利用FRET技术在活细胞内观察EGF对PKA作用的时空成像

cAMP依赖的蛋白激酶(protein kinase A,PKA)在细胞生长与分化过程中扮演重要角色,特别是在调节Ras信号通路引起的细胞增殖效应中起着重要作用。为了在活细胞内动态观察表皮生长因子(epidermal growth factor,EGF)对PKA的作用,采用一种可以检测PKA酶活性的报告蛋白(A-kinase activity reporter,AKAR)——这种报告蛋白是利用荧光共振能量转移(fluorescence resonance energy transfer,FRET)原理设计的,使其在人类肺癌细胞(ASTC-a-1)中稳定表达。加入EGF刺激因子后,随时间变化的成像分析显示出在活细胞生理条件下被EGF作用的PKA酶活性变化的时空信息。这些资料为EGF作用PKA提供了直接的实时证据。     

FRET-based direct detection of dynamic protein kinase A activity on the sarcoplasmic reticulum in cardiomyocytes

The second messenger cAMP-dependent protein kinase A (PKA) plays an important role in the various cellular and physiological responses. On the sarcoplasmic reticulum (SR) in cardiomyocytes, PKA regulates the calcium cycling for exciting–contraction coupling, which is often dysfunctional in a variety of heart diseases including heart failure. Here, we have developed a novel FRET-based A-kinase activity biosensor (AKAR), termed SR-AKAR3, to visualize the PKA dynamics on the SR. Activation of adrenergic receptor induces a rapid and significant increase in SR-AKAR3 FRET ratio, which is dependent on agonist occupation of the receptor and inhibited by H-89, a PKA inhibitor. Interestingly, direct activation of adenylyl cyclases or application of a cAMP analog 8-Br-cAMP induced much slower and smaller increases in SR-AKAR3 FRET ratio. These data indicate that the signaling induced by adrenergic stimulation displays a preferential access to the SR in comparison to those by direct activation of adenylyl cyclases. More, SR-AKAR3 mimics endogenous protein phospholamban on the SR for PKA-mediated phosphorylation and myocyte contraction response under adrenergic stimulation. Together, this new PKA activity biosensor provides a useful tool to directly visualize the dynamic regulation of PKA activity on the SR in cardiomyocytes under various physiological and clinical conditions.     

“Shaping” of cell signaling via AKAP-tethered PDE4D: Probing with AKAR2-AKAP5 biosensor

Background

PKA, a key regulator of cell signaling, phosphorylates a diverse and important array of target molecules and is spatially docked to members of the A-kinase Anchoring Protein (AKAP) family. AKAR2 is a biosensor which yields a FRET signal in vivo, when phosphorylated by PKA. AKAP5, a prominent member of the AKAP family, docks several signaling molecules including PKA, PDE4D, as well as GPCRs, and is obligate for the propagation of the activation of the mitogen-activated protein kinase cascade from GPCRs to ERK1,2.

Results

Using an AKAR2-AKAP5 fusion ??biosensor??, we investigated the spatial-temporal activation of AKAP5 undergoing phosphorylation by PKA in response to ??-adrenergic stimulation. The pattern of PKA activation reported by AKAR2-AKAP5 is a more rapid and spatially distinct from those ??sensed?? by AKAR2-AKAP12. Spatial-temporal restriction of activated PKA by AKAP5 was found to ??shape?? the signaling response. Phosphatase PDE4D tethered to AKAP5 also later reverses within 60?s elevated intracellular cyclic AMP levels stimulated by ??-adrenergic agonist. AKAP12, however, fails to attenuate the rise in cyclic AMP over this time. Fusion of the AKAP5 PDE4D-binding-domain to AKAP12 was found to accelerate a reversal of accumulation of intracellular cyclic AMP.

Conclusion

AKAPs, which are scaffolds with tethered enzymes, can ??shape?? the temporal and spatial aspects of cell signaling.     

PDE4 Control on cAMP/PKA Compartmentation Revealed by Biosensor Imaging in Neurons

Electrophysiological recordings (using the slow-AHP potassium current) together with novel biosensor imaging methods (with AKAR and Epac sensors) were used in preparations of rodent brain slices to record PKA activation in real time and in individual neurons. The experiments revealed the propagation of the PKA signal from the membrane to the cytosol and eventually to the nucleus. The experiments show how the geometry of the neurons combined with phosphodiesterase activities (mostly rolipram-sensitive PDE4) contributes to a functional compartmentation of the cAMP in subcellular domains.     

"Shaping" of cell signaling via AKAP-tethered PDE4D: Probing with AKAR2-AKAP5 biosensor

ABSTRACT: BACKGROUND: PKA, a key regulator of cell signaling, phosphorylates a diverse and important array of target molecules and is spatially docked to members of the A-kinase Anchoring Protein (AKAP) family. AKAR2 is a biosensor which yields a FRET signal in vivo, when phosphorylated by PKA. AKAP5, a prominent member of the AKAP family, docks several signaling molecules including PKA, PDE4D, as well as GPCRs, and is obligate for the propagation of the activation of the mitogen-activated protein kinase cascade from GPCRs to ERK1,2. RESULTS: Using an AKAR2-AKAP5 fusion "biosensor", we investigated the spatial-temporal activation of AKAP5 undergoing phosphorylation by PKA in response to beta-adrenergic stimulation. The pattern of PKA activation reported by AKAR2-AKAP5 is a more rapid and spatially distinct from those "sensed" by AKAR2-AKAP12. Spatial-temporal restriction of activated PKA by AKAP5 was found to "shape" the signaling response. Phosphatase PDE4D tethered to AKAP5 also later reverses within 60 s elevated intracellular cyclic AMP levels stimulated by beta-adrenergic agonist. AKAP12, however, fails to attenuate the rise in cyclic AMP over this time. Fusion of the AKAP5 PDE4D-binding-domain to AKAP12 was found to accelerate a reversal of accumulation of intracellular cyclic AMP. CONCLUSION: AKAPs, which are scaffolds with tethered enzymes, can "shape" the temporal and spatial aspects of cell signaling.     

Protein kinase A regulates 3-phosphatidylinositide dynamics during platelet-derived growth factor-induced membrane ruffling and chemotaxis

Spatial regulation of the cAMP-dependent protein kinase (PKA) is required for chemotaxis in fibroblasts; however, the mechanism(s) by which PKA regulates the cell migration machinery remain largely unknown. Here we report that one function of PKA during platelet-derived growth factor (PDGF)-induced chemotaxis was to promote membrane ruffling by regulating phosphatidylinositol 3,4,5-trisphosphate (PIP(3)) dynamics. Inhibition of PKA activity dramatically altered membrane dynamics and attenuated formation of peripheral membrane ruffles in response to PDGF. PKA inhibition also significantly decreased the number and size of PIP(3)-rich membrane ruffles in response to uniform stimulation and to gradients of PDGF. This ruffling defect was quantified using a newly developed method, based on computer vision edge-detection algorithms. PKA inhibition caused a marked attenuation in the bulk accumulation of PIP(3) following PDGF stimulation, without effects on PI3-kinase (PI3K) activity. The deficits in PIP(3) dynamics correlated with a significant inhibition of growth factor-induced membrane recruitment of endogenous Akt and Rac activation in PKA-inhibited cells. Simultaneous inhibition of PKA and Rac had an additive inhibitory effect on growth factor-induced ruffling dynamics. Conversely, the expression of a constitutively active Rac allele was able to rescue the defect in membrane ruffling and restore the localization of a fluorescent PIP(3) marker to membrane ruffles in PKA-inhibited cells, even in the absence of PI3K activity. These data demonstrate that, like Rac, PKA contributes to PIP(3) and membrane dynamics independently of direct regulation of PI3K activity and suggest that modulation of PIP(3)/3-phosphatidylinositol (3-PI) lipids represents a major target for PKA in the regulation of PDGF-induced chemotactic events.     

Rab32 regulates melanosome transport in Xenopus melanophores by protein kinase a recruitment

Intracellular transport is essential for cytoplasm organization, but mechanisms regulating transport are mostly unknown. In Xenopus melanophores, melanosome transport is regulated by cAMP-dependent protein kinase A (PKA). Melanosome aggregation is triggered by melatonin, whereas dispersion is induced by melanocyte-stimulating hormone (MSH). The action of hormones is mediated by cAMP: High cAMP in MSH-treated cells stimulates PKA, whereas low cAMP in melatonin-treated cells inhibits it. PKA activity is typically restricted to specific cell compartments by A-kinase anchoring proteins (AKAPs). Recently, Rab32 has been implicated in protein trafficking to melanosomes and shown to function as an AKAP on mitochondria. Here, we tested the hypothesis that Rab32 is involved in regulation of melanosome transport by PKA. We demonstrated that Rab32 is localized to the surface of melanosomes in a GTP-dependent manner and binds to the regulatory subunit RIIalpha of PKA. Both RIIalpha and Cbeta subunits of PKA are required for transport regulation and are recruited to melanosomes by Rab32. Overexpression of wild-type Rab32, but not mutants unable to bind PKA or melanosomes, inhibits melanosome aggregation by melatonin. Therefore, in melanophores, Rab32 is a melanosome-specific AKAP that is essential for regulation of melanosome transport.     

Developmentally acquired PKA localisation in mouse oocytes and embryos

Localisation of Protein Kinase A (PKA) by A-Kinase Anchoring Proteins (AKAPs) is known to coordinate localised signalling complexes that target cAMP-mediated signalling to specific cellular sub-domains. The cAMP PKA signalling pathway is implicated in both meiotic arrest and meiotic resumption, thus spatio-temporal changes in PKA localisation during development may determine the oocytes response to changes in cAMP. In this study we aim to establish whether changes in PKA localisation occur during oocyte and early embryo development.Using fluorescently-labelled PKA constructs we show that in meiotically incompetent oocytes PKA is distributed throughout the cytoplasm and shows no punctuate localisation. As meiotic competence is acquired, PKA associates with mitochondria. Immature germinal vesicle (GV) stage oocytes show an aggregation of PKA around the GV and PKA remains co-localised with mitochondria throughout oocyte maturation. After fertilisation, the punctuate, mitochondrial distribution was lost, such that by the 2-cell stage there was no evidence of PKA localisation. RT-PCR and Western blotting revealed two candidate AKAPs that are known to be targeted to mitochondria, AKAP1 and D-AKAP2. In summary these data show a dynamic regulation of PKA localisation during oocyte and early embryo development.     

cAMP-PKA signaling to the mitochondria: protein scaffolds, mRNA and phosphatases

Energy metabolism and, specifically, the coupling of mitochondria to growth and survival is controlled by the cAMP-PKA pathway in yeast. In higher eukaryotes, cAMP signaling originating at the plasma membrane is distributed to different subcellular districts by cAMP waves received by PKA bound to PKA anchor proteins (AKAPs) tethered to these compartments. This review focuses on the subgroup of AKAPs that anchor PKA to the mitochondrial outer membrane (mtAKAPs). Only PKA anchored to mtAKAPs can efficiently transmit cAMP signals to mitochondria. mtAKAP complexes are remarkably heterogeneous. In addition to PKA regulatory subunits, they may include mRNAs, tyrosine phosphatase(s) and tyrosine kinase(s). Selective regulation of these components by cAMP-PKA integrates various signal transduction pathways and can determine which subcellular compartment receives the signal. Unveiling the interactions among the components of these large complexes will shed light on how cAMP and PKA regulate vital mitochondrial processes.     

Progesterone synthesis by human placental mitochondria is sensitive to PKA inhibition by H89

The transfer of cholesterol to mitochondria, which might involve the phosphorylation of proteins, is the rate-limiting step in human placental steroidogenesis. Protein kinase A (PKA) activity and its role in progesterone synthesis by human placental mitochondria were assessed in this study. The results showed that PKA and phosphotyrosine phosphatase D1 are associated with syncytiotrophoblast mitochondrial membrane by an anchoring kinase cAMP protein-121. The 32P-labeled of four major proteins was analyzed. The specific inhibitor of PKA, H89, decreased progesterone synthesis in mitochondria while in mitochondrial steroidogenic contact sites protein-phosphorylation was diminished, suggesting that PKA plays a role in placental hormone synthesis. In isolated mitochondria, PKA activity was unaffected by the addition of cAMP suggesting a constant activity of this kinase in the syncytiotrophoblast. The presence of PKA and phosphotyrosine phosphatase D1 anchored to mitochondria by an anchoring kinase cAMP protein-121 indicated that syncytiotrophoblast mitochondria contain a full phosphorylation/dephosphorylation system.     

Biogenesis of the preprotein translocase of the outer mitochondrial membrane: protein kinase A phosphorylates the precursor of Tom40 and impairs its import

The preprotein translocase of the outer mitochondrial membrane (TOM) functions as the main entry gate for the import of nuclear-encoded proteins into mitochondria. The major subunits of the TOM complex are the three receptors Tom20, Tom22, and Tom70 and the central channel-forming protein Tom40. Cytosolic kinases have been shown to regulate the biogenesis and activity of the Tom receptors. Casein kinase 2 stimulates the biogenesis of Tom22 and Tom20, whereas protein kinase A (PKA) impairs the receptor function of Tom70. Here we report that PKA exerts an inhibitory effect on the biogenesis of the β-barrel protein Tom40. Tom40 is synthesized as precursor on cytosolic ribosomes and subsequently imported into mitochondria. We show that PKA phosphorylates the precursor of Tom40. The phosphorylated Tom40 precursor is impaired in import into mitochondria, whereas the nonphosphorylated precursor is efficiently imported. We conclude that PKA plays a dual role in the regulation of the TOM complex. Phosphorylation by PKA not only impairs the receptor activity of Tom70, but it also inhibits the biogenesis of the channel protein Tom40.     

Spatiotemporally regulated protein kinase A activity is a critical regulator of growth factor-stimulated extracellular signal-regulated kinase signaling in PC12 cells

PC12 cells exhibit precise temporal control of growth factor signaling in which stimulation with epidermal growth factor (EGF) leads to transient extracellular signal-regulated kinase (ERK) activity and cell proliferation, whereas nerve growth factor (NGF) stimulation leads to sustained ERK activity and differentiation. While cyclic AMP (cAMP)-mediated signaling has been shown to be important in conferring the sustained ERK activity achieved by NGF, little is known about the regulation of cAMP and cAMP-dependent protein kinase (PKA) in these cells. Using fluorescence resonance energy transfer (FRET)-based biosensors localized to discrete subcellular locations, we showed that both NGF and EGF potently activate PKA at the plasma membrane, although they generate temporally distinct activity patterns. We further show that both stimuli fail to induce cytosolic PKA activity and identify phosphodiesterase 3 (PDE3) as a critical regulator in maintaining this spatial compartmentalization. Importantly, inhibition of PDE3, and thus perturbation of the spatiotemporal regulation of PKA activity, dramatically increases the duration of EGF-stimulated nuclear ERK activity in a PKA-dependent manner. Together, these findings identify EGF and NGF as potent activators of PKA activity specifically at the plasma membrane and reveal a novel regulatory mechanism contributing to the growth factor signaling specificity achieved by NGF and EGF in PC12 cells.     

Analyses of the Involvement of PKA Regulation Mechanism in Meiotic Incompetence of Porcine Growing Oocytes

Mammalian growing oocytes (GOs) lack the ability to resume meiosis, although the molecular mechanism of this limitation is not fully understood. In the present study, we cloned cDNAs of cAMP-dependent protein-kinase (PKA) subunits from porcine oocytes and analyzed the involvement of the PKA regulation mechanism in the meiotic incompetence of GOs at the molecular level. We found a cAMP-independent high PKA activity in GOs throughout the in vitro culture using a porcine PKA assay system we established, and inhibition of the activity by injection of the antisense RNA of the PKA catalytic subunit (PKA-C) induced meiotic resumption in GOs. Then we examined the possibility that the amount of the PKA regulatory subunit (PKA-R), which can bind and inhibit PKA-C, was insufficient to suppress PKA activity in GOs because of the overexpression of two PKA-Rs, PRKAR1A and PRKAR2A. We found that neither of them affected PKA activity and induced meiotic resumption in GO although PRKAR2A could inhibit PKA activity and induce meiosis in cAMP-treated full-grown oocytes (FGOs). Finally, we analyzed the subcellular localization of PKA subunits and found that all the subunits were localized in the cytoplasm during meiotic arrest and that PKA-C and PRKAR2A, but not PRKAR1A, entered into the nucleus just before meiotic resumption in FGOs, whereas all of them remained in the cytoplasm in GOs throughout the culture period. Our findings suggest that the continuous high PKA activity is a primary cause of the meiotic incompetence of porcine GOs and that this PKA activity is not simply caused by an insufficient expression level of PKA-R, but can be attributed to more complex spatial-temporal regulation mechanisms.     

The VDAC channel as the mitochondria function regulator

Regulation of mitochondria physiology, indispensable for proper cell activity, requires an efficient exchange of molecules between mitochondria and cytoplasm at the level of the mitochondrial outer membrane. The common pathway for the metabolite exchange between mitochondria and cytoplasm is the VDAC channel (voltage dependent anion channel), known also as mitochondrial porin. The channel was identified for the first time in 1976 and since that time has been extensively studied. It has been recognized that the VDAC channel plays a crucial role in the regulation of metabolic and energetic functions of mitochondria. In this article we review the VDAC channel relevance to ATP rationing, Ca2+ homeostasis, protection against oxidative stress and apoptosis execution.     

Spatial Distribution of Protein Kinase A Activity during Cell Migration Is Mediated by A-kinase Anchoring Protein AKAP Lbc

Protein kinase A (PKA) has been suggested to be spatially regulated in migrating cells due to its ability to control signaling events that are critical for polarized actin cytoskeletal dynamics. Here, using the fluorescence resonance energy transfer-based A-kinase activity reporter (AKAR1), we find that PKA activity gradients form with the strongest activity at the leading edge and are restricted to the basal surface in migrating cells. The existence of these gradients was confirmed using immunocytochemistry using phospho-PKA substrate antibodies. This observation holds true for carcinoma cells migrating randomly on laminin-1 or stimulated to migrate on collagen I with lysophosphatidic acid. Phosphodiesterase inhibition allows the formation of PKA activity gradients; however, these gradients are no longer polarized. PKA activity gradients are not detected when a non-phosphorylatable mutant of AKAR1 is used, if PKA activity is inhibited with H-89 or protein kinase inhibitor, or when PKA anchoring is perturbed. We further find that a specific A-kinase anchoring protein, AKAP-Lbc, is a major contributor to the formation of these gradients. In summary, our data show that PKA activity gradients are generated at the leading edge of migrating cells and provide additional insight into the mechanisms of PKA regulation of cell motility.Cell motility is controlled by a complex network of signals that are initiated by binding to the extracellular matrix. Understanding the biochemical mechanisms that control cell migration is necessary for better comprehension of processes like wound healing, embryonic development, and angiogenesis as well as cancer metastasis (1). PKA³ is an important regulator of cell signaling and various biological functions (2-4). Previous studies have shown that cell motility is delicately controlled by synthesis and breakdown of cAMP through its effects on PKA. PKA regulates key signaling events that are critical for actin cytoskeletal remodeling and cell polarization during migration, including control of the activation states of RhoA, Rac, cdc42, Pak, and c-Abl. For example, PKA is known to inhibit the activation of RhoA, whereas it is required for the activation of Rac1, two proteins that are spatially regulated during cell migration. Therefore, it has been suggested that PKA activity in migrating cells is spatially regulated (5-9). The mounting evidence for the formation of cAMP/PKA gradients and their influence over directed cell motility is compelling. To conclusively determine that PKA activity gradients exist, the visualization of these gradients in single cells is needed to determine the nature of gradients and the mechanisms governing how they are formed.The compartmental action of cAMP was suggested over three decades ago (10, 11) and has hence been shown to mediate the precise spatiotemporal control of its effectors (12-15). Tight control of cAMP levels is governed by the coordinated actions of cyclic nucleotide phosphodiesterases (PDEs) and adenylyl cyclases. Gradients of cAMP and, thus, PKA activity are expected to exist in a cell. This idea is based, most simplistically, on the fact that cAMP is generated by membrane-bound adenylyl cyclases and broken down by cytosolic PDEs; that is, the two arms of cAMP metabolism are spatially separated. Further compartmentalization of PKA activity also occurs as a result of the anchoring of PKA and cAMP-specific PDEs to A-kinase anchoring proteins (AKAPs), which has been demonstrated in a variety of cell types (16, 17). The anchoring of PKA occurs typically through the binding of the type II regulatory (RII) subunits to AKAPs where the relative levels of PDE activity and cAMP generated regulate the regional activity of PKA. PKA anchoring, in addition to cAMP synthesis and degradation, is believed to control spatial signaling of PKA (14, 15). Until recently, we have lacked both the model systems and technology to adequately study the possibility that cAMP/PKA activity gradients exist. We and others (5-8) have established that polarization and migration of cells are dependent on cAMP synthesis and breakdown. Here, we sought to demonstrate the existence of cAMP/PKA gradients in single migrating cells using the fluorescence resonance energy transfer (FRET)-based PKA biosensor A-kinase activity reporter (AKAR1) and determine how signaling components that regulate PKA activity, including cAMP synthesis, PDEs, and PKA anchoring, affect the formation of these gradients.     

甲硫氨酸脑啡肽和抗δ阿片受体抗体对小鼠骨髓瘤细胞信号传递系统的作用

为了探讨阿片肽与细胞表面受体结合后所产生的生物效应及其机制 ,用不同浓度甲硫氨酸脑啡肽 ( MENK)及抗 δ阿片受体单克隆抗体处理小鼠的骨髓瘤细胞 ( NS- 1 ) ,然后测定蛋白激酶A( PKA) ,蛋白激酶 C( PKC)活性及三磷酸肌醇 ( IP3 )含量 .研究结果表明 ,NENK可升高细胞胞浆及胞膜 PKA的活性 ,且这一作用可被抗δ阿片受体抗体所拮抗 .MENK对 PKC影响呈双向反应 ,0 .1 μmol/L MENK可以升高胞浆 PKC活性 ,但却明显降低胞膜 PKC活性 ;在 MENK浓度为 1 0μmol/L时则情况刚好相反 .1 μmol/L的 MENK可明显降低胞浆及胞膜 PKC活性 ,抗体可拮抗这种下调作用 .MENK可降低细胞内 IP3 的含量 ,且这一作用可被抗δ阿片受体抗体所拮抗 .由此可以推论 :MENK在与 δ阿片受体结合后 ,可以经过多种信号传导系统来调节细胞功能 ,从而产生不同的生物效应 .     

The Ras/cAMP-dependent protein kinase signaling pathway regulates an early step of the autophagy process in Saccharomyces cerevisiae

When faced with nutrient deprivation, Saccharomyces cerevisiae cells enter into a nondividing resting state, known as stationary phase. The Ras/PKA (cAMP-dependent protein kinase) signaling pathway plays an important role in regulating the entry into this resting state and the subsequent survival of stationary phase cells. The survival of these resting cells is also dependent upon autophagy, a membrane trafficking pathway that is induced upon nutrient deprivation. Autophagy is responsible for targeting bulk protein and other cytoplasmic constituents to the vacuolar compartment for their ultimate degradation. The data presented here demonstrate that the Ras/PKA signaling pathway inhibits an early step in autophagy because mutants with elevated levels of Ras/PKA activity fail to accumulate transport intermediates normally associated with this process. Quantitative assays indicate that these increased levels of Ras/PKA signaling activity result in an essentially complete block to autophagy. Interestingly, Ras/PKA activity also inhibited a related process, the cytoplasm to vacuole targeting (Cvt) pathway that is responsible for the delivery of a subset of vacuolar proteins in growing cells. These data therefore indicate that the Ras/PKA signaling pathway is not regulating a switch between the autophagy and Cvt modes of transport. Instead, it is more likely that this signaling pathway is controlling an activity that is required during the early stages of both of these membrane trafficking pathways. Finally, the data suggest that at least a portion of the Ras/PKA effects on stationary phase survival are the result of the regulation of autophagy activity by this signaling pathway.     

Regulation of NADH/CoQ Oxidoreductase: Do Phosphorylation Events Affect Activity?

We had previously suggested that phosphorylation of proteins by mitochondrial kinases regulate the activity of NADH/CoQ oxidoreductase. Initial data showed that pyruvate dehydrogenase kinase (PDK) and cAMP-dependent protein kinase A (PKA) phosphorylate mitochondrial membrane proteins. Upon phosphorylation with crude PDK, mitochondria appeared to be deficient in NADH/cytochrome c reductase activity associated with increased superoxide production. Conversely, phosphorylation by PKA resulted in increased NADH/cytochrome c reductase activity and decreased superoxide formation. Current data confirms PKA involvement in regulating Complex I activity through phosphorylation of an 18 kDa subunit. Beef heart NADH/ cytochrome c reductase activity increases to 150% of control upon incubation with PKA and ATP-gamma-S. We have cloned the four human isoforms of PDK and purified beef heart Complex I. Incubation of mitochondria with PDK isoforms and ATP did not alter Complex I activity or superoxide production. Radiolabeling of mitochondria and purified Complex I with PDK failed to reveal phosphorylated proteins.