Stepwise reduction of cytochromes b-562, b-566 and b-558 in rat liver mitochondria.

1. Addition of KCN to aerobic, rotenone-inhibited rat liver mitochondria with out addition of substrate caused reduction of cytochromes b-562 (having an alpha-band at 562 nm at room temperature), c + c1, and a + a3. The effect of KCN on cytochrome b-562 was reversed by pentachlorophenol, though the effect of KCN on cytochromes c+c1 and a+a3 was not reversed by this uncoupler.2. Addition of ATP to aerobic, rat liver mitochondria inhibited with 500 muM KCN under conditions were cytochromes b-562, c+c1 and a+a3 were reduced, caused reduction of cytochrome b-566. The absorbance spectrum of cytochrome b-566 had an alpha-band at 565.5 nm, a beta-band at 538 nm and a gamma-band at 431 nm, but no shoulder around 558 nm at room temperature. 3. Addition of succinate to rotenone-KCN-inhibited and ATP-treated rat liver mitochondria under conditions where cytochromes b-566, b-562, c+c1 and a+a3 were already fully reduced, caused reduction of cytochrome b-558 (having an alpha-band at 558 nm, a beta-band at 527 nm and a gamma-band at 426 nm at room temperature) after exhaustion of molecular oxygen in the reaction medium, without any contribution from a long-wavelength species (cytochrome b-566). 4. It was concluded that the 558-nm band is not a short-wavelength shoulder of cytochrome b-566, but is due to a different species from cytochrome b-566.     

Occurrence of cytochrome aa3 in Anacystis nidulans

The cytochrome content of membrane fragments prepared from the bluegreen alga (cyanobacterium) Anacystis nidulans was examined by difference spectrophotometry. Two b-type cytochromes and a hitherto unknown cytochrome a could be characterized. In the reduced-minus-oxidised difference spectra the a-type cytochrome showed an α-band at 605 nm and a γ-band at 445 nm. These bands shifted to 590 and 430 nm, respectively, in CO difference spectra. NADPH, NADH and ascorbate reduced the cytochrome through added horse heart cytochrome c as electron mediator. In presence of KCN the reduced-minus-oxidised spectrum showed a peak at 600 nm and a trough at 604 nm. Photoaction spectra of O₂ uptake and of horse heart cytochrome c oxidation by CO-inhibited membranes showed peaks at 590 and 430 nm. These findings are consistent with cytochrome aa₃ being the predominant respiratory cytochrome c oxidase in Anacystis nidulans.     

Effect of pH on cytochromes b in ATP-Mg submitochondrial particles

Addition of ATP to anaerobic, succinate-reduced phosphorylating submitochondrial particles (ATP-Mg particles) causes reduction of cytochromes b absorbing at 558 and 566 nm in the pH range 5.5–9.0. The extent of the reduction of both cytochromes induced by ATP is maximal at pH 7.4–7.5. On the other hand, addition of ATP to anaerobic, NADH-reduced particles causes oxidation of b₅₆₂ at high pH, while it causes reduction of cytochromes absorbing at 558 and 566 nm at low pH. The optimal pH for the oxidation of cytochromes b is in the region 8.5–9.0. Partial reduction of the cytochromes absorbing at 558 and 566 nm can be brought about non-energetically by lowering the potential of the substrate redox couple or by making the reaction mixture alkaline. Addition of the electron-transfer mediator, phenazine methosulphate, to anaerobic, NADH-reduced particles causes complete reduction of cytochromes b absorbing at 558 and 566 nm in the pH range 5.5–9.0. The findings are interpreted in terms of a pH-induced removal of an accessibility barrier (structural or kinetic) that interferes with the redox equilibrium between NADH and cytochrome b.     

Optical measurements of intracellular oxygen concentration of rat heart in vitro

The optical characteristics of hemoglobin-free perfused rat heart have been examined in detail. Ethyl hydrogen peroxide is found to convert myoglobin into “ferryl compound” in the perfused heart, as is also seen in vitro. After pretreatment with ethyl hydrogen peroxide, a typical mitochondrial absorption spectrum, similar to that of isolated rat heart mitochondria, is obtained in perfused heart. The overall absorption spectrum of the heart obtained by the aerobic to anaerobic transition is a superposition of the mitochondrial spectrum on that of myoglobin. By comparing these spectra, it is found that measurement of cytochrome a + a₃ at 605–620 nm is possible in spite of the absorbance change due to the oxygenation-deoxygenation of myoglobin, whereas the wavelength pairs for cytochrome c at 550-540 nm, cytochrome b at 562–575 nm and cytochrome a + a₃ at 445–450 nm can not be used in the heart because of interference from the absorption change of myoglobin. The partial pressure of O₂ (P₅₀) which is required for half maximal deoxygenation (or oxygenation) of myoglobin in perfused heart is found to be 2.4 mm Hg at room temperature and the Hill constant, n, is 1.1; these values are similar to those of myoglobin purified from rat heart. The steady-state O₂ titration has been performed by using absorbancy changes of myoglobin and cytochrome a + a₃ as intracellular O₂ indicators. In the perfused heart, the percentage change of oxygenation-deoxygenation of myoglobin parallels the oxidation-reduction of cytochrome a + a₃, while the mixture of purified myoglobin and isolated mitochondria shows a deviation, reflecting the difference of O₂ affinities between myoglobin and cytochrome a + a₃. The results indicate that there may be an O₂ gradient between cytosolic and mitochondrial compartments in the hemoglobin-free perfused heart. The absorption changes of myoglobin and of cytochrome a + a₃ can be measured in a single contraction-relaxation cycle. A triple beam method was introduced to eliminate the effect of light scattering changes in these measurements. The results demonstrated that myoglobin is more oxygenated during the systolic and diastolic periods and deoxygenated in the resting period, whereas cytochrome a + a₃ is more reduced in systole and diastole and oxidized in the resting state. Changing the perfusion conditions greatly alters the time course of the events which occur during the contraction-relaxation cycle of the perfused heart.     

The respiratory chain of Paramecium tetraurelia in wild type and the mutant Cl1 I. Spectral properties and redox potentials

1. Purified mitochondria have been prepared from wild type Paramecium tetraurelia and from the mutant Cl₁ which lacks cytochrome aa₃. Both mitochondrial preparations are characterized by cyanide insensitivity. Their spectral properties and their redox potentials have been studied.2. Difference spectra (dithionite reduced minus oxidized) of mitochondria from wild type P. tetraurelia at 77 K revealed the α peaks of b-type cytochrome(s) at 553 and 557 nm, of c-type cytochrome at 549 nm and a-type cytochrome at 608 nm. Two α peaks at 549 and 545 nm could be distinguished in the isolated cytochrome c at 77 K. After cytochrome c extraction from wild type mitochondria, a new peak at 551 nm was unmasked, probably belonging to cytochrome c₁. The a-type cytochrome was characterized by a split Soret band with maxima at 441 and 450 nm. The mitochondria of the mutant Cl₁ in exponential phase of growth differed from the wild type mitochondria in that cytochrome aa₃ was absent while twice the quantity of cytochrome b was present. In stationary phase, mitochondria of the mutant were characterized by a new absorption peak at 590 nm.3. Cytochrome aa₃ was present at a concentration of 0.3 nmol/mg protein in wild type mitochondria and ubiquinone at a concentration of 8 nmol/mg protein both in mitochondria of the wild type and the mutant Cl₁. Cytochrome aa₃ was more susceptible to heat than cytochromes b and c,c₁.4. CO difference spectra at 77 K revealed two different Co-cytochrome complexes. The first, found only in wild type mitochondria, was a typical CO-cytochrome a₃ complex characterized by peaks at 596 and 435 nm and troughs at 613 and 450 nm. The second, found both in mitochondria of the wild type and the mutant, was a CO-cytochrome b complex with peaks at 567, 539 and 420 nm and a trough at 558-549 nm. Both complexes are photo-dissociable.5. Spectral evidence was obtained for interaction of cyanide with the a-type cytochrome (shift of the α peak at 77 K from 608 to 605 nm), but not with the b-type cytochrome.6. The mid-point potentials of the different cytochromes at neutral pH are as follows: cytochrome aa₃ 235 and 395 mV, cytochrome c,c₁ 233 mV, cytochromes b 120 mV.     

The cytochromes of mitochondria from Tetrahymena pyriformis strain ST

1. Mitochondria of the obligately aerobic ciliate protozoon, Tetrahymena pyriformis strain ST, are unusual in that they possess a cytochrome oxidase system that does not react with reduced mammalian cytochrome c; the presence of cytochromes a₆₀₃+a₃ is masked in the α-band region of spectra by the broad absorption band of cytochrome a₆₂₀. 2. Other haemoproteins present include cytochromes b₅₆₀, b₅₅₆, c₅₅₃ and c₅₄₉. 3. The reaction of reduced cytochrome a₃ with CO is reversed by flash photolysis, and in the presence of O₂ the subsequent oxidation of this cytochrome is followed by that of cytochrome a₆₀₃. 4. Cytochromes a₆₂₀ and b₅₆₀ also react with CO and with KCN; the latter cytochrome corresponds with that designated cytochrome o by other workers. 5. The contribution of cytochrome a₆₀₃ to difference spectra is revealed by making use of the fact that it does not react with KCN. 6. Cytochrome a₆₂₀ is unstable, and its α-absorption band is lost from spectra of mitochondria which have been aged or treated with ultrasound, detergents or organic solvents. 7. Possible pathways of electron transport via the several different terminal oxidases in Tetrahymena mitochondria are proposed.     

Reducibility of cytochromes b in aerobic beef-heart mitochondria treated with antimycin

Under anaerobic conditions cytochrome b in beef-heart mitochondria is partially reduced in the presence of NADH, whereas other cytochromes are completely reduced. Addition of antimycin together with oxygen under these conditions causes an immediate reduction of cytochromes b-558, b-562 and b-566 and oxidation of cytochrome c. During the subsequent transient aerobic steady state cytochromes b-558 and b-566 are rapidly re-oxidized without changes in redox state of cytochrome c, but cytochrome b-562 remains reduced. When oxygen is consumed by the leak through or around the antimycin-inhibition site, cytochrome b-562 becomes oxidized with concomitant reduction of cytochrome c.

The cytochromes b in lyophilized beef-heart mitochondria are more readily accessible to electrons from NADH, and in the presence of antimycin and NADH a complete and stable reduction is obtained under both aerobic and anaerobic conditions. Gradual addition of rotenone under these conditions causes re-oxidation of cytochromes b in which oxidation of cytochromes b-558 and b-566 precedes that of cytochrome b-562.

It is concluded that (1) the effect of antimycin in the presence of oxygen involves all three cytochromes b, (2) the reducibility of the cytochromes b in the aerobic steady state of antimycin-treated mitochondria is dependent upon the potential of the substrate redox couple registered on the cytochromes, and (3) the midpoint potential of cytochrome b-562 in the presence of antimycin is higher than that of cytochrome b-558 or b-566.     

Spectral study of b cytochromes in yeast mitochondria and intact cells

Three types of b cytochromes are demonstrated in Candida utilis mitochondria. One of these b cytochromes has a symmetrical -band at 561.5 nm at room temperature. This b cytochrome is readily reduced either by anaerobiosis or by cyanide treatment in the presence of glycerol 1-phosphate or succinate both in coupled and uncoupled mitochondria. The second b cytochrome has a double -band at 565 nm and 558 nm. This b cytochrome is readily reduced either by anaerobiosis or by cyanide treatment in the presence of glycerol 1-phosphate or succinate in coupled mitochondria, but in uncoupled mitochondria it is slowly reduced after anaerobiosis and this reduction rate is enhanced by antimycin A addition. Thus the oxidation-reduction state of this cytochrome is energy dependent. The first cytochrome is spectroscopically identified as cytochrome b_K and the second as cytochrome b_T. The third b cytochrome has an -band around 563 nm (b₅₆₃) and is reduced slowly after anaerobiosis in uncoupled mitochondria but faster than the b_T. Further properties of this component are not known. Midpoint potentials of cytochromes b_T, b₅₆₃ and b_K are approximately −50 mV, +5 mV, and +65 mV, respectively.

In intact cells, cytochrome b_T is reduced immediately after anaerobiosis or cyanide treatment, and rapidly oxidized when uncoupler is added. Addition of antimycin A instead of uncoupler to the anaerobic cells causes oxidation of mainly cytochrome b_T while addition of antimycin A to the aerobic cells results in a reduction of the cytochrome b_T.     

Characterization of cytochrome b in the isolated ubiquinol-cytochrome c2 oxidoreductase from Rhodopseudomonas sphaeroides GA

Extinction coefficients for cytochrome b and c₁ in the isolated cytochrome bc₁ complex from Rhodopseudomonas sphaeroides GA have been determined. They are 25 mM^?1.cm^?1 at 561 nm for cytochrome b and 17.4 mM^?1.cm^?1 at 553 nM for cytochrome c₁ for the difference between the reduced and the oxidized state. Cytochrome b is present in two forms in the complex. One form has an E_m7 of 50 mV, an α-peak of 557 nm at liquid N₂ temperature and of 561 nm at RT, which is red-shifted by antimycin A. The other form has an E_m7 of ?90 mV, a double α-peak of 555 and 561 nm at liquid N₂ temperature corresponding to 559 and 566 nm at RT. The absorption at 566 nm is red-shifted by myxothiazol. The two shifts are independent of each other. Both midpoint potentials of cytochromes b are pH-dependent. The redox center compositions of the cytochrome bc₁ complexes from Rhodopseudomonas sphaeroides and from mitochondria are identical.     

Measurement of cytochromes in human skeletal muscle mitochondria,isolated from fresh and frozen stored muscle specimens

Mitochondria were isolated from small muscle biopsy specimens, and the cytochrome content was calculated from the reduced minus oxidized difference spectrum recorded at room temperature.From the difference spectra obtained after reduction of the cytochromes with dithionite it is concluded that human mitochondrial suspensions are contaminated with hemoglobin or myoglobin.The cytochrome content calculated after reduction of the cytochromes with succinate plus KCN is lower than that obtained after reduction with dithionite, indicating incomplete reduction of the cytochromes by the former method.Storage of muscle tissue at −70°C before isolation of mitochondria results in a loss of cytochrome c + c₁ from these mitochondria.     

A method for in situ characterization of b- and c-type cytochromes in Escherichia coli and in Complex III from beef heart mitochondria by combined spectrum deconvolution and potentiometric analysis

An analytical technique for the in situ characterization of b- and c-type cytochromes has been developed. From evaluation of the results of potentiometric measurements and spectrum deconvolutions, it was concluded that an integrated best-fit analysis of potentiometric and spectral data gave the most reliable results. In the total cytochrome b content of cytoplasmic membranes from aerobically grown Escherichia coli, four major components are distinguished with α-band maxima at 77 K of 555.7, 556.7, 558.6 and 563.5 nm, and midpoint potentials at pH 7.0 of 46, 174, ?75 and 187 mV, respectively. In addition, two very small contributions to the α-band spectrum at 547.0 and 560.2 nm, with midpoint potentials of 71 and 169 mV, respectively, have been distinguished. On the basis of their spectral properties they should be designated as a cytochrome c and a cytochrome b, respectively. In Complex III, isolated from beef heart mitochondria, five cytochromes are distinguished: cytochrome c₁ (Λ_m(25°C) = 553.5 nm; E′₀ = 238 mV) and four cytochromes bΛ_m(25°C) = 558.6, 561.2, 562.1, 566.1 nm and E′₀ = ?83, 26, 85, ?60 mV).     

Potential role of subunit c of F0F1-ATPase and subunit c of storage body in the mitochondrial permeability transition. Effect of the phosphorylation status of subunit c on pore opening

Phosphorylated and non-phosphorylated forms of the F₀F₁-ATPase subunit c from rat liver mitochondria (RLM) were purified and their effect on the opening of the permeability transition pore (mPTP) was investigated. Addition of dephosphorylated subunit c to RLM induced mitochondrial swelling, decreased the membrane potential and reduced the Ca²⁺ uptake capacity, which was prevented by cyclosporin A. The same effect was observed in the presence of storage subunit c purified from livers of sheep affected with ceroid lipofuscinosis. In black-lipid bilayer membranes subunit c increased the conductance due to formation of single channels with fast and slow kinetics. The dephosphorylated subunit c formed channels with slow kinetics, i.e. the open state being of significantly longer duration than in the case of channels formed by the phosphorylated form that had short life spans and fast kinetics. The channels formed were cation-selective more so with the phosphorylated form. Subunit c of rat liver mitochondria was able to bind Ca²⁺. Collectively, the data allowed us to suppose that subunit c F₀F₁-ATPase might be a structural/regulatory component of mPTP exerting its role in dependence on phosphorylation status.     

The EPR spectrum of isolated Complex III

It has been found that antimycin shifts the EPR signal of oxidized Complex III at g = 3.44 (ferricytochrome b-562) to g = 3.48, while the signal at g = 3.8 (ferricytochrome b-566) sharpens. Antimycin also affects the optical spectrum of ferricytochrome b by sharpening the α-band and splitting the γ-band. It is shown that nitric oxide reacts irreversibly with the non-heme iron components of Complex III. A reaction of NO with ferrocytochrome b-566 is suggested, resulting in lines at g = 2.10, 2.07 and 2.01.     

Reconstruction of absolute absorption spectrum of reduced heme a in cytochrome c oxidase from bovine heart

This paper presents a new experimental approach for determining the individual optical characteristics of reduced heme a in bovine heart cytochrome c oxidase starting from a small selective shift of the heme a absorption spectrum induced by calcium ions. The difference spectrum induced by Ca²⁺ corresponds actually to a first derivative (differential) of the heme a ²⁺ absolute absorption spectrum. Such an absolute spectrum was obtained for the mixed-valence cyanide complex of cytochrome oxidase (a ²⁺ a ₃ ³⁺ -CN) and was subsequently used as a basis spectrum for further procession and modeling. The individual absorption spectrum of the reduced heme a in the Soret region was reconstructed as the integral of the difference spectrum induced by addition of Ca²⁺. The spectrum of heme a ²⁺ in the Soret region obtained in this way is characterized by a peak with a maximum at 447 nm and half-width of 17 nm and can be decomposed into two Gaussians with maxima at 442 and 451 nm and half-widths of ～10 nm (589 cm^?1) corresponding to the perpendicularly oriented electronic π→π* transitions B _0x and B _0y in the porphyrin ring. The reconstructed spectrum in the Soret band differs significantly from the “classical” absorption spectrum of heme a ²⁺ originally described by Vanneste (Vanneste, W. H. (1966) Biochemistry, 65, 838–848). The differences indicate that the overall γ-band of heme a ²⁺ in cytochrome oxidase contains in addition to the B _0x and B _0y transitions extra components that are not sensitive to calcium ions, or, alternatively, that the Vanneste’s spectrum of heme a ²⁺ contains significant contribution from heme a ₃ ²⁺ . The reconstructed absorption band of heme a ²⁺ in the α-band with maximum at 605 nm and half-width of 18 nm (850 cm^?1) corresponds most likely to the individual Q _0y transition of heme a, whereas the Q _0x transition contributes only weakly to the spectrum.     

Inhibition of Respiration in Prototheca zopfii by Light

Irradiation of cells of Prototheca zopfii with blue light inhibited the respiratory capacity of the cells. The inhibition of respiration was correlated with a photodestruction of cytochrome c(551), cytochrome b(559), and cytochrome a₃. Cytochrome c(549), cytochrome b(555), and cytochrome b(564) were unaffected by the irradiation treatment. The α-band of reduced cytochrome a was shifted from 599 to 603 nm by irradiation, an effect similar to that observed when methanol was added to nonirradiated cells. The presence of oxygen was required during irradiation for both photoinhibition of respiration and photodestruction of the cytochromes. Cytochrome a₃ was protected against photodestruction by cyanide. Photodestruction of these same cytochromes also occurred when washed mitochondria of P. zopfii were irradiated.     

The interaction between heme and protein in cytochrome c1

The optical spectrum of reduced bovine cytochrome c₁ at 77 K shows a fine splitting of the β-band, which is indicative of the native conformation of the protein. At room temperature, this conformation is reflected in an absorbance band at 530 nm. The exposure of the heme of ferrocytochrome c₁, investigated by means of solvent-perturbation spectroscopy, appears to be extremely sensitive to temperature and SH reagents bound to the oxidized protein. Addition of combinations of potential ligands to the isolated tryptic heme peptide of cytochrome c₁ reveals that only a mixture of methionine and cysteine (or their equivalents) generates a β-band at 77 K which is identical in shape to that of native cytochrome c₁. In the EPR spectrum of a complex of ferrocytochrome c₁ and nitric oxide at pH 10.5, no hyperfine splitting derived from a second ligated nitrogen atom could be detected. The results indicate that methionine and cysteine are the axial ligands of heme in cytochrome c₁. The EPR spectrum of isolated ferricytochrome c₁ is that of a low-spin heme iron compound with a g_z value of 3.36 and a g_y value of 2.04.     

Cytochromes of plant plasma membranes. Characterization by absorbance difference spectrophotometry and redox titration

The cytochrome composition of plasma membranes (PM) obtained by phase partitioning of microsomal fractions from spinach leaves (Spinacea oleracea L. cv. Medania), cauliflower inflorescences (Brassica oleracea L.), sugar beer leaves (Beta vulgaris L.) and barley (Hordeum vulgare L. cv. Kristina) roots and leaves was characterized by absorbance difference spectrophotometry at different reducing conditions at 20 and – 196°C, by redox titration, and by heme staining of polypeptide bands after lithium dodecyl sulfate polyacrylamide gel electrophoresis (LDS-PAGE). The location of the α-bands in the difference spectra and the loss of heme after treatment with LDS indicated that predominantly cytochromes of the b-type were present in all species tested. The total concentration of cytochrome was ca 0.35 nmol (mg protein)^?1. The main component (ca 70% of total) was completely reduced by ascorbate and partly by NADH and had a midpoint potential of ca 150 mV. At – 196°C, ascorbate reduction revealed a symmetrical α-band at ca 557 nm with PM from spinach leaves, cauliflower and sugar beet leaves, but with barley root and leaf PM ascorbate reduction resulted in an asymmetrical α-band (shoulder at 552, maximum at 559 nm). In the dithionite-reduced minus ascorbate-reduced spectrum at –196°C a split α-band (552 + 558 nm) was seen with PM from all species. This minor component had a midpoint potential of ca – 50 mV and is probably identical to cytochrome b₅, the presence of which would explain the relatively high NADH-cytochrome c reductase activities observed with plant PM. With PM from cauliflower, CO-difference spectra indicated that cytochromes P-420 and P-450 were present at concentrations up to 0.06 and 0.03 nmol (mg protein)^?1, respectively. Visualization of cytochromes by heme staining after LDS-PAGE was complicated by endogenous peroxidase activity and by loss of heme during solubilisation. A presumptive b-cytochrome (heme-stained band at 94 kDa) was only detected with barley leaf PM.     

Phyllospadine,a New Flavonoidal Alkaloid from the Sea-Grass Phyllosphadix iwatensis

Attempts to solubilize active ubiquinol: cytochrome c reductase, cytochrome b-c₁ complex, from the submitochondrial particles from sweet potato root tissue ended in failure because all detergents tested caused inactivation of this enzyme complex. Consequently, the complex was isolated with the content of cytochrome b as the marker for purification after solubilization with deoxycholate though it was inactive. Deoxycholate had no effect on two ±-bands at 555 and 558 nm but caused a blue shift of an ±-band at 563 nm in the reduced-minus-oxidized difference spectrum of the submitochondrial particles at low temperature. The purified complex exhibited the same difference spectra at low and room temperatures as the submitochondrial particles in the presence of deoxycholate, which suggests that the complex has three (at least two) cytochrome b components with different spectroscopic properties and that the apparent molar ratio of cytochrome b to c₁ is 1.5. The purified complex consisted of eight subunits: I, 51 kDa; II, 49kDa; III, 33kDa; IV, 32 kDa; V, 27 kDa; VI, 17 kDa; and VII and VIII, 10 kDa. Subunits III and IV were cytochrome c₁ and b, respectively.     

Stable alterations in HeLa cell mitochondria following ethidium bromide treatment

This study describes the isolation of three HeLa cell clones after exposure of HeLa cells to ethidium bromide (EB) in culture medium for either 14 days, or 14 days plusreexposure for 30 days. All three EB-induced clones differed from the parental HeLa cell in various physical properties of their mitochondria. The ratio of mitochondrial DNA component I to component II was altered in clone HeLa-2A. In addition, the cytochrome content of the respiratory chain a + a₃, b and C₁ decreased, while the cytochroms c content remained unchanged. The amount of cytochromes b and c₁; which were not reduced by KCN treatment, but were reduced by dithionite, increased in clone HeLa-2A. The ultrastructure of HeLa-2A cells revealed several alterations characteristic of EB treatment. Some mitochondria had enlarged profiles, a reduced number of cristae and a more lucent electron density of the matrix. Other mitochondria were tightly packed with cristae, which occasionally showed a whorled configuration. These changes were observed 4 months (20–25 passages) after the omission of EB from the medium.