Abstract
Cytochrome c (Cytc) is a multifunctional protein, acting as an electron carrier in the electron transport chain (ETC), where it shuttles electrons from bc1 complex to cytochrome c oxidase (COX), and as a trigger of type II apoptosis when released from the mitochondria. We previously showed that Cytc is regulated in a highly tissue-specific manner: Cytc isolated from heart, liver, and kidney is phosphorylated on Y97, Y48, and T28, respectively. Here, we have analyzed the effect of a new Cytc phosphorylation site, threonine 58, which we mapped in rat kidney Cytc by mass spectrometry. We generated and overexpressed wild-type, phosphomimetic T58E, and two controls, T58A and T58I Cytc; the latter replacement is found in human and testis-specific Cytc. In vitro, COX activity, caspase-3 activity, and heme degradation in the presence of H2O2 were decreased with phosphomimetic Cytc compared to wild-type. Cytc-knockout cells expressing T58E or T58I Cytc showed a reduction in intact cell respiration, mitochondrial membrane potential (∆Ψm), ROS production, and apoptotic activity compared to wild-type. We propose that, under physiological conditions, Cytc is phosphorylated, which controls mitochondrial respiration and apoptosis. Under conditions of stress Cytc phosphorylations are lost leading to maximal respiration rates, ∆Ψm hyperpolarization, ROS production, and apoptosis.
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Introduction
Cytochrome c (Cytc) is a small, globular nuclear-encoded protein with a covalently attached heme group. It is located at the mitochondrial intermembrane space (IMS) as a mobile single electron carrier between Complexes III (bc1 complex) and IV (cytochrome c oxidase, COX) of the electron transport chain (ETC). Cytc null mice die at midgestation1 when energy metabolism switches from mainly glycolytic to mainly aerobic2, indicating that Cytc is an essential protein for the development of organisms and indispensable for mitochondrial ATP production. In addition to functioning in mitochondrial respiration, under stress conditions Cytc serves as a proapoptotic signal3. Upon its release from the mitochondria into the cytosol, Cytc interacts with apoptotic protease-activating factor 1 (Apaf-1) to form the apoptosome, leading to activation of caspase-9 and the downstream caspase cascade3,4. Beyond these two major functions, Cytc acts as a peroxidase that oxidizes the mitochondrial membrane lipid cardiolipin at earlier stages of apoptosis, thus promoting Cytc release from the IMS into the cytosol5. In addition, Cytc can function as both a reactive oxygen species (ROS) scavenger and producer via reduction of p66shc, a protein involved in ROS generation and apoptosis6. Furthermore, Cytc serves as the electron acceptor in the Erv1-Mia40 redox relay system involved in mitochondrial IMS protein import7.
Considering the multiple functions that Cytc plays in different pathophysiological conditions, it is imperative that Cytc is tightly regulated. Earlier, the study of regulatory mechanisms of Cytc mainly focused on allosteric regulation by binding of ATP and the expressions of the tissue-specific (somatic and testis) isoforms in mammals8,9. Recently, a novel regulatory mechanism has emerged, and we reported that Cytc can be phosphorylated in a tissue-specific manner, which appears to be physiologically relevant because the majority of the Cytc pool was found to be modified when the protein was purified under conditions preserving the physiological phosphorylation status (reviewed in10). Under basal physiological conditions, Cytc was phosphorylated on Y97 in heart, Y48 in liver, and T28 in kidney11,12,13. Phosphorylation of T28 and S47 was also found in skeletal muscle14,15. These phosphorylations can be lost under stressed conditions, such as ischemia. Functional studies showed that phosphorylation or phosphomimetic substitution of Cytc T28, Y48, and Y97 leads to a partial inhibition of respiration and reduced mitochondrial membrane potential (ΔΨm) levels and ROS production11,12,13. We then proposed that this mechanism maintains optimal intermediate ΔΨm levels for efficient ATP generation but limits ROS production, which occurs at pathologically high ΔΨm levels10.
Interestingly, those phosphorylated or phosphomimetic Cytc species have different effects on caspase activation. For example, Y48E abolishes the capacity of triggering apoptosis and fully protects against caspase activation whereas T28E has no such effect13,16. Therefore, phosphorylations at different sites exert distinct effects on the regulation of Cytc functions to meet tissue-specific energy needs and regulation of apoptosis.
Based on our previous studies we have proposed a model in which the activity of the ETC is controlled by phosphorylations of Cytc under normal conditions, thus preventing ΔΨm hyperpolarization and subsequent excessive ROS production that causes apoptosis. We here characterize a new phosphorylation of Cytc on T58 that we found in rat kidney tissue under normal conditions, suggesting that it plays a biological role. Additionally, previous research concluded that this site is important for the binding of cardiolipin to Cytc17. Therefore, we hypothesized that T58 phosphorylation may cause structural and functional changes. To further test our hypothesis and model, we analyzed the effects of this new Cytc phosphorylation site. In vitro, phosphomimetic T58E substitution causes an inhibition of respiration in the reaction with COX and reduced downstream caspase-3 activity. In a cell culture model, introduction of phosphomimetic T58E and WT Cytc into Cytc knockout cells revealed that phosphomimetic substitution leads to reduced intact cell respiration, ΔΨm, and ROS production. Moreover, this substitution protects the cells from apoptosis when challenged with hydrogen peroxide (H2O2) or staurosporine. These data suggest that Cytc phosphorylation on T58 regulates the overall flux of the ETC, preventing ΔΨm hyperpolarization and subsequent excessive ROS production that causes apoptosis10.
Results
Rat kidney cytochrome c is phosphorylated on threonine 58
We purified Cytc from kidney tissue under conditions preserving physiological phosphorylations. Previously, we reported T28 phosphorylation of Cytc purified from kidney13, an organ that heavily relies on aerobic energy metabolism. Surprisingly, mass spectrometric analysis revealed a new phosphorylation site, on T58, in two out of five independent kidney preparations (Fig. 1), while T28 was identified in all of them. The T58 residue is conserved in the somatic Cytc isoform of mammals but is replaced with an isoleucine in the testis isoform.
Overexpression and purification of functional cytochrome c variants in E. coli cells
To study the effect of T58 phosphorylation in vitro we generated T58E phosphomimetic Cytc. Phosphomimetic amino acid replacement can functionally mimic protein phosphorylation and be used to model the functional effects of fully phosphorylated proteins18,19. We and others have applied this approach to Cytc by replacing phosphorylatable Cytc residues with the negatively charged amino acid glutamate, which produced similar functional effects as in vivo-phosphorylated Cytc13,16,20. We therefore constructed mouse Cytc expression plasmids for WT and three mutants, including phosphomimetic T58E, and T58A as a non-phosphorylatable control. We also generated T58I Cytc as an additional control because the isoleucine residue is found at this position in the testis isoform of mammals that express two isoforms of Cytc. Furthermore, isoleucine is present in Cytc of humans that lack tissue-specific isoforms and only express a single Cytc. To obtain sufficient amounts of the proteins, we overexpressed these variants in E. coli C41 (DE3) cells. The Coomassie blue stained gel shows that Cytc variants were purified to homogeneity (Fig. 2A) with a spectral ratio of the 410 nm/280 nm peaks greater than 416.
Cytochrome c oxidase activity is decreased in the reaction with phosphomimetic cytochrome c
Our previous studies showed that Y48E and T28E phosphomimetic Cytc displayed an ~30% and 50% reduction, respectively, in the reaction with isolated bovine liver COX at maximal turnover similar to the reaction with Y48 and T28 phosphorylated Cytc, suggesting that the replacement with glutamate is an ideal phosphomimetic model13,16. To understand if T58E, located at a different site, has a similar effect, we first performed polarography experiments to analyze the activities of the Cytc variants in the reaction with purified cow liver COX. COX was isolated as a regulatory-competent enzyme under conditions preserving its in vivo phosphorylation status21. As shown in Fig. 2B, the oxygen consumption rates of T58E and T58I were reduced by 45% and 25% compared to the WT Cytc whereas T58A showed no significant change. The apparent Km values of the Cytc variants in the reactions with COX were 3.0, 3.0, 4.5, and 2.5 µM for WT, T58E, T58A, and T58I Cytc, respectively.
Caspase-3 activity is reduced with phosphomimetic cytochrome c
To test the effect of T58E on apoptosis, we analyzed the ability of Cytc variants to initiate apoptosis using a cell-free caspase-3 assay. The Cytc variants were incubated with cytosolic extracts from Cytc knockout embryonic fibroblasts1. We assessed downstream caspase-3 activation by measuring fluorescence intensity produced after cleavage of the artificial caspase-3 substrate DEVD conjugated with rhodamine. Interestingly, all the Cytc mutants displayed reduced caspase-3 activity, by about 70%, 50%, and 60% for T58E, T58A, and T58I Cytc compared to WT (Fig. 2C), suggesting lower levels of apoptosome formation in the presence of the mutants.
Phosphomimetic cytochrome c displays similar thermal stability to WT cytochrome c
To determine the thermal stability of T58 variants of Cytc, the recombinant proteins were gradually heated to undergo denaturation in the presence of SYPRO Orange dye, which interacts with hydrophobic regions of the protein that become exposed upon denaturation. The hydrophobic regions increase fluorescence emission of the dye resulting in a fluorescence readout for thermal denaturation of the protein22. The first melting temperature (Tm) for WT, T58A, T58E, and T58I were 55.7 ± 0.3, 54.4 ± 1.1, 56.4 ± 0.9, and 91.5 ± 0.2 °C, respectively. WT, T58A, and T58E Cytc showed second melting temperatures (Tm2) of 91.2 ± 0.1, 91.5 ± 0.4, and 91.4 ± 0.5 °C, respectively (Supplementary Fig. 1). T58I displayed only one melting temperature whereas the other variants displayed two, suggesting that different domains of WT and T58E Cytc have varying melting temperatures resulting in a step-wise unfolding. The results confirm that the T58I Cytc replacement observed in the testis isoform of Cytc and human Cytc stabilizes the protein. These results are consistent with the heme degradation studies (see below), which also suggest that T58I is the most stable Cytc variant.
Phosphomimetic cytochrome c displays lower redox potential and lower oxidation and higher reduction rates and is partially resistant to heme degradation by hydrogen peroxide
The redox midpoint potential of native Cytc is between that of Complex III and Complex IV, allowing efficient electron transfer during respiration. The reported midpoint potential values for Cytc are in the range of 220–270 mV. To determine the tendency of the Cytc mutants to acquire electrons, redox potentials for WT, T58A, T58E, and T58I Cytc were measured using the equilibration method. The redox potentials of the Cytc variants were in a similar range from 209 mV (T58E) to 227 mV (WT) as shown in Fig. 3A.
Cytc also functions as a ROS scavenger. Therefore, we were interested in understanding if the phosphomimetic substitution (T58E) exhibits a different behavior in reaction with an oxidant (H2O2) or a reductant (ascorbate). We analyzed oxidation rates of ferro-(Fe2+)-Cytc variants in the presence of 100 µM H2O2 and reduction rates of ferri-(Fe3+)-Cytc variants in the presence of 200 µM ascorbate. Interestingly, T58E Cytc displayed a 50% lower oxidation rate and a 50% higher reduction rate compared to WT Cytc whereas both rates of oxidation and reduction of the T58I mutant were similar to those of WT and the T58A mutant (Fig. 3B,C).
Next, we tested resistance of the fully oxidized or reduced Cytc variants to a high load of H2O2. Due to oxidative modifications including M80 oxidation, lysine carbonylation, tyrosine crosslinking, and others23, Cytc can become dysfunctional and the heme group degraded, which can be monitored by measuring the spectrum of Cytc showing a decrease in the absorption of the heme Soret band at 408 nm present in intact Cytc. When challenged with excessive H2O2 (3 mM), T58E showed increased resistance to degradation (Fig. 3D,E). Interestingly, T58I Cytc was even more resistant than phosphomimetic Cytc. Both mutants also demonstrated a stronger antioxidative ability than WT and T58A Cytc whereas the T58A mutant was most susceptible to rapid degradation.
Peroxidase activity is lower in phosphomimetic cytochrome c
Native Cytc has a low degree of peroxidase activity, which increases with the increased ratios of CL to Cytc. Amplex red oxidation to resorufin was used to monitor the cardiolipin peroxidase activity of Cytc. When incubated with liposomes containing a larger percentage of cardiolipin (30 and 50%), T58E Cytc demonstrated a reduced cardiolipin peroxidase activity compared to WT (Fig. 3F), similar to that of T28E Cytc13. Interestingly, T58I also showed lower peroxidase activity at the higher percentages of cardiolipin, suggesting that changes at residue 58 affect peroxidase activity of Cytc.
Mitochondrial respiration is partially inhibited in intact cells stably expressing phosphomimetic cytochrome c
To test the effect of phosphomimetic substitution of T58 on mitochondrial respiration in intact cells, Cytc double knockout mouse embryonic fibroblasts were used to generate stable cell lines expressing Cytc variants (the mouse and rat somatic Cytc protein sequences are identical). Both somatic and testis Cytc were knocked out to ensure that the lack of the somatic isoform does not induce the expression of the testis isoform and restore mitochondrial respiration24. We chose stable cell line clones with equivalent expression levels of each Cytc variant (Fig. 4A) and analyzed intact cell respiration using a Seahorse bioanalyzer. If the reaction between Cytc and COX is rate-limiting, reduced respiration rates seen in vitro should translate into reduced oxygen consumption rates in intact cells. Cell lines stably expressing T58E and T58I Cytc displayed 68% and 25% reduced respiration rates, respectively (Fig. 4B), which is consistent with the results obtained with purified COX in vitro (Fig. 2B). T58A Cytc-mediated respiration rate was between WT and T58E (Fig. 4B). In addition, ATP levels were reduced by 65%, 66%, and 36% for cells expressing T58A, T58E, and T58I, respectively (Fig. 4C).
Mitochondrial membrane potential and ROS production are decreased in cells expressing phosphomimetic cytochrome c
Since a decreased mitochondrial respiration rate was observed in intact cells after phosphomimetic substitution of T58, we hypothesized that this should translate into a reduction of the mitochondrial membrane potential (ΔΨm). We measured ΔΨm using JC-1, a voltage-dependent probe, and found that the ΔΨm was indeed reduced in T58E and T58I Cytc-expressing cells, as indicated by ~50% and 30% decreased JC-1 fluorescence (Fig. 4D), which matches the pattern of the corresponding respiration rates. As membrane potential determines mitochondrial ROS production, we measured ROS levels in the mitochondria of our Cytc variant-expressing cells using MitoSOX, a mitochondrial ROS indicator. We found that the ROS levels were also reduced, as shown by 70% and 60% decrease in fluorescence in T58E and T58I Cytc-expressing cells, respectively (Fig. 4E).
H2O2- or staurosporine-induced apoptosis is decreased in cells expressing phosphomimetic cytochrome c
Our in vitro data showed that phosphomimetic T58E Cytc was able to trigger activation of caspase-3 but to a much lower extent compared to WT Cytc in the cell-free detection system. To confirm that this “controlled” caspase-3 activation by phosphomimetic T58 Cytc can occur in intact cells, we analyzed apoptosis induced with either H2O2 or staurosporine for all Cytc mutants using the empty vector and WT cells as controls. Consistently, phosphomimetic substitution of Cytc T58 resulted in a significant decrease in the rates of both H2O2- (Fig. 5A,B) and staurosporine-induced apoptosis and necrosis (Fig. 5C,D). As expected, cells transfected with empty vector displayed much lower rates of cell death compared to WT due to absence of Cytc.
Molecular dynamics simulations suggest structural and functional differences of the T58 variants
To explore possible differences of the Cytc T58 variants in their solution structures, molecular dynamics simulations were performed using the A chain from WT Cytc13 or the modeled mutated variants as well as a model of phosphorylated Cytc with the phosphate group added to T58 in the WT molecule A using COOT (PDB code Tpo58). In all five simulations of the amino acid side chains, the final solution structures of Cytc after 600 and 700 ns remained stable. The loop consisting of amino acids 20–30 showed the highest root mean square fluctuations (RMSF) for all variants (Fig. 6), similar to what we reported recently for Cytc variants of T2813. The loop RMSF were the highest for T58A Cytc, which may explain the structural instability of the T58A mutant when subjected to H2O2 (Fig. 3D,E).
Discussion
Previously, we reported phosphorylation of Cytc at three distinct sites with tissue specificity, Y97 in heart, Y48 in liver, and T28 in kidney. In the present study, we isolated Cytc from normal rat kidney and found that threonine 58 was also phosphorylated in some Cytc preparations from kidney while T28 was always phosphorylated13. The identification of T58 as another phosphorylation site in kidney in only some preparations could suggest that it is a minor posttranslational modification in this organ as a whole or, alternatively, that it only occurs in one or a few of the more than 26 cell types of the kidney25.
Since Cytc isolated from tissues is usually only partially phosphorylated, and because phosphorylations are somewhat unstable and can be easily lost, especially during longer experiments, and because it is cumbersome to acquire sufficient amounts of phosphorylated Cytc isolated from mammalian tissues, we here used an in vitro approach to test the functional effect of T58 phosphorylation. We mutated T58 to phosphomimetic glutamate, non-phosphorylatable alanine, and isoleucine to dissect the functional effects of the T58 modifications, using recombinant Cytc variants and a cell culture model using Cytc deficient mouse embryonic lung fibroblasts stably expressing Cytc variants.
The biochemical and functional characterization of the overexpressed phosphomimetic Cytc, which introduces a negative charge mimicking threonine phosphorylation, revealed that the substitution of T58 with glutamate partially inhibits mitochondrial respiration - both in vitro and in intact cells - and reduces apoptotic cell death. Although all Cytc variants generated hyperbolic kinetics in the reactions with purified bovine liver COX, maximal turnover was decreased by 45% and 25% with the phosphomimetic and isoleucine-substituted Cytc mutants compared to the WT. Similar reductions were seen in intact cells. These results are consistent with our previous findings with phospho- or phosphomimetic-Y97, Y48, and T28, except that T28 phosphorylation did not have any effect on apoptosis. Our data further support a high-throughput study which concluded that, in general, phosphorylation of metabolic mitochondrial proteins negatively regulates mitochondrial enzyme activity whereas dephosphorylation activates mitochondrial functions26.
The redox midpoint potentials of the four Cytc variants were in a similar range, suggesting that they may only constitute a minor component to the observed functional differences, including the reaction with COX and intact cell respiration. With the lower oxidation rate and higher reduction rate, phosphomimetic T58E Cytc may exhibit a slower rate of electron transfer to COX and increased ROS scavenging activity. Phosphomimetic T58E Cytc, both at the fully oxidized and reduced state, displayed increased resistance to heme degradation by H2O2, possibly due to its lower oxidation rate, which may be a result of conformational changes caused by the phosphomimetic substitution.
T58 is located in a loop on the back side of the heme crevice according to the Cytc crystal structure (Fig. 7A,B). It is not one of the 23 positions among the 104 amino acid residues of Cytc, previously proposed to be critical to the structure, function, folding, and stability of Cytc27. T58 is not in direct contact with COX based on a Cytc-COX docking model (Fig. 7C). As shown, the closest residue to Cytc T58 on COX within a distance of 15 Å is T80 of COX subunit VIa. Therefore, phosphorylation of T58 likely affects the binding affinity of Cytc with COX indirectly, leading to a reduction of the electron transfer rate.
Interaction with and peroxidation of cardiolipin was proposed to be a step for Cytc release from the IMS into the cytoplasm during apoptosis28. The largely electrostatic interaction-centered A-site involves residues K72, K73, K86, and K8 whereas the L-site involves K22, K25, H26, K27, and H33, leading to partial unfolding of the protein. However, in addition to the A- and the L-site, a third interaction site (C-site), which includes residues F36, G37, T58, W59, and K60, was detected using reverse micelle encapsulation to better mimic cristae curvature17. Interestingly, in the latter study the interaction of Cytc with CL at the three sites did not cause significant protein unfolding. T58 phosphorylation could impair the Cytc-CL interaction at the C-site and the oxidation of cardiolipin, thereby hindering the release of Cytc. This concept is supported by our findings showing that phosphomimetic T58E Cytc has a lower CL peroxidase activity compared to WT in vitro and a significantly reduced apoptotic activity in intact cells. The human Cytc structure (entry number: 3ZCF23) shows that T58 is in the proximity of K39 within a distance of 4 Å. T58 phosphorylated or phosphomimetic Cytc may form a salt bridge with K39, which is one of the key sites for Apaf-1 binding29. The electrostatic interaction or formation of a hydrogen bond between T58E and K39 of Cytc could cause conformational changes, thus suppressing apoptosome formation. Furthermore, Cytc T58 is in the proximity of F1063, Q1085, G1086, T1087, and D1106 of Apaf-1 at a distance < 7 Å (Fig. 7D), which could also affect Cytc-Apaf-1 binding when T58 is modified. For induction of apoptosis in cells stably expressing Cytc variants, we used H2O230,31,32 and staurosporine33,34. A recent study showed that the intrinsic apoptosis pathway has two subtypes, caspase-dependent and independent35, suggesting that Cytc-knockout cells could still undergo apoptosis via a caspase-independent pathway in the absence of a trigger of the extrinsic pathway. Cells expressing empty vector, which lack Cytc, showed a basal level of apoptosis after treatment with H2O2 or staurosporine, which may be explained by an alternative caspase-independent programed cell death pathway mediated by apoptosis inducing factor (AIF), mitochondrial serine protease HtrA2, and endonuclease G (endo G). Cells containing empty vector maintained a mitochondrial membrane potential due to reverse operation by adenine nucleotide translocase (ANT)36 and F0F1-ATPase37.
In all phyla across 285 Cytc sequences from bacteria to mammals, threonine is the most conserved amino acid at residue 5827. Isoleucine is second-most abundant and is present in the mammalian Cytc testis isoform and in humans, who only have a single functional Cytc gene, which is ubiquitously expressed. Glutamate is present in over 10 species whereas alanine was present in one plant species. The organisms carrying glutamate at T58 are mostly plants and yeast species, that may benefit from a lower rate of apoptosis and respiration as an adaptation to their environments. The evolutionary tolerance on this residue may account for the absence of detrimental functional defects in the T58 Cytc variants tested in this study. Isoleucine-substituted Cytc behaves in between the WT and phosphomimetic Cytc in its functions related to respiration and apoptosis. A previous study showed that somatic and testis Cytc have distinct functions. For example, testis Cytc had a threefold increased ability to reduce H2O2 and a fourfold increased ability to trigger apoptosis38. However, since rodent somatic and testis Cytc differ in 15 amino acids out of the 104 present in the mature protein, a functional comparison of our T58I mutant and testis Cytc cannot be made.
To explore possible protein dynamics changes in our mutants, we conducted molecular dynamics simulations. Interestingly, the T58 epitope is among the domains of Cytc with the most stability and none of the T58 substitutions showed any obvious change in rigidity. However, T58A Cytc produced structures in which the amino acid side chains within the 20-30 amino acid loop move more compared to the other Cytc variants (Fig. 6). These findings may explain that in T58A Cytc the heme group appears more accessible to react with oxidants such as H2O2 rendering the protein instable. Alanine, a small amino acid, is only present in a few species, possibly because it introduces additional flexibility at the heme crevice, and the reduction of protein stability may interfere with its multiple functions, similarly to what we reported for T28 Cytc13. With the replacement of glutamate or isoleucine, as used here, Cytc produces functional effects more similar to phosphorylated Cytc. Both oxidized and reduced Cytc species are rigid as shown by nitrogen-15 relaxation NMR39. However, certain amino acid replacements may cause local or global changes in protein dynamics. For example, this was suggested for G41S and Y48H Cytc, mutations that cause thrombocytopenia in humans. Here molecular dynamics simulations suggested partial unfolding of the protein40, and increased dynamics within the 40–57 Ω-loop were identified by NMR, which could explain increased peroxidase activity as seen in the mutants40. Interestingly, our MD simulations show reduced RMSF in the 40–57 Ω-loop for T58E Cytc (and modeled T58-phosphorylated Cytc), suggesting increased stability of this important structural domain.
In conclusion, all four functionally characterized phosphorylated or phosphomimetic substituted Cytc molecules including Y97, Y48, T28, and T58 showed partial inhibition of respiration. The results presented here further support our model that under basal physiological conditions, phosphorylation of Cytc T58 maintains an optimal intermediate ETC electron flux and thus an intermediate membrane potential range that limits ROS generation41. Under stress, such as ischemia, Cytc becomes dephosphorylated resulting in maximal ETC flux, hyperpolarization of membrane potential, and exponential increase of ROS production, leading to apoptotic cell death10. Our findings using intact cells suggest that a small modification of a Cytc residue can control the overall flux of the ETC. Future work is needed to identify the signaling pathways, including kinases and phosphatases, that regulate Cytc in physiological and pathological conditions.
Materials and Methods
Isolation of cytochrome c from rat kidney tissue
All reagents and chemicals were purchased from Sigma (St. Louis, MO) unless stated otherwise. Procedures for acquiring animal tissues were approved by the Wayne State University Institutional Animal Care and Use Committee (IACUC), and all experiments were performed in accordance with relevant guidelines and regulations. Rats were sacrificed, kidneys were removed, and Cytc was extracted by the acid extraction method12. Briefly, kidney tissues were homogenized in 100 mM phosphate buffer, pH 4.5, and incubated at 4 °C overnight. When most cellular proteins are denatured and precipitated, Cytc is extracted as a soluble protein in solution. Homogenates were centrifuged at 15,810 × g for 35 min, the supernatants decanted through cheesecloth, and the pH adjusted to 7.4 using KOH. PMSF protease inhibitor (1 mM) and phosphatase inhibitors (10 mM KF, 1 mM activated sodium orthovanadate) were added to preserve the phosphorylation state of Cytc. The supernatant was centrifuged after pH adjustment for 20 min at 4 °C. A DE52 anion exchange column was equilibrated with 20 mM phosphate buffer, pH 7.4, to reach a conductivity of 3.6 mS/cm. The pH and the conductivity of the supernatant were adjusted to meet the DE52 column condition used for anion-exchange chromatography. Cytc passed through the anion-exchange column since it is highly positively charged and was collected in the flow-through. The flow-through was adjusted to pH 6.5, and then applied to a CM52 cation exchange column, which was equilibrated with 30 mM phosphate buffer, pH 6.5, and a conductivity 5.5 mS/cm. Cytc was bound to the CM52 column and oxidized on the column with 2 mM K3Fe(CN)6, then eluted via a step-gradient of 30, 50, 80, 120, and 150 mM phosphate buffers, pH 6.5. Finally, size exclusion chromatography was used to further purify the protein with a column equilibrated with 150 mM phosphate buffer, pH 6.5. The protein was concentrated in a vacuum centrifuge, desalted with an Amicon Ultra-15 3 kDa centrifugal filter unit (Millipore, Billerca, MA), and stored at −80 °C.
Mass spectrometry to detect site-specific phosphorylations on purified cytochrome c
Phosphorylation site mapping on purified kidney Cytc was performed as described12. Immunoprecipitated protein was subjected to tryptic digestion and enrichment of phosphopeptides with titanium dioxide (TiO2), then desalted via Sep-Pak C18 reversed phase chromatography and dried as described. Peptides were injected into the mass spectrometer (LTQ Orbitrap-Velos, Thermo Scientific, Waltham, MA) after electrospray ionization. MS/MS spectra were assigned to peptide sequences from the UniProt protein database and searched with the MASCOT algorithm for posttranslational modifications. Phosphopeptide spectra were manually verified.
Mutagenesis, expression, and purification of cytochrome c
Rodent somatic Cytc cDNA was cloned into the pLW01 expression vector16,42, which also contains the cDNA encoding heme lyase (CYC3), an enzyme that is not present in bacteria but needed for the covalent attachment of the heme group to apo-cytochrome c. The codon corresponding to T58 of the somatic rodent Cytc cDNA was mutagenized to a glutamate residue (T58E) as a phosphomimetic replacement or an alanine residue as an additional unphosphorylatable control (T58A), as well as isoleucine (T58I), which is present in the rodent testis-specific isoform of Cytc and human Cytc at this position. These mutants were generated using the QuickChange lightning site-directed mutagenesis kit (Agilent, Santa Clara, CA) according to the manufacturer’s protocol. Briefly, the PLW01 Cytc plasmid was amplified using the following mutagenesis primers. Forward primers 5′-CCAACAAGAACAAAGGTATCGAGTGGGGAGAGGATACCC-3′ (Tm = 69 °C), 5′-ACAAGAACAA AGGTATCGCTTGGGGAGAGGATACC-3′ (Tm = 67 °C) and 5′-CCAACAAGAACAAAGGTATCA TCTGGGGAGAGGATAG-3′ (Tm = 78 °C) and the corresponding reverse-complemented primers 5′-GGGTATCCTCTCCCCACTCGATACCTTTGTTCTTGTTGG-3′ (Tm = 69 °C), 5′-GGTATCC TCTCCCCAAGCGATACCTTTGTTCTTGT-3′ (Tm = 67 °C) and 5′-TATCCTCTCCCCAGATGAT ACCTTTGTTCTTGTTGG-3′ (Tm = 78 °C) were used for PCR to generate T58E, T58A, and T58I mutants, respectively. Parental DNA was digested using the restriction enzyme DpnI and mutated DNA was transformed into XL10-Gold Ultracompetent cells (Stratagene, Technologies, La Jolla, CA). Plasmids containing PLW01-Cytc mutants were purified from individual colonies by using the Wizard Plus SV miniprep purification system (Promega, Madison, WI) and mutated DNA was sequenced to confirm the presence of the desired mutation. Constructs were transformed into competent E. coli C41 (DE3) cells (Lucigen, Middleton, WI) for protein expression16. The sequence-confirmed clones were cultured in 10 mL of TB medium (Difco, BD, Franklin Lakes, NJ) supplemented with 100 mg/mL carbenicillin and allowed to grow at 37 °C overnight while shaking. These cultures were inoculated in 4 L of TB medium with 100 mg/mL carbenicillin and allowed to grow until A600 reached 2–3. The expression of Cytc was induced by addition of 100 µM isopropyl β-D-1-thiogalactopyranoside (IPTG) and the protein was overexpressed in the culture at 37 °C for 6-8 h. Cells were harvested by centrifugation at 8,400 × g, at 4 °C for 40 min, and the pellets were frozen and stored at -80 °C until use. For extraction of Cytc, the bacterial pellets were resuspended in lysis buffer consisting of 20 mM phosphate, pH 7.4, supplemented with a mixture of protease inhibitors (P8340, Sigma, St. Louis, MO) according to the manufacturer’s instructions. For every 10 g of bacterial pellet, 100 mL of lysis buffer was used to resuspend the cells, which were lysed using a French pressure cell press (AMINCO, American Instrument Co.). The lysates were centrifuged at 15,000 rpm at 4 °C for 45 min, the supernatant pH was adjusted to 7.4, and Cytc mutants were purified by ion exchange chromatography as described above16.
To express Cytc mutants in Cytc double knockout mouse lung fibroblasts, the pBABE-puromycin expression plasmid (Addgene, Cambridge, MA) was used with rodent Cytc cloned into BamHI and EcoRI restriction sites using the following primers: outer forward primer pBABE, 5′-ATCTTGT GGAAAGGACGCGGGATCCATGGGTGAT GTTGAAAAA-3′ (Tm = 68.0 °C); outer reverse primer pBABE, 5′-GGTCGACCACTGTGCTGGCGAATTCTTACTTATCGTCGTCATCC TTGTAATCTTCATTAGTAGCC-3′ (Tm = 68.8 °C). A similar PCR mutagenesis approach was used with the same mutagenesis primers as above to obtain the C-terminal 1 x FLAG-tagged WT, T58E, T58A, and T58I constructs. The mutants were transfected into Cytc double knockout lung fibroblast cells24 and cultured at 37 °C in DMEM (high glucose, Gibco BRL) with 10% FBS, 1% of penicillin/streptomycin, 50 mg/mL uridine, 1 mM pyruvate, and 5% CO2. Stable cell lines expressing WT, the three mutants, and an empty vector control were selected with 2 µg/mL puromycin.
Concentration determination of cytochrome c
Purified Cytc was first fully reduced with 100 mM sodium dithionite, desalted with a NAP-5 column (GE Healthcare), and absorbance was measured on a Jasco V-570 double beam spectrophotometer (2 nm bandwidth). The concentration was calculated via differential spectra at 550 nm by subtracting the oxidized form from the reduced form using the formula (A550-reduced - Ab550-oxidized) /19.6 mM × dilution factor. Cytc purity was confirmed by Coomassie blue staining on a 10%Tris-Tricine SDS-PAGE gel.
Western blot analysis
Twenty micrograms of protein from cell lysates containing overexpressed Cytc were subjected to SDS-polyacrylamide gel electrophoresis (SDS-PAGE) using a 10% Tris-Tricine gel. Proteins were transferred onto a PVDF membrane (0.2 µm, Bio-Rad, Hercules, CA) in 25 mM Tris base, 192 mM glycine, and 20% methanol for 100 min at 175 mA. Western analysis was performed with a 1:5000 dilution of mouse anti-Cytc (556433, 7H8.2C12, BD Biosciences, San Jose, CA), followed by 1:10,000 dilution of anti-mouse IgG conjugated with horseradish peroxidase (NA93IV, GE Healthcare, Chicargo, IL). Signal was generated using HyGLO ECL reagent (E-2500, Denville Scientific Inc., Metuchen, NJ).
Measurement of cytochrome c oxidase activity
Regulatory competent bovine liver COX, the same isozyme present in kidney, was purified as described21 and diluted to 3 µM in COX measuring buffer (10 mM K-HEPES, pH7.4, 40 mM KCl, 1% Tween 20), containing a 40-fold molar excess of cardiolipin and 0.2 mM ATP, and dialyzed overnight at 4 °C to remove cholate bound to COX during enzyme purification. COX activity at a concentration of 150 nM was measured in a chamber equipped with a micro-Clark-type oxygen electrode (Oxygraph system, Hansatech, Pentney, UK) at 25 °C in 200 µL of COX measuring buffer and 20 mM ascorbate as electron donor. Increasing amounts of purified Cytc variants (0–20 µM) were added, and oxygen consumption was analyzed using Hansatech Oxygraph software. COX activity was expressed as turnover number (sec−1).
Caspase-3 activity with T58 cytochrome c variants
Caspase-3 activation was assayed using an in vitro cell-free apoptosis detection system with cytosolic extracts from Cytc−/− mouse embryonic fibroblasts (ATCC® CRL-2613™, Manassas, VA)24 as described16. Briefly, cells were cultured in 8 × 75 cm2 flasks, trypsinized, pelleted, and washed twice with cold PBS, followed by one wash with cytosol extraction buffer (CEB: 20 mM HEPES, pH 7.5, 1.5 mM MgCl2, 10 mM KCl, 1 mM EGTA, 1 mM EDTA, 1 mM DTT, 100 μM PMSF). One mL of CEB was added to the cell pellet and the suspension was transferred to a 2 mL Dounce homogenizer, allowing it to swell in the hypotonic CEB for 15 min on ice. Cells were disrupted by 30-35 strokes with a tight pestle. Lysates were centrifuged at 15,000 × g for 15 min at 4 °C to remove organelles and nuclei. Protein concentration was measured using the DC protein assay kit (Bio-Rad, Hercules, CA). Caspase-3 activity induced by addition of purified Cytc variants was measured using the EnzChek Caspase-3 assay kit (Invitrogen, Carlsbad, CA). Rhodamine 110-linked DEVD tetrapeptide was used as an artificial substrate of caspase-3, which fluoresces upon cleavage by caspase-3. Cell extracts were used at a protein concentration of 1 mg/mL and incubated with wild-type and T58 Cytc variants at 20 μg/mL for 2 h at 37 °C. Ten µL of preincubated (active) extracts were utilized for caspase-3 activity assays carried out in quadruplicate, and with caspase-3 inhibitor as control according to the manufacturer’s instructions. Fluorescence was detected using a Fluoroskan Ascent FL plate reader (Labsystems, Thermo Scientific, Waltham, MA, excitation filter 485 nm with 14 nm bandwidth, emission filter 527 nm with 10 nm bandwidth). Fluorescence values were measured in 30 min intervals for 3 h at room temperature. Fluorescence units from the caspase inhibitor and background (cytosolic extract without Cytc) were subtracted. Data were expressed as a percentage of change compared to the WT.
Thermal shift assay
Thermal shift assay was performed using an Applied Biosystems 7500 Real-time PCR system to determine thermal stability of the proteins. A buffer mimicking physiological salt concentrations (140 mM KCl, 10 mM KPi, pH 7.4) was used along with a final SYPRO orange (5000X stock, Invitrogen) concentration of 2.5X and a Cytc concentration of 0.2 mg/mL. The total reaction volume was 25 µL and the microplate was sealed with an optical clear adhesive film. The thermal stability was measured as a standard curve from 25 to 95 °C with a ramp speed of 0.5 °C/min. The melting temperature of each mutant was determined using the negative first derivative curve22 generated by ABI 7500 Software v2.0.6.
Measurement of redox potential
The midpoint redox potential (E°) was measured as described13 using 2,6-dichloroindophenol (DCIP, E°′ = 237 mV) as a reference compound, which has an absorption band at 600 nm in its oxidized state. Briefly, 1 mL of 2 mg/mL Cytc solution was added into a cuvette with 50 µL of 1 mM potassium ferricyanide, 2 mL of 50 mM citrate buffer, pH = 6.5, and 0.1 mL of 1 mM DCIP. Absorbance corresponding to fully oxidized Cytc (A550-A570) and DCIP (A600) were recorded using a Jasco V-570 double beam spectrophotometer. Then sequential 1 µL additions of 5 mM ascorbate were used to reduce Cytc, and absorbance values were measured for each step in one-minute intervals. When the readings were constant, a few grains of sodium dithionite (Na2S2O4) were added at the end of the titration to fully reduce Cytc and DCIP. The ratios of oxidized and reduced forms of Cytc and DCIP were plotted as log (DCIPox/DCIPred) versus log (Cytcox/Cytcred), which yielded a linear line with a slope, nDCIP/nCytc, and a y-intercept, nCytc/59.2 (ECytc-EDCIP). These values were used to calculate the E°Cytc with the Nernst equation.
Measurements of cytochrome c oxidation and reduction rates
The kinetics of oxidation of ferro-Cytc by H2O2 and reduction of ferri-Cytc by ascorbate were measured spectrophotometrically at 550 nm as described38. Briefly, WT and T58E, T58A, and T58I Cytc mutants were fully reduced with sodium dithionite, and the proteins were desalted using NAP5 columns. The initial spectra of 15 µM Cytc in 0.2 M Tris-Cl, pH 7.0 were measured at both 550 nm and 630 nm (as background reading). Then oxidizing agent H2O2 (100 µM) was added to the cuvette and the absorbance at 550 nm was recorded at 10, 20, and 30 sec. The amount of oxidized Cytc was calculated as described above. For reduction rate analysis, the kinetics of reduction of Cytc with ascorbate were measured. Cytc variants were fully oxidized with K3Fe(CN)6 and desalted using NAP5 columns. Ferri-Cytc (15 µM) was added to 50 mM sodium phosphate, pH 7.0, and 200 µM ascorbate was added to the cuvette and sealed from air. The measurements were performed as described above.
Heme degradation assay
The degradation of heme was analyzed through dissipation of the Soret band at 408 nm using 5 µM ferri- or ferro-Cytc in 50 mM phosphate buffer, pH 6.1, with 3 mM H2O2 as described38. Spectra were recorded initially, after 60 sec, followed by measurements every 200 sec until 800 sec.
Measurement of cardiolipin peroxidase activity
The cardiolipin peroxidase activity of Cytc was measured as previously described13,16, with modifications. Fluorescence of resorufin, the oxidation product of Amplex Red, was detected using a Flouroskan Ascent microplate reader (Labsystems, Thermoscientific) with excitation and emission wavelengths of 530 nm and 590 nm, respectively. Liposomes containing 0%, 20%, 30%, and 50% of tetraoleoyl-cardiolipin (TOCL) and 1,2-Dioleoyl-sn-glycero-3-phosphocholine (DOPC) in 20 mM K-HEPES buffer, pH = 7.2 were sonicated 5 times for 30 sec on ice, with one-minute intervals. Liposomes (25 µM) were incubated in a 96-well plate with 1 µM Cytc in the presence of 20 mM K-Hepes. The reaction was started with the addition of 10 µM Amplex Red and 5 µM H2O2. The reaction progress was monitored for 5 min, during which the reaction rate was linear.
Measurement of oxygen consumption rate in intact cells
Cells were cultured in DMEM supplemented with 10% FBS, 1% penicillin/streptomycin in Seahorse XFe24 cell culture microplates at a density of 20,000 cells per well in 250 μL media and incubated at 37 °C and 5% CO2. After 20 h the medium was replaced with Seahorse XF medium supplemented with 10 mM glucose, pH 7.4, and intact cell respiration was measured with an XFe24 Analyzer (Seahorse Biosciences, North Billerica, MA). Normalization to total protein content in the well after the experiment was used to control for variation in cell number between the cells expressing WT and T58 Cytc variants. Following the Seahorse assay, the cells in each well were lysed with 25 μL RIPA buffer containing protease inhibitor cocktail (Roche Applied Science, Mannheim, Germany) and protein concentration was determined using the DC protein assay (Bio-Rad, Hercules, CA), standardized to a bovine serum albumin (BSA) standard curve.
Measurement of mitochondrial membrane potential
Cell lines stably expressing Cytc variants were seeded at a density of 20,000 cells/well onto black 96-well plates (Costar, CLS3603, Sigma, Ronkonkoma, NY) and allowed to grow to 80–90% confluence. To assess relative changes in ΔΨm, cells were incubated for 1 h in phenol red- and FBS-free medium containing 1 µM JC-1 (5,5′,6,6′-tetrachloro-1,1′,3,3′-tetraethyl-benzimidazolyl-carbocyanine iodide, Molecular Probes, Inc.). JC-1 can selectively enter mitochondria and exists as a monomer at low membrane potential or at low concentration, emitting green fluorescence. At higher membrane potential, JC-1 aggregates and emits red fluorescence. Fluorescence was measured in PBS using a Synergy H1 microplate reader (BioTek Instruments, Inc., Winooski, VT) with excitation: 485 nm; emission: 527 nm, and excitation: 485 nm; emission: 590 nm, respectively. Data were presented as the ratio of red to green fluorescence.
Mitochondrial ROS measurement
Cells expressing Cytc variants were cultured in 24-well plates and incubated with 5 µM MitoSOX (M36008, Thermo Scientific) for 30 min at 37 °C. Cells were washed with PBS, and fluorescence was analyzed with a Synergy H1 plate reader (BioTek, Winooski, VT) by using excitation and emission wavelengths of 510 nm and 580 nm.
ATP Assay
Lung fibroblast cells stably expressing Cytc variants cultured in a T75 flask were scraped in warm 1 × PBS, collected as triplicates and immediately stored at −80 °C until measurement. Release of ATP was performed by boiling the samples in 300 µL boiling buffer (100 mM Tris-Cl, pH7.75, 4 mM EDTA) and immediate transfer of the samples to a boiling water bath for 2 min. Samples were kept on ice, sonicated, and diluted by 300-fold, and 40 µl of the diluted samples were used to determine the ATP concentration with the ATP bioluminescence assay kit HS II (Roche Applied Science) following the manufacturer’s protocol. Data were normalized to the protein concentration.
Apoptosis of stable cell lines expressing cytochrome c variants
Apoptosis was detected by staining the cells with Annexin V-FITC and propidium Iodide (PI) dyes, following H2O2 treatment 300 μM43,44,45 for 14 h or 1 µM staurosporine treatment46 for 5 h, respectively, with modifications. Briefly, cells were detached using 1 mM EDTA in PBS at 37 °C for 1 min. The reaction was neutralized by adding 2 mL of medium to the cells. Cells were pelleted and washed twice with cold PBS and resuspended in 1x Binding Buffer (0.1 M HEPES, pH 7.4, 1.4 M NaCl, and 25 mM CaCl2 solution) at a concentration of ~1 × 106 cells/mL. The cell suspensions (100 µL; ~105 cells) were transferred to a 5 mL culture tube, 5 µL of Annexin V and 2 µL PI were added to the cells as described in the Annexin V apoptosis kit manual (BD Biosciences). The cells were gently mixed and incubated for 15 min in the dark at room temperature. Binding buffer (500 µL) was added to each tube and the data were acquired by flow cytometry (FloMax, Sysmex America, Inc., Lincolnshire, IL) within 1 h. Unstained and stained/untreated cells were analyzed as controls for H2O2-treated samples whereas the same amount of DMSO vehicle was used as control for staurosporine-treated samples. The data were analyzed using FCS Express 6 RUC software (De Novo Software, Glendale, CA).
Molecular dynamics
Molecular dynamics were performed with YASARA version 17–12–2447 using its conservative “slow” protocol and the recommended default forcefield, AMBER 201448. The starting structure for the molecular dynamics calculations on WT is from molecule A in 5C0Z.PDB, which was obtained from oxidized Cytc in the presence of potassium ferricyanide (K3[Fe(CN)6]), and T58 mutants were all modeled from WT molecule A. RMSF plots for the amino acid side chains were generated with Excel using data imported from YASARA.
Statistical analyses
Statistical analyses of the data were performed with MSTAT version 5.4 (University of Wisconsin, N. Drinkwater) using the Wilcoxon rank sum test. Data are reported as means ± SEM. and were considered statistically significant (*) with p < 0.05.
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Acknowledgements
This work was supported by the U.S. National Institutes of Health grant R01 GM116807. We thank Dr. Elmar Krieger, the lead developer of Yasara, for his timely and insightful advice on the optimum protocols for performing and interpreting molecular dynamics calculations.
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M.H. conceived the study and J.W., H.A.K., C.T.M., L.I.G., and B.F.P.E. assisted with study design. J.W., H.A.K., A.V., J.L., I.L., G.M., Q.J., M.A.R., A.R.S., A.A.T., M,P.Z., B.F.P.E., and M.H. performed and analyzed experiments. J.W., H.A.K. and M.H. wrote the manuscript, assisted by I.L., B.F.P.E., and L.I.G.
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Wan, J., Kalpage, H.A., Vaishnav, A. et al. Regulation of Respiration and Apoptosis by Cytochrome c Threonine 58 Phosphorylation. Sci Rep 9, 15815 (2019). https://doi.org/10.1038/s41598-019-52101-z
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DOI: https://doi.org/10.1038/s41598-019-52101-z
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