Changes in Properties of Succinate Dehydrogenase during Senescence of Pea Cotyledons

Comparisons were made between succinate dehydrogenases (EC 1.3.99.1 [EC] )from 1-day-old and 5-day-old pea cotyledons. The enzyme wasloosely bound to the mitochondrial inner membrane in 5-day-oldcotyledons, but tightly in 1-day-old cotyledons. In addition,the enzyme partially purified from 5-day-old cotyledons wasmuch more labile than that from 1-day-old cotyledons. Succinaterapidly inactivated partially purified succinate dehydrogenasefrom 1-day-old cotyledons, but not from 5-day-old cotyledons.Dithiothreitol caused a change in the charge of the enzyme proteinfrom either 1- or 5-day-old cotyledons, only when succinatewas present. The enzyme from 5-day-old cotyledons differed fromthe succinate-induced labile form of the enzyme from 1-day-oldcotyledons in electrophoretic properties on a polyacrylamidegel. There was also a difference in the pattern of polyacrylamidegel electrophoresis between succinate dehydrogenases partiallypurified from 1- and 5-day-old cotyleodns. The partially purifiedenzyme from either 1- or 5-day-old cotyledons in the presenceof succinate had a molecular weight of 92,000. The molecularweight of the large subunit was suggested to be 65,000. Thepartially purified enzyme prepared from 1-day-old cotyledonsin the absence of succinate was in a form with a molecular weightof 113,000. (Received August 29, 1980; Accepted December 3, 1980)     

Biochemical Properties of Mitochondrial Membrane from Dry Pea Seeds and Changes in the Properties during Imbibition

An attempt to isolate intact mitochondria from dry pea seeds (Pisum sativum var. Alaska) ended in failure. Cytochrome oxidase in crude mitochondrial fraction from dry seeds was separated into three fractions by sucrose density gradient centrifugation. Two of the fractions contained malate dehydrogenase, whereas the other did not. Equilibrium centrifugation of mitochondrial membrane on sucrose gradients revealed that the membrane from the fraction without malate dehydrogenase was lighter than that from the others. Differences were observed in relative content of phospholipid to protein and in polypeptide composition analyzed by sodium dodecyl sulfate-polyacrylamide gel electrophoresis among the membranes from three fractions and imbibed cotyledons. Membrane from the fraction without malate dehydrogenase was rich in phospholipid and lacking in polypeptides with relatively high molecular weights as compared with that from others. During imbibition, the fraction without malate dehydrogenase and one of the other two disappeared rapidly after a lag phase lasting for at least 1 hour. Concomitantly, active and stable mitochondria increased in the cotyledons. The results were interpreted to indicate that there were at least three types of mitochondria in dry seeds, the membranes of which differed in their biochemical properties, and that the mitochondria became active and stable through assembly of protein into the membranes during imbibition.     

Development of Mitochondrial Activity in Pea Cotyledons Following Imbibition; Influence of the Embryonic Axis

The development of mitochondria in cotyledons during the initialstages following imbibition and the subsequent degenerationwere faster when the embryonic axis was attached. This was moreclearly demonstrated when mitochondrial activity was determinedusing malate or -oxoglutarate as substrate rather than NADHor succinate. Cycloheximide did not inhibit the initial developmentof mitochondria in attached cotyledons, although it inhibitedthe incorporation of ¹⁴C-amino acid into protein. Abscisic acidinhibited almost completely the initial increase in mitochondrialactivities of attached cotyledons. The activities of severalenzymes in mitochondrial fractions were almost the same in attachedand detached cotyledons during 4 d after, imbibition. The degenerationof mitochondria was not accompanied by the loss of enzymes.It was inferred that the initial development and the subsequentdegeneration of mitochondria in cotyledons during 4 d afterimbibition was brought about by the structural improvement anddisorganization of mitochondria, respectively. The initial differencesin the development of mitochondrial activities between attachedand detached cotyledons were suggested to be attributable todifferences in the development of the activities of electrontransfer pathway from endogenous NADH to ubiquinone.     

Development of Mitochondrial Activities in Pea Cotyledons during and following Germination of the Axis

Development of mitochondrial activities in pea cotyledons during early times after the start of imbibition occurred in two phases. In the first phase (0 to 8 hours after the start of imbibition), succinate or NADH oxidation increased rapidly, while malate or α-ketoglutarate oxidation remained low. The latter activities developed only 8 to 12 hours after the start of imbibition (the second phase). Development in the first phase was induced by water uptake, but some development occurred even when the cotyledons were fully imbibed. The presence of the axis was required for the second phase of the development. It is suggested that mitochondrial development in the second phase is brought about by activation of the electron transfer path at a site between the oxidation of endogenous NADH and the reduction of ubiquinone.     

Acyl-CoA Synthetase Is Located in the Outer Membrane and Acyl-CoA Thioesterase in the Inner Membrane of Pea Chloroplast Envelopes

Both acyl-CoA synthetase and acyl-CoA thioesterase activities are present in chloroplast envelope membranes. The functions of these enzymes in lipid metabolism remains unresolved, although the synthetase has been proposed to be involved in either plastid galactolipid synthesis or the export of plastid-synthesized fatty acids to the cytoplasm. We have examined the locations of both enzymes within the two envelope membranes of pea (Pisum sativum var Laxton's Progress No. 9) chloroplasts. Inner and outer envelope membranes were purified from unfractionated envelope preparations by linear density sucrose gradient centrifugation. Acyl-CoA synthetase was located in the outer envelope membrane while acyl-CoA thioesterase was located in the inner envelope membrane. Thus, it seems unlikely that the synthetase is directly involved in galactolipid assembly. Instead, its localization supports the hypothesis that it functions in the transport of plastid-synthesized fatty acids to the endoplasmic reticulum.     

Mitofilin Is a Transmembrane Protein of the Inner Mitochondrial Membrane Expressed as Two Isoforms

Mitofilin, also known as heart muscle protein, is a recently identified mitochondrial protein. We have isolated two human cDNAs that encode different isoforms of mitofilin. Using reverse PCR, we provide evidence that both isoforms are derived by alternative splicing and encode two proteins of 88 and 90 kDa that are detected in immunoblot analyses with mitofilin-specific antibodies. Immunofluorescence microscopy, fractionating of human osteosarcoma cells, and protease protection experiments with isolated mitochondria and mitoplasts indicate that mitofilin is an integral membrane protein of the inner mitochondrial membrane.³⁵S-labeled mitofilin is transported into isolated yeast mitochondria in a reaction that depends on the membrane potential across the inner mitochondrial membrane (ΔΨ). During mitochondrialin vitroimport, mitofilin is proteolytically processed to the mature protein that is also detected in cellular fractions, indicating that the amino-terminal leader sequence is removed. Sequence analysis and our results suggest that mitofilin is anchored in the inner mitochondrial membrane with an amino-terminal transmembrane domain, while the majority of the protein is extruding into the intermembrane space.     

Proteins of the Inner Membrane of Escherichia coli: Identification of Succinate Dehydrogenase by Polyacrylamide Gel Electrophoresis with sdh Amber Mutants

The inner or cytoplasmic membrane fraction of the cell envelope of Escherichia coli was isolated by isopycnic centrifugation on sucrose gradients. The membrane proteins were analyzed by electrophoresis in sodium dodecyl sulfate-polyacrylamide gels (8.5%), and up to 56 bands were resolved. Different preparations gave very similar patterns of proteins. Succinate dehydrogenase mutants (sdh) were isolated which could not grow on succinate minimal medium, although growth on fumarate was unimpaired. The protein patterns of inner membrane preparations from sdh amber mutants were compared with the wild type, and one major band was greatly reduced in the mutants. This component, which represented approximately 5% of the inner membrane protein, was restored by introducing an amber suppressor gene (supU), which also restored the Sdh(+) phenotype. The band corresponded to a protein with a molecular weight of 67,000 daltons, which is close to that for the large subunits of the succinate dehydrogenases of Rhodospirillum rubrum and beef heart mitochondria.     

Rapid Development of Mitochondria in Pea Cotyledons during the Early Stage of Germination

Rapid increases in activities and components of mitochondrial particles isolated from cotyledons of Pisum sativum var. Alaska during the early stage of germination are described. Respiratory rate of the cotyledons increased rapidly as hydration proceeded. A similar but slightly delayed increase in respiratory activity of the isolated mitochondrial fraction was observed. The respiratory control ratio and adenosine 5′-pyrophosphate/oxygen ratio rose during imbibition. Cytochrome oxidase and malate dehydrogenase activities in the mitochondrial fraction increased during the initial phase of imbibition. The increase seemed to precede that in respiratory activity. A significant activity of cytochrome oxidase and most of the malate dehydrogenase activity in the cotyledons were present in the postmitochondrial fraction in the case of the dry seeds. Mitochondrial protein and phospholipid also increased during imbibition, and the rise in the components seemed to concur with that in respiratory activity. The mechanism of mitochondrial development during imbibition is discussed.     

Calcium-Dependent Nonspecific Permeability of the Inner Mitochondrial Membrane Is Not Induced in Mitochondria of the Yeast Endomyces magnusii

Mitochondria of the yeast Endomyces magnusii were examined for the presence of a Ca2+- and phosphate-induced permeability of the inner mitochondrial membrane (pore). For this purpose, coupled mitochondria were incubated under conditions known to induce the permeability transition pore in animal mitochondria, i.e., in the presence of high concentrations of Ca2+ and P(i), prooxidants (t-butylhydroperoxide), oxaloacetate, atractyloside (an inhibitor of ADP/ATP translocator), SH-reagents, by depletion of adenine nucleotide pools, and deenergization of the mitochondria. Large amplitude swelling, collapse of the membrane potential, and efflux of the accumulated Ca2+ were used as parameters for demonstrating pore induction. E. magnusii mitochondria were highly resistant to the above-mentioned substances. Deenergization of mitochondria or depletion of adenine nucleotide pools have no effect on low-amplitude swelling or the other parameters. Cyclosporin A, a specific inhibitor of the nonspecific permeability transition in animal mitochondria, did not affect the parameters measured. It is thus evident that E. magnusii mitochondria lack a functional Ca2+-dependent pore, or possess a pore differently regulated as compared to that of mammalian mitochondria.     

ATP Synthesis in Cotyledons of Cucumber and Mung Bean Seeds during the First Hours of Imbibition

ATP concentration increased rapidly during the first 6h of imbibitionin cotyledons of cucumber and mung bean seeds. The increasewas strongly inhibited by 1-h treatment of tissues with cyanidein both species. Carbonylcyanide m-chlorophenylhydrazone, anuncoupler of oxidative phosphorylation, showed little effectduring the first hour of the treatment, but its inhibitory effecton ATP synthesis became significant after 3 h. Mitochondrialfractions prepared from 6-h-old cucumber cotyledons were capableof phosphorylating ADP to ATP. These results suggest that mitochondrialoxidative phosphorylation may be involved in ATP synthesis duringthe early hours of imbibition in both cucumber and mung beanseeds. (Received December 7, 1987; Accepted April 9, 1988)     

Respiration Rate, Mitochondrial Activity and Mitochondrial Structure in the Cotyledons of Phaseolus vulgaris L. during Germination

Parallel observations have been made on changes in respirationrate, mitochondrial activity, and the fine structure of mitochondria,in the cotyledons of Phaseolus vulgaris germinating at 25^? Cin the dark. While oxygen uptake of the intact cotyledons risesto a peak between the third and fifth days of germination, mitochondrialactivity falls from 36 hours onwards. In most of the storagecells, mitochondrial cristae have become swollen and the matrixhas darkened by the third day. The continulng rise in respirationrate beyond 36 hours could be accounted for by the increasein soluble oxidative activity, which occurs while mitochondrialactivity is falling. Alternatively, it could be mediated bymitochondria from the vascular bundle cells, where swellingand darkening are delayed till after the fifth day of germination,and where there is proliferation of cristae till the fourthday.     

Changes in the Content of Phytochrome I and II Apoproteins in Embryonic Axes of Pea Seeds during Imbibition

The contents of phytochrome I and II in crude extracts fromembryonic axes of Pisum sativum cv. Alaska seeds were immunochemicallydetermined using purified pea phytochrome I and II as standards.We have produced and used three different types of mouse monoclonalanti-pea phytochrome antibodies (mAP) such as one reacting preferentiallywith phytochrome I, one with phytochrome II, and one with bothI and II. Phytochrome II was separated from I in the samplesusing immobilized column chromatography with mAPl. The amountsof two phytochrome species were quantitatively measured withwestern blotting and ELISA. Ca. 0.2 µg /axis of phytochromeI and ca. 0.05 µg /axis of phytochrome II were detectedby ELISA after imbibition for 12 h in the dark, though smallamounts of both were detected in dry axes. Ca. 0.05 µg/axis each of phytochrome I and II were detected by ELISA afterimbibition for 12 h in the light, and the results were confirmedby western blotting. This study showed that phytochrome II isnot green-tissue-specific, being also found in dark-imbibedembryonic axes, and that although light significantly lowersthe content of phytochrome I in the axis, it does not significantlyaffect that of phytochrome II. (Received June 10, 1987; Accepted August 27, 1987)     

Transport of Phosphatidylserine from Microsomes to the Inner Mitochondrial Membrane in Brain Tissue

Abstract: Phosphatidylserine was labeled by incubating rat brain homogenates with [3-¹⁴C]serine in the presence of Ca²⁺ (base-exchange conditions). Some labeled phosphati-dylethanolamine also forms, in spite of the inhibition of Ca²⁺ on phosphatidylserine decarboxylase. Phosphatidylserine labeling and decarboxylation also occur on incubating a mixture of purified mitochondria and microsomes, suggesting that no soluble factors are necessary for the synthesis and the decarboxylation of phosphatidylserine. Ca²⁺ favors the transfer of phosphatidylserine from microsomes (where it forms) to mitochondria (where it is decarboxylated). The specific radioactivity of the phosphatidylserine transferred to mitochondria is higher than that of microsomal phosphatidylserine. This finding supports the hypothesis that the lipid is compartmentalized in microsomes and that radioactive, newly synthesized phosphatidylserine is much better exported than the bulk of microsomal phospholipid.     

The Tim54p–Tim22p Complex Mediates Insertion of Proteins into the Mitochondrial Inner Membrane

We have identified a new protein, Tim54p, located in the yeast mitochondrial inner membrane. Tim54p is an essential import component, required for the insertion of at least two polytopic proteins into the inner membrane, but not for the translocation of precursors into the matrix. Several observations suggest that Tim54p and Tim22p are part of a protein complex in the inner membrane distinct from the previously characterized Tim23p-Tim17p complex. First, multiple copies of the TIM22 gene, but not TIM23 or TIM17, suppress the growth defect of a tim54-1 temperature-sensitive mutant. Second, Tim22p can be coprecipitated with Tim54p from detergent-solubilized mitochondria, but Tim54p and Tim22p do not interact with either Tim23p or Tim17p. Finally, the tim54-1 mutation destabilizes the Tim22 protein, but not Tim23p or Tim17p. Our results support the idea that the mitochondrial inner membrane carries two independent import complexes: one required for the translocation of proteins across the inner membrane (Tim23p–Tim17p), and the other required for the insertion of proteins into the inner membrane (Tim54p–Tim22p).     

Dual Role of Mitochondrial Porin in Metabolite Transport across the Outer Membrane and Protein Transfer to the Inner Membrane

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内毒素休克大鼠肝线粒体质子跨膜转运的改变

用稳态荧光探针标记技术动态观察内毒素休克大鼠肝亚线粒体质子跨膜转运的变化.发现,休克5 h ATP、NADH和琥珀酸钠所致的9-氨基-6-氯-2-甲氧基吖啶(ACMA）最大荧光淬灭值（ΔA_max）显著低于对照组(P＜0.05)、最大荧光淬灭时间（T_ΔAmax）、半数荧光淬灭时间（T_1/2ΔAmax）非常显著延长(P＜0.01),肝线粒体质子跨膜转运能力下降;膜脂分子烃链和膜脂深层次流动性下降;线粒体膜PLA₂活性增加;血浆脂质过氧化产物MDA和线粒体MDA含量均显著增加.可能膜脂质过氧化和磷脂酶A₂的水解是引起内毒素休克肝线粒体质子转运功能改变的重要因素.     

Sym2 of Pea Is Involved in a Nodulation Factor-Perception Mechanism That Controls the Infection Process in the Epidermis

In pea (Pisum sativum) up to 50 nodulation mutants are known, several of which are affected in the early steps of the symbiotic interaction with Rhizobium sp. bacteria. Here we describe the role of the sym2 gene in nodulation (Nod) factor perception. Our experiments show that the sym2A allele from the wild pea variety Afghanistan confers an arrest in infection-thread growth if the Rhizobium leguminosarum bv viciae strain does not produce Nod factors with a NodX-mediated acetylation at their reducing end. Since the induction of the early nodulin gene ENOD12 in the epidermis and the formation of a nodule primordium in the inner cortex were not affected, we conclude that more than one Nod factor-perception mechanism is active. Furthermore, we show that sym2A-mediated control of infection-thread growth was affected by the bacterial nodulation gene nodO.     

Protein Synthesis in the Axes of Polyethylene Glycol-Treated Pea Seed and during Subsequent Germination

Germination of Alaska pea seeds is inhibited by –0.3 MPapolyethylene glycol but upon subsequent transfer to water, germinationis completed rapidly and radicle emergence occurs more quicklythan in water-imbibed seeds. Protein synthesis is reduced inthe axes of seeds imbibed on PEG but increases upon their returnto water, though not to the level exhibited by axes germinatedon water. Mobilization of proteins in the axes is retarded bytheir failure to complete germination on PEG, although somedoes occur. The quantitative reduction in protein synthesisresulting from incubation in osmoticum is not accompanied bymarked qualitative changes. The block to germination is notobviously associated with a restriction in synthesis of anyparticular protein or set of proteins; conversely, no ‘water-stress’proteins are synthesized in the presence of PEG. The synthesisof growth-specific proteins is prevented by PEG, but these increaseupon relief from the osmoconditioning treatments. These observationsdispute earlier claims for accelerated protein synthesis resultingfrom PEG treatments. Key words: Osmotic priming, Pisum sativum, germination, protein synthesis     

Development of Microbody Membrane Proteins during the Transformation of Glyoxysomes to Leaf Peroxisomes in Pumpkin Cotyledons

The microbody transition observed in the cotyledons of somefatty seedlings involves the conversion of glyoxysomes to leafperoxisomes. To clarify the molecular mechanisms underlyingthe microbody transition, we established a method for the preparationof highly purified microbodies. SDS-PAGE and immunoblot analysisof isolated microbodies from pumpkin cotyledons at various stagesshowed that glyoxysomal enzymes are replaced by leaf-peroxisomalenzymes during the microbody transition. Two proteins in glyoxysomalmembranes, with molecular masses of 31 kDa and 28 kDa, werenot solubilized from the membranes with 0.2 M KCl, an indicationthat these proteins are bound tightly with glyoxysomal membranes.Their polyclonal antibodies were raised against the respectivepurified protein. Immunoblot analysis of subcellular fractionsand immunogold analysis confirmed that these proteins were specificallylocalized on glyoxysomal membranes. Analysis of these membraneproteins during development revealed that the amounts of thesemembrane proteins decreased during the microbody transitionand that the large one was retained in leaf peroxisomes, whereasthe small one could not be found in leaf peroxisomes after completionof the microbody transition. The results clearly showed thatmembrane proteins in glyoxysomes change dramatically duringthe microbody transition, as do the enzymes in the matrix. ¹Present address: School of Agriculture, Nagoya University Chikusa,Nagoya, 464-01 Japan.     

p53 Is Required for Cisplatin-induced Processing of the Mitochondrial Fusion Protein L-Opa1 That Is Mediated by the Mitochondrial Metallopeptidase Oma1 in Gynecologic Cancers

Mitochondria are highly dynamic organelles, and mitochondrial fission is a crucial step of apoptosis. Although Oma1 is believed to be responsible for long form Opa1 (L-Opa1) processing during mitochondrial fragmentation, whether and how Oma1 is involved in L-Opa1 processing and participates in the regulation of chemoresistance is unknown. Chemosensitive and chemoresistant ovarian (OVCA) and cervical (CECA) cancer cells were treated with cisplatin (CDDP). Mitochondrial dynamics and protein contents were assessed by immunofluorescence and Western blot, respectively. The requirements of Oma1 and p53 for CDDP-induced L-Opa1 processing, mitochondrial fragmentation, and apoptosis were examined by siRNA or cDNA. CDDP induces L-Opa1 processing and mitochondrial fragmentation in chemosensitive but not in chemoresistant cells. CDDP induced Oma1 40-kDa form increases in OV2008 cells, not in C13* cells. Oma1 knockdown inhibited L-Opa1 processing, mitochondrial fragmentation, and apoptosis. Silencing p53 expression attenuated the effects of CDDP in Oma1 (40 kDa) increase, L-Opa1 processing, mitochondrial fragmentation, and apoptosis in chemosensitive OVCA cells, whereas reconstitution of p53 in p53 mutant or null chemoresistant OVCA cells induced Oma1 (40 kDa) increase, L-Opa1 processing, mitochondrial fragmentation, and apoptosis irrespective of the presence of CDDP. Prohibitin 1 (Phb1) dissociates from Opa1-Phb1 complex and binds phosphorylated p53 (serine 15) in response to CDDP in chemosensitive but not chemoresistant CECA cells. These findings demonstrate that (a) p53 and Oma1 mediate L-Opa1 processing, (b) mitochondrial fragmentation is involved in CDDP-induced apoptosis in OVCA and CECA cells, and (c) dysregulated mitochondrial dynamics may in part be involved in the pathophysiology of CDDP resistance.