Analyses of deoxycytidylate deaminase molecular forms in human-mouse and monkey-mouse somatic cell hybrids

Disc polyacrylamide gel electrophoresis (disc PAGE) analyses have revealed that mouse, human, and monkey cytosol deoxycytidylate (dCMP) deaminases differ in electrophoretic mobility, so that mixtures of mouse and human, mouse and monkey, and human and monkey enzymes can be separated. To learn whether the genes for dCMP deaminase and thymidine (dT) kinase are genetically linked, disc PAGE analyses of cytosol fractions from human-mouse and monkey-mouse somatic cell hybrids were carried out. The interspecific somatic cell hybrids were derived from the fusion of cytosol dT kinase deficient mouse cells with cytosol dT kinase-positive human and monkey cells: they contained mostly mouse chromosomes and a few primate chromosomes, including the determinant for primate cytosol dT kinase. The disc PAGE analyses demonstrated that the human-mouse and monkey-mouse somatic cell hybrids contained a dCMP deaminase activity with an electrophoretic mobility characteristic of mouse dCMP deaminase. Enzymes with electrophoretic mobilities characteristic of human and monkey dCMP deaminases were not demonstrable. These findings suggest that primate cytosol dT kinase and dCMP deaminase are coded on different chromosomes, or that the formation in hybrid cells of an active primate dCMP deaminase is suppressed. Chick-mouse somatic cell hybrids containing chick but not mouse cytosol dT kinase were also analyzed. The chick-mouse hybrid cells contained cytosol dCMP deaminase activity, but it was not possible to establish whether the enzyme was of murine or avian origin because of the similarity in electrophoretic mobility between the chick and mouse enzymes. Human and mouse cells contained low levels of mitochondrial dCMP deaminase activity. In contrast to dT kinase isozymes, however, mitochondrial and cytosol dCMP deaminases were electrophoretically indistinguishable.This investigation was aided by Grant Q-163 from the Robert A. Welch Foundation and by USPHS Grants CA-06656-12 and 1-K6-AI 2352 from the National Cancer Institute and the National Institute of Allergy and Infectious Diseases.     

Properties of mitochondrial thymidine kinases of parental and enzyme-deficient HeLa cells

HeLa(BU25), a mutant subline of HeLa S3 cells, contains mitochondrial thymidine (dT) kinase, despite a marked deficiency in the dT kinase activity of the “cytosol” (high-speed supernatant) cell fraction. The HeLa(BU25) mitochondrial dT kinase differs from the “cytosol” enzyme of parental HeLa S3 cells in sedimentation coefficient, ability to utilize ribonucleoside 5′-triphosphates other than ATP as phosphate donors, sensitivity to inhibition by dCTP, and in disc polyacrylamide gel electrophoretic (disc PAGE) patterns. Two dT kinase activities [relative mobilities (Rm) of 0.4 and 0.6–0.7] were detected after disc PAGE of HeLa(BU25) mitochondrial extracts and both activities migrated more rapidly than the typical cytosol enzyme (Rm = 0.2) of dT kinase-positive human cells. The 0.6 to 0.7-Rm dT kinase of HeLa(BU25) mitochondria, but not the 0.4-Rm activity, utilized GTP and UTP, as well as ATP, as phosphate donors. HeLa S3 mitochondrial fractions contained the 0.6–0.7 Rm and the 0.4-Rm activities, and in addition, a “cytosol-like” 0.2-Rm activity. The 0.6 to 0.7-Rm dT kinase of HeLa S3 mitochondria utilized either UTP or ATP as phosphate donors, but the 0.4- and 0.2-Rm dT kinases utilized only ATP. Similarly, the HeLa S3 cytosol dT kinase efficiently utilized ATP, but not UTP, as a phosphate donor.     

Characterization of nucleoside phosphotransferase and thymidine kinase activities of chick embryo cells and of chick-mouse somatic cell hybrids.

Experiments were carried out to characterize the thymidine (dT) phosphorylating activities of chick embryo, chick erythrocytes, and of chick mouse somatic cell hybrids derived from fused chick erythrocytes and dT kinase-deficient LM(TK) mouse cells. Disc PAGE, isoelectric focusing, and glycerol gradient centrifugation analyses revealed that chick embryo cells contained four distinctive dT phosphorylating activities, two dT kinases and two nucleoside phosphotransferases. Thymidine kinase F. found principally in the cytosol, was also detected in mitochondrial and nuclear extracts, but was very low or absent from chick erythrocytes. Thymidine kinase A corresponds to the mitochondrial-specific isozyme found in bromodeoxyuridine-resistant mammalian cells. Nucleoside phosphotransferase activities were very active in chick embryo cytosol and were detected in embryo mitochondria! and nuclear extracts and cytosol and nuclear extracts of chick erythrocytes. Most of the chick embryo nucleoside phosphotransferase activity could be removed by purification of cytosol dT kinase F. Chick-mouse somatic cell hybrids exhibited chick dT kinase F, but neither chick dT kinase A. chick nucleoside phosphotransferase, nor mouse cytosol dT kinase activities. The results indicate (1) the genetic determinant for chick cytosol dT kinase F is on a different chromosome from the determinants for the chick nucleoside phosphotransferases and mitochondrial dT kinase A, and/or (2) only the chick cytosol dT kinase F, but neither the chick nucleoside phosphotransferases nor dT kinase A, was reactivated in the hybrids.     

Distinctive properties of mitochondrial thymidine(dT)kinase from bromodeoxyuridine(dBU)-resistant mouse lines

dBU-resistant mouse lines lack detectable dT kinase activity in the high speed supernatant (cytosol) cell fraction. However, they contain a mitochondrial dT kinase, which sediments more slowly in glycerol gradients than the cytosol enzyme of parental mouse lines, exhibits a disc PAGE mobility relative to the tracking dye (Rm) of about 0.7–0.8, and utilizes ATP, UTP, GTP, and CTP as phosphate donors. The mitochondrial fraction of parental cells also contains this 0.7–0.8 Rm activity and, in addition, a minor dT kinase activity which migrates faster than the cytosol enzyme, but utilizes only ATP as phosphate donor. The cytosol dT kinase of parental mouse lines exhibits an Rm of about 0.2–0.3 and utilizes only ATP as phosphate donor.     

ACQUISITION OF CHICK CYTOSOL THYMIDINE KINASE ACTIVITY BY THYMIDINE KINASE-DEFICIENT MOUSE FIBROBLAST CELLS AFTER FUSION WITH CHICK ERYTHROCYTES

Chick-mouse heterokaryons were obtained by UV-Sendai virus-induced fusion of chick erythrocytes with thymidine (dT) kinase-deficient mouse fibroblast [LM(TK^-)] cells. Autoradiographic studies demonstrated that 1 day after fusion, [³H]dT was incorporated into both red blood cell and LM(TK^-) nuclei of 23% of the heterokaryons. Self-fused LM(TK^-) cells failed to incorporate [³H]dT into nuclear DNA. 15 clonal lines of chick-mouse somatic cell hybrids [LM(TK^-)/CRB] were isolated from the heterokaryons by cultivating them in selective hypoxanthine-aminopterin-thymidine-glycine medium. LM(TK^-) and chick erythrocytes exhibited little, if any, cytosol dT kinase activity. In contrast, all 15 LM(TK^-)/CRB lines contained levels of cytosol dT kinase activity comparable to that found in chick embryo cells. Disk polyacrylamide gel electrophoresis and isoelectric focusing analyses demonstrated that the LM(TK^-)/CRB cells contained chick cytosol, but not mouse cytosol dT kinase. The LM(TK^-)/CRB cells also contained mouse mitochondrial, but not chick mitochondrial dT kinase. Hence, the clonal lines were somatic cell hybrids and not LM(TK^-) cell revertants. The experiments demonstrate that chick erythrocyte cytosol dT kinase can be activated in heterokaryons and in hybrid cells, most likely as a result of functions supplied by mouse fibroblast cells.     

Linkage relationship between the genes for thymidine kinase and galactokinase in different primates.

In this study we investigated the expression of primate galactokinase in somatic cell hybrids between a thymidine kinase-deficient mouse cell line and two different primate cell lines, one of which was derived from African green monkey kidney cells and the other from chimpanzee fibroblasts. All the African green monkey-mouse hybrid clones, selected in HAT medium, expressed monkey galactokinase activity and contained a monkey chromosome similar to a human E-group chromosome. When these clones were backselected in medium containing 5-bromodeoxyuridine, both this chromosome and the monkey galactokinase activity were lost. All the hybrid clones between mouse and chimpanzee cells, which were selected in HAT medium, contained the chimpanzee chromosome 17 and expressed chimpanzee galactokinase activity. These results indicate that the linkage relationship between galactokinase and thymidine kinase has been maintained in 3 divergent primate species--man, chimpanzee, and Old World monkey.     

Mitochondrial and herpesvirus-specific deoxypyrimidine kinases.

To characterize and compare the thymidine (TdR) and deoxycytidine (CdR) kinase isozymes of uninfected and herpesvirus-infected cells: (i) the subcellular distribution of the isozymes has been studied; (ii) a specific assay for CdR kinase has been devised; (iii) the TdR kinase isozymes have been partially purified; and (iv) the purified enzymes have been analyzed by disc polyacrylamide gel electrophoresis, isoelectric focusing, and glycerol gradient centrifugation and by substrate competition and dCTP inhibition studies. The results indicate that there are interesting individual differences with respect to nucleoside acceptor specificity between the cytosol and mitochondrial pyrimidine deoxyribonucleoside kinases of uninfected cells and between the enzymes induced by different herpesviruses. In the cytosol of uninfected mouse, chicken, and owl monkey kidney cells, two different proteins, TdR kinase F and CdR kinase 2, catalyze the phosphorylations of TdR and CdR, respectively. TdR kinase F does not phosphorylate CdR, nor does CdR kinase 2 phosphorylate TdR. A second TdR kinase isozyme present in HeLa(BU25) mitochondria (TdR kinase B) also lacks CdR phosphorylating activity. In contrast, a genetically distinctive deoxypyrimidine kinase (TdR kinase A) of mouse, human, and chick mitochondria catalyzes the phosphorylation of both TdR and CdT. Three herpesviruses, marmoset herpesvirus and herpes simplex virus types 1 and 2, induce in the cytosol fraction of LM(TK-) mouse cells isozymes which share common properties with mitochondrial TdR kinase A, including the ability to catalyze the phosphorylation of both TdR and CdR. However, the herpesvirus-induced deoxypyrimidine kinases differ from mitochondrial TdR kinase A with respect to sedimentation coefficient, sensitivity to dCTP inhibition, and antigenic determinants. The herpesvirus-specific and the mitochondrial deoxypyrimidine kinases exhibit a preference for TdR over CdR as nucleoside acceptor. Pseudorabies virus and herpesvirus of turkeys induce cytosol TdR kinases resembling the other herpesvirus-induced TdR kinases in several properties, but like cellular TdR kinase F, the pseudorabies virus and herpesvirus of turkeys TdR kinases lack detectable CdR phosphorylating activities. Finally, a marmoset herpesvirus nutant resistant to bromodeoxyuridine, equine herpesvirus type 1, and Herpesvirus aotus induces neither TdR nor CdR phosphorylating enzymes during productive infections.     

Identification of chick thymidine kinase determinant in somatic cell hybrids of chick erythrocytes and thymidine kinase-deficient mouse cells

Disc polyacrylamide gel electrophoresis (disc PAGE) analyses of chick-mouse somatic cell hybrids [LM(TK⁻)/CRB]isolated from fusion mixtures of chick erythrocytes and thymidine (TdR) kinase-deficient mouse [LM(TK⁻)]cells have demonstrated that the somatic cell hybrids contain only chick cytosol TdR kinase F and mouse mitochondrial TdR kinase A activities. Karyotypes were analysed by the method which sequentially reveals Q- and C-bands. Four hybrid clones contained the full complement of mouse chromosomes and 1 to 3 chick micro-chromosomes. Counterselection of the LM(TK⁻)/CRB hybrids in 5-bromodeoxyuridine (BUdR) medium resulted in the loss of chick cytosol TdR kinase F activity and at least one of the chick chromosomes, but mouse mitochondrial TdR kinase A activity was unaffected. Unlike the LM(TK⁻)/CRB somatic cell hybrids, the BUdR-resistant clones could not grow in HATG (hypoxanthine-aminopte-rin-thymidine-glycine) medium. The results demonstrate that: (1) the chick cytosol TdR kinase F gene is on a member of the micro-chromosomes; and (2) selection in HATG- and BUdR-containing medium involves only cytosol TdR kinase F.     

Identification and characterization of tyrosine kinase activity associated with mitochondrial outer membrane in sarcoma 180 cells

Tyrosine protein kinase activity has been detected in the mitochondrial fraction purified from sarcoma 180 tumor cells. Following hypotonic disruption of mitochondria, tyrosine kinase activity appeared to cosediment with monamine oxidase, marker enzyme of mitochondrial outer membrane; meanwhile, serine and threonine kinases were found to be associated with the inner membrane and matrix of mitochondria. Mitochondrial tyrosine kinase(s) showed thermosensitivity and Mn2+ dependence, useful properties for its characterization and separation from tyrosine kinases associated with other particulate fraction and from serine and threonine kinases associated with mitochondria. Following in vitro incubation of mitochondria with labelled ATP as substrate and analysis by PAGE, a complex pattern of phosphotyrosine containing proteins with a major band of 50-55 kilodaltons resulted.     

Plants Salvage Deoxyribonucleosides in Mitochondria

Deoxyribonucleoside kinases phosphorylate deoxyribonucleosides into the corresponding 5′-monophosphate deoxyribonucleosides to supply the cell with nucleic acid precursors. In mitochondrial fractions of the model plant Arabidopsis thaliana, we detected deoxyadenosine and thymidine kinase activities, while the cytosol fraction contained six-fold lower activity and chloroplasts contained no measurable activities. In addition, a mitochondrial fraction isolated from the potato Solanum tuberosum contained thymidine kinase and deoxyadenosine kinase activities. We conclude that an active salvage of deoxyribonucleosides in plants takes place in their mitochondria. In general, the observed localization of the plant dNK activities in the mitochondrion suggests that plants have a different organization of the deoxyribonucleoside salvage compared to mammals.     

Bystander effects of nucleoside analogs phosphorylated in the cytosol or mitochondria

The efficiency of nucleoside kinase suicide gene therapy for cancer is highly dependent on "bystander" cell killing, i.e., the transfer of cytotoxic phosphorylated nucleoside analogs to cells adjacent to those expressing the suicide enzyme. We have recently studied the possible use of mitochondrial nucleoside kinases as suicide genes. In the present study, we investigated if nucleoside analogs phosphorylated in the mitochondrial matrix cause bystander killing. We used deoxycytidine kinase-deficient Chinese hamster ovary cells reconstituted with deoxycytidine kinase targeted to either the cytosol or mitochondria matrix and determined the bystander cell killing when these cells were incubated with the nucleoside analogs 1-beta-D-arabinofuranosylcytosine and 2',2'-difluorodeoxycytidine. A bystander effect occurred when nucleoside analogs were phosphorylated in the cytosol, but not when these compounds were phosphorylated in the mitochondria. These findings suggest that nucleoside kinases targeted to the mitochondrial matrix have limited use in suicide gene therapy when efficient bystander cell killing is required.     

PINK1 kinase dysfunction triggers neurodegeneration in the primate brain without impacting mitochondrial homeostasis

In vitro studies have established the prevalent theory that the mitochondrial kinase PINK1 protects neurodegeneration by removing damaged mitochondria in Parkinson's disease(PD).However,difficulty in detecting endogenous PINK1 protein in rodent brains and cell lines has prevented the rigorous investigation of the in vivo role of PINK1.Here we report that PINK1 kinase form is selectively expressed in the human and monkey brains.CRISPR/Cas9-mediated deficiency of PINK1 causes similar neurodegeneration in the brains of fetal and adult monkeys as well as cultured monkey neurons without affecting mitochondrial protein expression and morphology.Importantly,PINK1 mutations in the primate brain and human cells reduce protein phosphorylation that is important for neuronal function and survival.Our findings suggest that PINK1 kinase activity rather than its mitochondrial function is essential for the neuronal survival in the primate brains and that its kinase dysfunction could be involved in the pathogenesis of PD.     

Characterization of mitochondrial DNA in chloramphenicol-resistant interspecific hybrids and a cybrid

We have examined the restriction endonuclease cleavage patterns exhibited by the mitochondrial DNAs (mtDNA) of four chloramphenicol-resistant (CAPR) human x mouse hybrids and one CAPR cybrid derived from CAPR HeLa cells and CAPS mouse RAG cells. Restriction fragments of mtDNAs were separated by electrophoresis and transferred by the Southern technique to diazobenzyloxymethyl paper. The covalently bound DNA fragments were hybridized initially with 32P-labeled complementary RNA (cRNA) prepared from human mtDNA and, after removal of the human probe, hybridized with mouse [32P]cRNA prepared from mouse mtDNA. Three hybrids which preferentially segregated human chromosomes and the cybrid exhibited mtDNA fragments indistinguishable from mouse cells. One hybrid, ROH8A, which exhibited "reverse" chromosome segregation, contained only human mtDNA. The pattern of chromosome and mtDNA segregation observed in these hybrids and the cybrid support the hypothesis that a complete set of human chromosomes must be retained if a human-mouse hybrid is to retain human mitochondrial DNA.     

Submitochondrial localization and characteristics of thymidine kinase molecular forms in parental and kinase-deficient hela cells

Although HeLa (BU25) cells are deficient in cytosol dT kinase activity, they contain two mitochondrial dT kinases with disc PAGE mobilities (R _m) of 0.4 and 0.6 and isoelectric points (pI) of 8.4 and 5.6, respectively. Mitochondrial extracts of parental HeLa S3 contain the two HeLa (BU25) activities, but also a cytosol-like enzyme (0.25 R _m, pI 9.8). The 0.6-R _m (pI 5.6) mitochondrial activity utilizes ribonucleoside 5′-triphosphates other than ATP (dATP) as phosphate donors and is sensitive to dCTP inhibition. The predominant HeLa S3 cytosol (0.25 R _m) enzyme and the 0.4 R _m mitochondrial enzymeefficiently utilize only ATP as a phosphate donor and are relatively insensitive to dCTP inhibition. Submitochondrial fractionation studies have shown that (1) 74–98% of the mitochondrial dT kinase is located in the matrix plus inner membrane fractions; (2) the matrix fraction has the highest specific activity, contains all the 0.6-R _m activity, most of the HeLa S3 0.25-R _m activity, and some 0.4-R _m activity; (3) the inner membrane fraction is the major site of the 0.4-R _m activity but the outer membrane fraction also contains the 0.4 R _m activity; and (4) all HeLa S3 submitochondrial fractions contain the 0.25-R _m dT kinase activity.     

Incorporation of nucleoside analogs into nuclear or mitochondrial DNA is determined by the intracellular phosphorylation site

Nucleoside analogs used in cancer chemotherapy and in treatment of virus infections are phosphorylated in cells by nucleoside and nucleotide kinases to their pharmacologically active form. The phosphorylated nucleoside analogs are incorporated into DNA and cause cell death or inhibit viral replication. Cellular DNA is replicated both in the nucleus and in the mitochondria, and nucleoside analogs may interfere with DNA replication in both these subcellular locations. In the present study we created a cell model system where nucleoside analogs were phosphorylated, and thereby pharmacologically activated, in either the nucleus, cytosol, or mitochondria of cancer cells. The system was based on the reconstitution of deoxycytidine kinase (dCK)-deficient Chinese hamster ovary cells with genetically engineered dCK targeted to the different subcellular compartments. The nucleoside analogs phosphorylated by dCK in the mitochondria were predominantly incorporated into mitochondrial DNA, whereas the nucleoside analogs phosphorylated in the nucleus or cytosol were incorporated into nuclear DNA. We further show that the nucleoside analogs phosphorylated in the mitochondria induced cell death by an apoptotic program. These data showed that the subcellular site of nucleoside analog phosphorylation is an important determinant for incorporation of nucleoside analogs into nuclear or mitochondrial DNA.     

X-chromosome inactivation in monkey embryos and pluripotent stem cells

Inactivation of one X chromosome in female mammals (XX) compensates for the reduced dosage of X-linked gene expression in males (XY). However, the inner cell mass (ICM) of mouse preimplantation blastocysts and their in vitro counterparts, pluripotent embryonic stem cells (ESCs), initially maintain two active X chromosomes (XaXa). Random X chromosome inactivation (XCI) takes place in the ICM lineage after implantation or upon differentiation of ESCs, resulting in mosaic tissues composed of two cell types carrying either maternal or paternal active X chromosomes. While the status of XCI in human embryos and ICMs remains unknown, majority of human female ESCs show non-random XCI. We demonstrate here that rhesus monkey ESCs also display monoallelic expression and methylation of X-linked genes in agreement with non-random XCI. However, XIST and other X-linked genes were expressed from both chromosomes in isolated female monkey ICMs indicating that ex vivo pluripotent cells retain XaXa. Intriguingly, the trophectoderm (TE) in preimplantation monkey blastocysts also expressed X-linked genes from both alleles suggesting that, unlike the mouse, primate TE lineage does not support imprinted paternal XCI. Our results provide insights into the species-specific nature of XCI in the primate system and reveal fundamental epigenetic differences between in vitro and ex vivo primate pluripotent cells.     

The role of contact sites between inner and outer mitochondrial membrane in energy transfer

Three functions have been suggested to be localized in contact sites between the inner and the outer membrane of mitochondria from mammalian cells: (i) transfer of energy from matrix to cytosol through the action of peripheral kinases; (ii) import of mitochondrial precursor proteins; and (iii) transfer of lipids between outer and inner membrane. In the contact site-related energy transfer a number of kinases localized in the periphery of the mitochondrion play a crucial role. Two examples of such kinases are relevant here: (i) hexokinase isoenzyme I which is capable of binding to the outer aspect of the outer membrane; and (ii) the mitochondrial isoenzyme of creatine kinase which is localized in the intermembrane space. Recently, evidence was presented that both hexokinase and creatine kinase are preferentially localized in contact sites (Adams, V. et al. (1989) Biochim. Biophys. Acta 981, 213-225). The aim of the present experiments was two-fold. First, to establish methods which enable the bioenergetic aspects of energy transfer mediated by kinases in contact sites to be measured. In these experiments emphasis was on hexokinase, while 31P-NMR was the major experimental technique. Second, we wanted to develop methods which can give insight into factors playing a role in the formation of contact sites involved in energy transfer. In the latter approach, mitochondrial creatine kinase was studied using monolayer techniques.     

Interaction of 9-(1,3-dihydroxy-2-propoxymethyl)guanine with cytosol and mitochondrial deoxyguanosine kinases: possible role in anti-cytomegalovirus activity

Summary The acyclic nucleoside 9-(1,3-dihydroxy-2-propoxymethyl)guanine (DHPG) is a potent inhibitor of human cytomegalovirus in vitro and in vivo. In order to investigate the phosphorylation of DHPG to the monophosphate and identify the enzyme responsible, attempts were made to isolate DHPG kinase from calf thymus and from human cytomegalovirus-infected lung cells. From calf thymus, a mitochondrial deoxyguanosine kinase was partially purified which co-migrated with DHPG phosphorylating activity on DEAE-cellulose, and had the same mobility by electrophoresis. DHPG triphosphate and DHPG kinase were elevated in cytomegalovirus-infected cells, but not enough enzyme activity was recovered to identify the kinase. However, DHPG was found to inhibit a cytosol deoxyguanosine kinase induced in these infected cells. The role of mitochondrial and cytosol deoxyguanosine kinases is discussed relative to the anti-cytomegalovirus activity of DHPG.     

Mammalian Mitochondrial and Cytosolic Folylpolyglutamate Synthetase Maintain the Subcellular Compartmentalization of Folates

Folylpoly-γ-glutamate synthetase (FPGS) catalyze the addition of multiple glutamates to tetrahydrofolate derivatives. Two mRNAs for the fpgs gene direct isoforms of FPGS to the cytosol and to mitochondria in mouse and human tissues. We sought to clarify the functions of these two compartmentalized isoforms. Stable cell lines were created that express cDNAs for the mitochondrial and cytosolic isoforms of human FPGS under control of a doxycycline-inducible promoter in the AUXB1 cell line. AUXB1 are devoid of endogenous FPGS activity due to a premature translational stop at codon 432 in the fpgs gene. Loss of folates was not measurable from these doxycycline-induced cells or from parental CHO cells over the course of three CHO cell generations. Likewise, there was no detectable transfer of folate polyglutamates either from the cytosol to mitochondria, or from mitochondria to the cytosol. The cell line expressing cytosolic FPGS required exogenous glycine but not thymidine or purine, whereas cells expressing the mitochondrial isoform required exogenous thymidine and purine but not glycine for optimal growth and survival. We concluded that mitochondrial FPGS is required because folate polyglutamates are not substrates for transport across the mitochondrial membrane in either direction and that polyglutamation not only traps folates in the cytosol, but also in the mitochondrial matrix.     

Screening of protein kinase inhibitors and knockdown experiments identified four kinases that affect mitochondrial ATP synthesis activity

Mitochondrial ATP synthase, a major ATP supplier in respiring cells, should be regulated in amount and in activity to respond to the varying demands of cells for ATP. We screened 80 protein kinase inhibitors and found that HeLa cells treated with four inhibitors exhibited reduced mitochondrial ATP synthesis activity. Consistently, knockdown of their target kinases (PKA, PKCδ, CaMKII and smMLCK) resulted in a decrease in mitochondrial ATP synthesis activity. Among them, mitochondria of smMLCK-knockdown cells contained only a small amount of ATP synthase, while the α- and β-subunits of ATP synthase were produced normally, suggesting that smMLCK affects assembly (or decay) of ATP synthase.