Biochemical and immunochemical evidences for the presence of lipoxygenase in plant mitochondria

In this paper, both biochemical and immunochemical evidence for the presence of lipoxygenase (LOX) in plant mitochondria is presented. Highly purified pea (Pisum sativum L., cv. Alaska) mitochondria show LOX activity, evaluated as conjugated diene formation, oxygen consumption, and hydroperoxide formation. Both 9- and 13-hydroperoxy-octadecadienoic acids are produced by the oxidation of linoleic acid. LOX activity is particularly evident in swollen mitochondria; it is inhibited by nordihydroguaiaretic acid, a pea anti-LOX B antibody, and has two pH optima (6.0 and 7.5). A mitochondrial protein of approximately 97 kDa cross-reacts with a pea seed anti-LOX B antibody. This reaction is detectable in both soluble (matrix fraction) and membrane-bound (submitochondrial particles) proteins. Considering that pea mitochondria were extracted from actively growing stems that were differentiating tube elements, it is suggested that the presence of LOX in these organelles may be related to their degradation linked to xylem differentiation.     

Dual intracellular localization and targeting of aminoimidazole ribonucleotide synthetase in cowpea

De novo purine biosynthesis is localized to both mitochondria and plastids isolated from Bradyrhizobium sp.-infected cells of cowpea (Vigna unguiculata L. Walp) nodules, but several of the pathway enzymes, including aminoimidazole ribonucleotide synthetase (AIRS [EC 6.3.3.1], encoded by Vupur5), are encoded by single genes. Immunolocalization confirmed the presence of AIRS protein in both organelles. Enzymatically active AIRS was purified separately from nodule mitochondria and plastids. N-terminal sequencing showed that these two isoforms matched the Vupur5 cDNA sequence but were processed at different sites following import; the mitochondrial isoform was five amino acids longer than the plastid isoform. Electrospray tandem mass spectrometry of a trypsin digest of mitochondrial AIRS identified two internal peptides identical with the amino acid sequence deduced from Vupur5 cDNA. Western blots of proteins from mitochondria and plastids isolated from root tips showed a single AIRS protein present at low levels in both organelles. (35)S-AIRS protein translated from a Vupur5 cDNA was imported into isolated pea (Pisum sativum) leaf chloroplasts in vitro by an ATP-dependent process but not into import-competent mitochondria from several plant and non-plant sources. Components of the mature protein are likely to be important for import because the N-terminal targeting sequence was unable to target green fluorescent protein to either chloroplasts or mitochondria in Arabidopsis leaves. The data confirm localization of the protein translated from the AIRS gene in cowpea to both plastids and mitochondria and that it is cotargeted to both organelles, but the mechanism underlying import into mitochondria has features that are yet to be identified.     

Purification of a serine and histidine phosphorylated mitochondrial nucleoside diphosphate kinase from Pisum sativum.

For the first time, to our knowledge, a nucleoside diphosphate kinase (NDPK) has been purified from plant mitochondria (Pisum sativum L.). In intact pea leaf mitochondria, a 17.4-kDa soluble protein was phosphorylated in the presence of EDTA when [gamma-32P]ATP was used as the phosphate donor. Cell fractionation demonstrated that the 17.4-kDa protein is a true mitochondrial protein, and the lack of accessibility to EDTA of the matrix compartment in intact mitochondria suggested it may have an intermembrane space localization. The 17.4-kDa protein was purified from mitochondrial soluble proteins using ATP-agarose and anion exchange chromatography. Amino-acid sequencing of two peptides, resulting from a trypsin digestion, revealed high similarity with the conserved catalytic phosphohistidine site and with the C-terminal of NDPKs. Acid and alkali treatments of [32P]-labelled pea mitochondrial NDPK indicated the presence of acid-stable as well as alkali-stable phosphogroups. Thin-layer chromatography experiments revealed serine as the acid-stable phosphogroup. The alkali-stable labelling probably reflects phosphorylation of the conserved catalytic histidine residue. In phosphorylation experiments, the purified pea mitochondrial NDPK was labelled more heavily on serine than histidine residues. Furthermore, kinetic studies showed a faster phosphorylation rate for serine compared to histidine. Both ATP and GTP could be used as phosphate donor for histidine as well as serine labelling of the pea mitochondrial NDPK.     

The beta-subunit of pea stem mitochondrial ATP synthase exhibits PPiase activity

A soluble protein with a molecular mass of 55 kDa has been purified from etiolated pea stem mitochondria. The protein exhibits a Mg2+-requiring PPiase activity, with an optimum at pH 9.0, which is not stimulated by monovalent cations, but inhibited by F-, Ca2+, aminomethylenediphosphate and imidodiphosphate. The protein does not cross-react with polyclonal antibodies raised against vacuolar, mitochondrial or soluble PPiases, respectively. Conversely, it cross-reacts with an antibody for the alpha/beta-subunit of the ATP synthase from beef heart mitochondria. The purified protein has been analyzed by MALDI-TOF mass spectrometry and the results, covering the 30% of assigned sequence, indicate that it corresponds to the beta-subunit of the ATP synthase of pea mitochondria. It is suggested that this enzymatic protein may perform a dual function as soluble PPiase or as subunit of the more complex ATP synthase.     

Peroxisomal manganese superoxide dismutase: Purification and properties of the isozyme from pea leaves

The peroxisomal manganese superoxide dismutase (perMn‐SOD; EC 1.15.1.1) was purified to homogeneity for the first time from peroxisomes of pea ( Pisum sativum L.) leaves. Peroxisomes were isolated from pea leaves by sucrose density‐gradient centrifugation, and then perMn‐SOD was purified from these organelles by two purification steps involving anion‐exchange and gel‐filtration fast protein liquid chromatography. Pure peroxisomal Mn‐SOD had a specific activity of 2 880 units per mg protein and was purified 3 000‐fold, with a yield of about 7 µg enzyme per kg pea leaves. The relative molecular mass determined for perMn‐SOD was 92 000, and it was composed of four equal subunits of 27 kDa. Ultraviolet and visible absorption spectra of the enzyme showed two absorption maxima at 278 and 483 nm, respectively, and two shoulders at 290 and 542 nm. By isoelectric focusing (pH 5‐7), an isoelectric point of 5.53 was determined for perMn‐SOD. In immunoblot assays, purified Mn‐SOD was recognized by a polyclonal antibody against mitochondrial Mn‐SOD (mitMn‐SOD) from pea leaves. The amino acid sequence of the N‐terminal region of the purified peroxisomal enzyme was determined. A 100% identity was found with the mitMn‐SOD from pea leaves, and high identities were also found with Mn‐SODs from other plant species.     

Stress CSP310 Protein Uncouples Oxidative Phosphorylation Otherwise than Other Plant Uncoupling Proteins Do

The addition of cold shock CSP310 protein to mitochondria isolated from both monocotyledonous (rye, wheat, and maize) and dicotyledonous (pea) plants uncoupled oxidation from phosphorylation. This uncoupling was caused neither by the damage to mitochondrial membranes nor by the activation of alternative cyanide-resistant oxidase. As distinct from the classical plant uncoupling mitochondrial protein (PUMP), CSP310 uncoupling effect was insensitive to BSA. Therefore, we believe that the mechanism of CSP310 action differs from that of known plant uncoupling proteins.     

A survey of the plant mitochondrial proteome in relation to development

To expand the functional analysis of plant mitochondria, we have undertaken the building of the proteome of pea mitochondria purified from leaves (green and etiolated), roots and seeds. In the first stage, we focused our proteomic exploration on the soluble protein complement of the green leaf mitochondria. We used traditional two-dimensional polyacrylamide gel electrophoresis, in combination with size exclusion chromatography as a third dimension, to identify the major proteins and further resolve their macromolecular complexity. The two-dimensional map of soluble proteins of green leaf mitochondria revealed 433 spots (with Coomassie blue staining) and around 73% of the proteins (in mass) were identified using three different approaches: Edman degradation, matrix-assisted laser desorption/ionization mass spectrometry and electrospray ionization tandem mass spectrometry. Quite a lot of the polypeptides were present in multiforms which indicated the presence of isoforms or the occurrence of post-translational modifications. Among these proteins, we uncovered an abundant family that was identified as aldehyde dehydrogenases, representing approximately 7.5% of the soluble proteins. The comparative analysis of soluble mitochondrial proteomes led to the identification of a number of proteins which were specifically present in root or in seed mitochondria, thus revealing the impact of tissue differentiation at the mitochondrial level.     

Identification and localization of multiple forms of serine hydroxymethyltransferase in pea (Pisum sativum) and characterization of a cDNA encoding a mitochondrial isoform.

Serine hydroxymethyltransferase (SHMT) has been purified from the mitochondria of green pea leaves. Activity can be fractionated into two distinct peaks by ion exchange chromatography. While these two forms of the enzyme are immunologically indistinguishable, immunoinhibition experiments show the presence of a distinct non-mitochondrial third form of the enzyme to also be present in green pea leaves. While this mitochondrial form of SHMT is abundant in leaves it is absent from roots, although the two tissues have comparable SHMT activity. An antibody raised to purified mitochondrial SHMT was used to screen a cDNA expression library. The sequence of one of the isolated positive clones contained an open reading frame, which encoded a sequence that matched the amino acid sequence determined from the N terminus of the mature protein. The open reading frame encodes a mature protein of 487 amino acids with a M(r) of 54,000, together with a 27-31 amino acid serine-rich leader sequence, presumably required for mitochondrial targeting. The cDNA hybridizes to a small multigene family of 2-3 genes, which appear to be expressed predominantly in leaves. Comparison of the deduced amino acid sequence with the amino acid sequences of the rabbit mitochondrial and cytoplasmic SHMT, show that pea mitochondrial SHMT is equally similar to both of these enzymes. In addition, the rabbit sequences are more like one another than they are to the pea sequence, suggesting an interesting evolutionary relationship for these proteins.     

Actin in mung bean mitochondria and implications for its function

Here, a large fraction of plant mitochondrial actin was found to be resistant to protease and high-salt treatments, suggesting it was protected by mitochondrial membranes. A portion of this actin became sensitive to protease or high-salt treatment after removal of the mitochondrial outer membrane, indicating that some actin is located inside the mitochondrial outer membrane. The import of an actin-green fluorescent protein (GFP) fusion protein into the mitochondria in a transgenic plant, actin:GFP, was visualized in living cells and demonstrated by flow cytometry and immunoblot analyses. Polymerized actin was found in mitochondria of actin:GFP plants and in mung bean (Vigna radiata). Notably, actin associated with mitochondria purified from early-developing cotyledons during seed germination was sensitive to high-salt and protease treatments. With cotyledon ageing, mitochondrial actin became more resistant to both treatments. The progressive import of actin into cotyledon mitochondria appeared to occur in concert with the conversion of quiescent mitochondria into active forms during seed germination. The binding of actin to mitochondrial DNA (mtDNA) was demonstrated by liquid chromatography-tandem mass spectrometry analysis. Porin and ADP/ATP carrier proteins were also found in mtDNA-protein complexes. Treatment with an actin depolymerization reagent reduced the mitochondrial membrane potential and triggered the release of cytochrome C. The potential function of mitochondrial actin and a possible actin import pathway are discussed.     

Coupling factor activity of the purified pea mitochondrial F1-ATPase

The pea cotyledon mitochondrial F1-ATPase was released from the submitochondrial particles by a washing procedure using 300 mM sucrose/2 mM Tricine (pH 7.4). The enzyme was purified by DEAE-cellulose chromatography and subsequent sucrose density gradient centrifugation. Using polyacrylamide gel electrophoresis under non-denaturing conditions, the purified protein exhibited a single sharp band with slightly lower mobility than the purified pea chloroplast CF1-ATPase. The molecular weights of pea mitochondrial F1-ATPase and pea chloroplast CF1-ATPase were found to be 409 000 and 378 000, respectively. The purified pea mitochondrial F1-ATPase dissociated into six types of subunits on polyacrylamide gel electrophoresis in the presence of sodium dodecyl sulfate. Most of these subunits had mobilities different from the subunits of the pea chloroplast CF1-ATPase. The purified mitochondrial F1-ATPase exhibited coupling factor activity. In spite of the observed differences between CF1 and F1, the mitochondrial enzyme stimulated ATP formation in CF1-depleted pea chloroplast membranes. Thus, the mitochondrial F1 was able to substitute functionally for the chloroplast CF1 in reconstituting photophosphorylation.     

A receptor for protein import into potato mitochondria

Five potential surface receptors for protein import into plant mitochondria were identified by gentle trypsin treatment of intact mitochondria from potato tubers and subsequent preparation of outer mitochondrial membranes. One of them, a 23 kDa protein, was purified to homogeneity and analysed by direct protein sequencing. Copy DNA clones encoding the corresponding polypeptide were isolated with labelled oligonucleotides derived from the amino acid data. The 23 kDa protein shares significant sequence similarity with protein import receptors from fungal mitochondria and contains one of their typical tetratricopeptide motifs. Its integration into the outer membrane is independent of protease accessible surface receptors and not accompanied by proteolytic processing. Monospecific antibodies against the 23 kDa protein significantly reduce import capacity of isolated mitochondria indicating that this component is indeed involved in the recognition or import of precursor proteins. As in fungi, immunological inhibition of protein import with IgGs against a single receptor is incomplete suggesting the existence of other receptors in the outer mitochondrial membrane of plant mitochondria.     

The characterization of a mitochondrial acyl carrier protein isoform isolated from Arabidopsis thaliana.

A cDNA clone was isolated from an Arabidopsis leaf cDNA library that shared a high degree of protein sequence identity with mitochondrial acyl carrier proteins (mtACPs) isolated from Neurospora crassa and bovine heart muscle. The cDNA encoded an 88-amino acid mature protein that was preceded by a putative 35-amino acid presequence. In vitro protein import studies have confirmed that the presequence specifically targets this protein into pea mitochondria but not into chloroplasts. These studies indicated that pea mitochondria were not only able to import and process the precursor protein but also possessed the ability to acylate the mature protein. The mitochondrial localization of this protein, mtACP-1, was confirmed by western blot analysis. Arabidopsis mitochondrial protein extracts contained two cross-reacting bands that comigrated with the mature mtACP-1 and acylated mtACP-1 proteins. The acylated form of mtACP-1 was approximately 4 times more abundant than the unacylated form and appeared to be localized predominantly in the mitochondrial membrane where the unacylated mtACP-1 was present mostly in the matrix fraction. A chloroplast fatty acid synthase system was used, and mtACP-1 was able to function as a cofactor for fatty acid synthesis. However, predominantly short- and medium-chain fatty acids were produced in fatty acid synthase reactions supplemented with mtACP-1, suggesting that mtACP-1 may be causing premature fatty acid chain termination.     

Biochemical characterization of the Arabidopsis biotin synthase reaction. The importance of mitochondria in biotin synthesis.

Biotin synthase, encoded by the bio2 gene in Arabidopsis, catalyzes the final step in the biotin biosynthetic pathway. The development of radiochemical and biological detection methods allowed the first detection and accurate quantification of a plant biotin synthase activity, using protein extracts from bacteria overexpressing the Arabidopsis Bio2 protein. Under optimized conditions, the turnover number of the reaction was >2 h(-1) with this in vitro system. Purified Bio2 protein was not efficient by itself in supporting biotin synthesis. However, heterologous interactions between the plant Bio2 protein and bacterial accessory proteins yielded a functional biotin synthase complex. Biotin synthase in this heterologous system obeyed Michaelis-Menten kinetics with respect to dethiobiotin (K(m) = 30 microM) and exhibited a kinetic cooperativity with respect to S-adenosyl-methionine (Hill coefficient = 1.9; K(0.5) = 39 microM), an obligatory cofactor of the reaction. In vitro inhibition of biotin synthase activity by acidomycin, a structural analog of biotin, showed that biotin synthase reaction was the specific target of this inhibitor of biotin synthesis. It is important that combination experiments using purified Bio2 protein and extracts from pea (Pisum sativum) leaf or potato (Solanum tuberosum) organelles showed that only mitochondrial fractions could elicit biotin formation in the plant-reconstituted system. Our data demonstrated that one or more unidentified factors from mitochondrial matrix (pea and potato) and from mitochondrial membranes (pea), in addition to the Bio2 protein, are obligatory for the conversion of dethiobiotin to biotin, highlighting the importance of mitochondria in plant biotin synthesis.     

Autophosphorylation of the pea mitochondrial heat-shock protein homolog

Highly purified mitochondria isolated from 14-day-old pea (Pisum sativum L., cv Little Marvel) seedlings contain a homolog of the 70,000 molecular weight heat-shock protein. The amount of this heat-shock cognate (Hsc70) was not reduced by limited proteolysis of intact mitochondria or by preparation of mitoplasts, indicating that the protein is located within the matrix compartment. Pea mitochondrial Hsc70 binds to immobilized ATP and reacts on western blots with anti-tomato Hsc70 antiserum. When a mitochondrial matrix fraction was incubated with [γ-³²P]ATP, there was phosphorylation of Hsc70. The extent of phosphorylation was increased by including calcium chloride in the reactions. Phospho amino acid analysis of purified mitochondrial Hsc70, phosphorylated in the calcium-stimulated reaction, revealed only phosphothreonine. Pea mitochondrial Hsc70, purified by a combination of ATP-agarose affinity chromatography and gel permeation chromatography, was labeled when incubated with ATP plus calcium, suggesting autophosphorylation rather than phosphorylation by an associated kinase. In analogy to mammalian cells and yeast, it is likely that mitochondrial Hsc70 acts as a molecular chaperone, and it is possible that phosphorylation plays a role in chaperone function.     

Light-induced increases in the glycine decarboxylase multienzyme complex from pea leaf mitochondria

The rates of mitochondrial glycine oxidation estimated by CO2-release and glycine-bicarbonate exchange activities in fully greened tissues are approximately 10 times greater than those of etiolated pea leaves and potato tuber mitochondria. The release of CO2 from glycine in intact mitochondria isolated from dark-grown and nonphotosynthetic tissues was sensitive to inhibitors of mitochondrial electron transport, glycine transport, and glycine decarboxylase activities. The CO2-release and glycine-bicarbonate exchange activities in crude mitochondrial protein extracts from light-grown versus dark-grown tissues exhibited light/dark ratios of 12 and 21, respectively. This suggests that the differences in capacity to oxidize glycine reside with the glycine decarboxylase enzyme complex itself. The complex is composed of four subunit enzymes, the P, H, T, and L proteins, which can be isolated individually and reconstituted into the active enzyme. The activities of P and T proteins were at least 10 times higher in fully greened pea leaves than in the etiolated tissue, while the H and L protein activities were four times higher in these same tissues. The levels of P and T proteins detected immunochemically were substantially lower in total mitochondrial extracts prepared from leaves of dark-grown pea seedlings. Labeling of whole pea seedlings and in vitro protein synthesis with isolated mitochondria indicated that the entire glycine decarboxylase enzyme complex is cytoplasmically synthesized and therefore encoded by the nucleus. Polypeptides synthesized from total leaf polyadenylated mRNA isolated from leaves of both the dark-grown and light-treated peas indicated the presence of P protein. This implies that translatable messages for this enzyme are present at some level throughout leaf development.     

Relevance of ferritin-binding sites on isolated mitochondria to the mobilization of iron from ferritin

Iron can be released from ferritin and utilized by isolated rat liver mitochondria for the synthesis of heme. Mobilization of iron from ferritin is initiated by the binding of ferritin to the mitochondria in an manner compatible with binding sites or receptors for ferritin on the mitochondria. The binding completes rapidly, it is independent of temperature, saturable, reversible and enhanced by K+ and Mg2+. The amount of ferritin binding sites is approx. 0.8 pmol/mg mitochondrial protein, and the affinity constant is 6.4 . 10(6)M-1. The binding kinetics correlate well with the functional features of the ferritin-mitochondrial interaction: i.e. mobilization of iron from ferritin followed by insertion of the iron into heme. The results support the concept of ferritin as a possible donor of iron to the mitochondria.     

A higher plant mitochondrial homologue of the yeast m-AAA protease. Molecular cloning,localization, and putative function

Mitochondrial AAA metalloproteases play a fundamental role in mitochondrial biogenesis and function. They have been identified in yeast and animals but not yet in plants. This work describes the isolation and sequence analysis of the full-length cDNA from the pea (Pisum sativum) with significant homology to the yeast matrix AAA (m-AAA) protease. The product of this clone was imported into isolated pea mitochondria where it was processed to its mature form (PsFtsH). We have shown that the central region of PsFtsH containing the chaperone domain is exposed to the matrix space. Furthermore, we have demonstrated that the pea protease can complement respiration deficiency in the yta10 and/or yta12 null yeast mutants, indicating that the plant protein can compensate for the loss of at least some of the important m-AAA functions in yeast. Based on biochemical experiments using isolated pea mitochondria, we propose that PsFtsH-like m-AAA is involved in the accumulation of the subunit 9 of the ATP synthase in the mitochondrial membrane.