have measured the magnetic circular dichroism of cytochrome c peroxidase and some of its derivatives from 250-350 nm. Comparison of the changes observed on conversion to the catalytic intermediate (cytochrome c peroxidase-I) with spectra obtained from horseradish peroxidase and its derivatives and model compounds of protoheme leads us to the conclusion that the observed changes in the magnetic circular dichroism spectra reflect conversion of the heme to the ferryl state. No evidence was found for modification of tryptophan in cytochrome c peroxidase-I.     

Magnetic circular dichroism studies of bovine liver catalase.

Absorption, circular dichroism (CD) and magnetic circular dichroism (MCD) spectra of beef liver catalase at pH 5.0 and 6.9, and its complexes with NaF, KCNO, NaCNS, NaN3 and NaCN, have been measured between 250 nm and 700 nm at room temperature. The pH 6.9 native catalase MCD shows the presence of several additional transitions not resolved in the absorption spectrum. While these bands can be seen in the spectra of all the derivatives, with the exception of the cyanide, their relative intensities changes considerably between complexes. Of special interest in the MCD of ferric hemes is the signal intensity at about 400 nm and 620 nm. The data indicate that the MCD intensity at 620 nm increases as the high spin iron porphyrin fraction increases, reaching a maximum with the fluoride complex. The 430 nm band intensity increases as the proportion of low spin iron increases, reaching a maximum with the cyanide complex. The MCD spectra also indicate clearly the existence of spin mixtures in the complexes with CNO-, CNS-, and N3-, where both the 430 nm and 620 nm bands have appreciable intensity. It is significant that despite almost identical absorption spectra the CNS- complex has higher fraction of low spin iron than either the CNO- or the N3- species. The differences between the pH 5 and 6.9 MCD spectra of the native catalase suggest that the environment of the heme centre is sensitive to protonation.     

Magnetic circular dichroism studies of hepatic microsomal cytochrome P-450.

Magnetic circular dichroism (MCD) spectra have been measured for cytochrome P-450 (P-450) purified from phenobarbital-induced rabbit liver microsomes. The temperature dependence of some of the MCD spectra has also been determined. The MCD spectrum of oxidized P-450 seems to suggest that it is in a state intermediate between the ferric low-spin states. Model experiments suggest that this anomaly arises from the coordination of a thiolate anion to the heme. Reduced P-450 shows a very peculiar MCD spectrum; the spectrum as well as its temperature dependence suggest that the heme in reduced P-450 is a "mixture" in terms of redox and/or spin states. The MCD spectrum of the CO complex of reduced P-450 exhibits an apparent Faraday A term around 450 nm which consists of about 50% C term and 50% the other terms, indicating that it is not in a purely ferrous low-spin state. The CO complex of reduced cytochrome P-420 (P-420), on the other hand, shows an MCD spectrum characteristic of a ferrous low-spin heme. It is suggested from model experiments that the thiolate anion coordinates to the heme trans to CO in the P-450-CO complex. The Soret region of the MCD spectrum of the EtNC complex of reduced P-450 is characterized by two apparent A terms around 430 and 455 nm, whereas that of the corresponding complex of P-420 has only one apparent A term around 434 nm.     

A comparison by magnetic circular dichroism of compound X and compound II of horseradish peroxidase

The chlorite product of horseradish peroxidase, compound X, is shown by magnetic circular dichroism (MCD) spectroscopy in the temperature range 1.6-50 K to have a very similar haem structure to compound II under the same conditions (pH 10.7). Both are concluded to contain the Fe(IV) = 0 group. The MCD spectrum also detects an unusual species, absorbing at wavelengths between 600 and 750 nm, that has magnetic properties different from those of the ferryl haem group. It is suggested that this is a species at the same oxidation level as ferryl haem but with the porphyrin ring having suffered a one-electron oxidation, i.e. [Fe(III) P.+].     

Magnetic circular dichroism studies of myoglobin, hemoglobin and peroxidase at room and low temperatures. Ferrous high spin derivatives.

The magnetic circular dichroism spectra (MCD) recorded for the visible and near-UV regions of high-spin ferrous derivatives of myoglobin, hemoglobin, hemoglobin dimers and isolated chains as well as of horseradish peroxidase at pH 6.8 and 11.4 have been compared at the room and liquid nitrogen temperatures. The MCD of the Q00- and QV-bands have been shown to be sensitive to structural differences in the heme environment of these hemoproteins. The room temperature visible MCD of native hemoglobin differs from that of myoglobin, hemoglobin dimers and isolated chains as well as from that of model pentacoordinated complex. The MCD of hemoglobin is characterized by the greater value of the MCD intensity ratio of derivative shape A-term in the Q00-band to the A-term in the QV-band. The evidneces are presented for the existence of two pH-dependent forms of ferroperoxidase, the neutral peroxidase shows the "hemoglobin-like" MCD, while the alkaline ferroperoxidase is characterized by the "myoglobin-like" MCD spectrum in the visible region. The differences in the MCD of deoxyhemoglobin and neutral ferroperoxidase as compared with other high-spin ferrous hemoproteins are considered to result from the constraints on heme group imposed by quaternary and/or tertiary protein structure. The differences between hemoporteins which are seen at the room temperature become more pronounced at liquid nitrogen temperature. Except the peak at approximately 580 nm in the MCD of deoxymyoglobin and reduced peroxidase at pH 11.4 the visible MCD does not show appreciable temperature dependent C-terms. The nature of the temperature dependent effect at approximately 580 nm is not clear. The Soret MCD of all hemoproteins studied are similar and are predominantly composed of the derivative-shaped C-terms as revealed by the increase of the MCD peaks approximately in accordance with Boltzmann distribution. The interpretation of temperature-dependent MCD observed for the Soret band has been made in terms of porphyrin to Fe-iron charge-transfer electronic transition which may be assigned as b( pi) leads to 3d. This charge-transfer band is strongly overlapped with usual B(pi --pi*) band resulting in diffuse Soret band. Adopting that only two normal vibrations are sinphase with charge-transfer transition the extracted C-terms of the Soret MCD have been fitted by theoretical dispersion curves.     

Magnetic circular dichroism studies of myoglobin,hemoglobin and peroxidase at room and low temperatures. Ferrous high spin derivatives

The magnetic circular dichroism spectra (MCD) recorded for the visible and near-UV regions of high-spin ferrous derivatives of myoglobin, hemoglobin, hemoglobin dimers and isolated chains as well as of horseradish peroxidase at pH 6.8 and 11.4 have been compared at the room and liquid nitrogen temperatures. The MCD of the Q ₀₀- and Q_v-bands have been shown to be sensitive to structural differences in the heme environment of these hemoproteins. The room temperature visible MCD of native hemoglobin differs from that of myoglobin, hemoglobin dimers and isolated chains as well as from that of model pentacoordinated complex. The MCD of hemoglobin is characterized by the greater value of the MCD intensity ratio of derivative shape A-term in the Q ₀₀-band to the A-term in the Q _v-band. The evidences are presented for the existence of two pH-dependent forms of ferroperoxidase, the neutral peroxidase shows the hemoglobin-like MCD, while the alkaline ferroperoxidase is characterized by the myoglobin-like MCD spectrum in the visible region. The differences in the MCD of deoxyhemoglobin and neutral ferroperoxidase as compared with other high-spin ferrous hemoproteins are considered to result from the constraints on heme group imposed by quaternary and/or tertiary protein structure. The differences between hemoproteins which are seen at the room temperature become more pronounced at liquid nitrogen temperature. Except the peak at 580 nm in the MCD of deoxymyoglobin and reduced peroxidase at pH 11.4 the visible MCD does not show appreciable temperature dependent C-terms. The nature of the temperature dependent effect at 580 nm is not clear. The Soret MCD of all hemoproteins studied are similar and are predominantly composed of the derivative-shaped C-terms as revealed by the increase of the MCD peaks approximately in accordance with Boltzmann distribution. The interpretation of temperature-dependent MCD observed for the Soret band has been made in terms of porphyrin to Fe-ion charge-transfer electronic transition which may be assigned as b() 3d. This charge-transfer band is strongly overlapped with usual B( - *) band resulting in diffuse Soret band. Adopting that only two normal vibrations are sinphase with charge-transfer transition the extracted C-terms of the Soret MCD have been fitted by theoretical dispersion curves.     

Magnetic circular dichroism of myoglobin-thiolate complexes.

Various complexes of myoglobin (Mb) with thiolate were studied by use of magnetic circular dichroism (MCD) spectroscopy. 1. MetMb-ethyl, n-propyl and isopropylmercaptan complexes offered MCD spectra similar to that of cytochrome P-450 (P-450) with respect to shape and intensity ratio of Soret MCD to Q0-0 MCD. The MCD spectra did not show any pH dependence. The complexes reduced by sodium dithionite exhibited the MCD spectrum of deoxyMb, indicative of release of thiolate anion from the heme iron. 2. Cysteine and cysteine methyl ester coordinated to the heme iron at pH 9.18 but not at pH 6.86 and 11.45. The complex formed at pH 9.18 gave an MCD spectrum similar to that of P-450, and an MCD spectrum of deoxy Mb on reduction with sodium dithionite. 3. The 2-mercaptoethanol complex exhibited three A terms associated with the Q0-0-1, and Soret transitions at pH 6.86 similar to those of Fe(II) cytochrome c, which indicates that Mb was reduced by this reagent at pH 6.86. At pH 9.18 2-mercaptoethanol gave an MCD spectrum similar to that of alkyl mercaptan just after the addition. With the time changed into deoxy Mb through some intermediate of reduced Mb-thiolate complex. At pH 11.45 2-mercaptoethanol formed complex which exhibited an MCD spectrum similar to those of other alkylmercaptans. 4. Sodium sulfide gave an MCD spectrum which resembled that of the normal thiol Mb complex just after addition at pH 6.86. The complex was gradually reduced to give 610 nm trough in addition to the MCD of deoxy Mb. The Mb-sulfur complex formed at pH 9.18 was gradually reduced to give an MCD spectrum which was fairly different from that of deoxy Mb. A similar MCD spectrum was observed at pH 11.45 just after the addition of Na2S. These results were considered to suggest the saturation of one of the conjugated double bonds of the porphyrin by sulfur.     

EPR studies on compound I of horseradish peroxidase.

Compound I of horseradish peroxidase (donor: hydrogen-peroxide oxidoreductase EC 1.11.1.7) was studied by EPR at low temperatures. An asymmetric signal was found, about 15 Gauss wide and with a g-value of 1.995, which could be detected only at temperatures below 20 K and which had an intensity corresponding to about 1% of the heme content. In a titration with H2O2, the signal intensity was proportional to the concentration of Compound I, reaching a maximum when equivalent amounts of H2O2 were added. This indicates that the signal is not due to an impurity, and it is suggested that a free radical is formed, relaxed by a near-by fast-relaxing iron.     

Conformational studies on parvalbumins by circular dichroism.

Structural variations of two parvalbumins, Whiting III and Pike III, in various denaturing conditions, have been studied by circular dichroism. CD signals are depressed from 4 urea. For Pike III, acidic pH, sodium dodecyl sulfate or complete removal of Ca2+ show little effect in the far ultraviolet region but rather strong effects in the near ultraviolet. For Whiting III similar results are obtained at acidic pH. Carboxymethylated Whiting III (0.15 Ca2+/mol) shows, on the contrary, decreased CD signals in the far and in the near ultraviolet spectra. Addition of Ca2+ fully restores the native CD spectra in both proteins. Ca2+ binding produces structural modifications which are found to vary according to parvalbumin and which seem in any case different from those described for troponin C.     

Magnetic circular dichroism of netropsin and natural circular dichroism of the netropsin-DNA complex

We report the first measurement of the magnetic circular dichroism (MCD) of the basic polypeptide antibiotic netropsin (Nt). The MCD shows that the longest wavelength absorption band of Nt is the sum of more than one component and permits a radically new interpretation of the circular dichroism of the complex which Nt forms with DNA. We conclude that Nt has no major effect on the CD and thus the helical structure of the bases of the DNA to which it is bound. Thus the ability of Nt to inhibit the function of DNA polymerase, RNA polymerase, and the photoreactivating enzyme must be mediated by factors other than a distortion of the helical structure of the bases.     

The horseradish peroxidase technique for cell lineage studies.

The identification of cell lineage for a given cell type of a particular tissue is an important step in understanding how this process contributes to histogenesis. The importance in understanding cell lineage has relevance for both theoretical and practical reasons. For example, delineating and identifying histogenic principals is required to advance stem cell research and tissue regeneration. To document cell lineage in a given experimental preparation, a number of techniques have been developed. This typically requires the injection of a tracer compound into a founder cell. As this cell produces progeny, the tracer is passed on to the daughter cells. By detecting the tracer in the progeny or daughter cells the investigator can determine which cells originated from the cell that was originally injected with the tracer. By using such an approach it is possible to trace the developmental path from the first cells of the embryo to the specialized cells making the tissue of the adult. A number of tracer compounds have been used with good results in lineage tracing. One of these tracer compounds is horseradish peroxidase (HRP). Several variations of the technique are available depending on what species are studied or what histological requirements are made by the study. A basic technique that can be adapted to individual needs is presented. Included in this protocol on lineage tracing are the procedures for injection, fixation, and the microscope evaluation of labelled cells in the Helobdella triseralis embryo. A brief discussion of the technique will note its advantages and disadvantages. Examples of labelled cell preparations are given to illustrate the technique.