Gibberellin regulates mitochondrial pyruvate dehydrogenase activity in rice

Pyruvate dehydrogenase kinase (PDK) is a negative regulator of the mitochondrial pyruvate dehydrogenase complex (mtPDC) that plays a key role in intermediary metabolism. OsPDK1 was identified as a gibberellin-up-regulated gene using a cDNA microarray. The full-length cDNA for OsPDK1 was 1498 bp and encoded a predicted polypeptide of 363 amino acids. Genomic DNA analysis showed the presence of another isoform of PDK, OsPDK2, in rice. Reverse transcriptase-PCR analysis revealed differential expression of the two isoforms. OsPDK1 was expressed in leaf blade and leaf sheath but not in callus and root, while OsPDK2 was expressed constitutively in all tissues examined. Maximum expression of OsPDK1 in leaf sheath was detected by Northern blot analysis when seedlings were treated with 5 microM GA3 for 24 h. OsPDK1 expression was up-regulated by GA3, and there was little effect of other plant hormones. Mitochondrial pyruvate dehydrogenase (PDH) activity was reduced compared with control plants in 2-week-old seedlings treated with GA3. The beta-glucuronidase (GUS) reporter gene, driven by a 2,067 bp OsPDK1 promoter region fragment, was mainly expressed in the aleurone layer of germinating seed and leaf sheath. Transgenic rice expressing PDK1 RNAi had altered vegetative growth with reduced accumulation of vegetative tissues. These results suggest that gibberellin modulates the activity of mtPDC by regulating OsPDK1 expression and subsequently controlling plant growth and development.

Mitochondria as a connected population: ensuring continuity of the mitochondrial genome during plant cell dedifferentiation through massive mitochondrial fusion

Mitochondrial fusion in plants and its role in development are poorly understood. Cultured tobacco mesophyll protoplasts provide an excellent experimental system for visualizing mitochondrial dynamics. Before protoplasts first divide, mitochondria undergo a phase of extensive elongation before fission causes an increase in number, followed by actin filament (AF)-dependent dispersion that distributes mitochondria uniformly throughout the cytoplasm. Here, by fusing protoplasts containing either green fluorescent protein- or MitoTracker-labelled mitochondria, we show that elongation results from fusion during early (4-8 h) protoplast culture. This massive mitochondrial fusion (MMF) leads to near-complete mixing of the mitochondrial population within 24 h. Staining isolated mitochondria with 4',6-diamidino-2-phenylindole (DAPI) revealed that in freshly prepared protoplasts mitochondrial nucleoids were unequally distributed, with many mitochondria failing to stain with DAPI, suggesting the presence of an incomplete mitochondrial genome. Following MMF, nucleoids were distributed evenly throughout the population, thereby ensuring continuity of the mitochondrial genome in daughter cells. Massive mitochondrial fusion appears to be specific to dedifferentiation, since it also occurs in mesophyll protoplasts of Arabidopsis and Medicago but not in protoplasts from already dedifferentiated cells such as BY-2 or callus cultures. Efficient MMF requires an inner membrane electrical gradient, cytoplasmic protein synthesis, microtubules and functional kinesin but not ATP or AFs, indicating fundamental differences from mitochondrial fusion in non-plant systems. Our studies reveal that individual mitochondria are connected over time by fusion events, a finding that allows a clearer interpretation of how novel mitochondrial genotypes develop following cell fusion, and indicates that developmentally regulated fusion ensures continuity of the mitochondrial genome.

Molecular analysis of two pyruvate dehydrogenase kinases from maize

Two maize cDNAs were isolated and sequenced that had open reading frames with approximately 37% amino acid identity to mammalian pyruvate dehydrogenase kinases. Both maize kinase sequences contain the five domains with conserved signature residues typical of procaryotic two-component histidine kinases. Sequence comparisons identified six other highly conserved motifs that are proposed to be specific to pyruvate dehydrogenase kinases. In addition, specific Trp and Cys residues are also invariant in these sequences. The maize cDNAs are 1332 (PDK1) and 1602 (PDK2) nucleotides in length, encoding polypeptides with calculated molecular masses of 38,867 and 41,327 Da that share 77% amino acid identity. Reverse transcriptase-polymerase chain reaction analysis with oligonucleotide-specific primers revealed a differential expression pattern for the two isoforms. PDK1 and PDK2 were expressed in Escherichia coli with N-terminal His6 tags to facilitate purification. The recombinant proteins migrated at 44 and 48 kDa, respectively, during SDS-polyacrylamide gel electrophoresis. Anti-PDK1 antibodies immunoprecipitated 75% of pyruvate dehydrogenase kinase activity from a maize mitochondrial matrix fraction, and recognized a matrix protein of 43 kDa. Recombinant PDK2, expressed as a fusion with the maltose-binding protein, inactivated kinase-depleted maize pyruvate dehydrogenase complex when incubated with MgATP, coincident with incorporation of 32P from [gamma-32P]ATP into the alpha subunit of pyruvate dehydrogenase.

A single gene of chloroplast origin codes for mitochondrial and chloroplastic methionyl-tRNA synthetase in Arabidopsis thaliana

One-fifth of the tRNAs used in plant mitochondrial translation is coded for by chloroplast-derived tRNA genes. To understand how aminoacyl-tRNA synthetases have adapted to the presence of these tRNAs in mitochondria, we have cloned an Arabidopsis thaliana cDNA coding for a methionyl-tRNA synthetase. This enzyme was chosen because chloroplast-like elongator tRNAMet genes have been described in several plant species, including A. thaliana. We demonstrate here that the isolated cDNA codes for both the chloroplastic and the mitochondrial methionyl-tRNA synthetase (MetRS). The protein is transported into isolated chloroplasts and mitochondria and is processed to its mature form in both organelles. Transient expression assays using the green fluorescent protein demonstrated that the N-terminal region of the MetRS is sufficient to address the protein to both chloroplasts and mitochondria. Moreover, characterization of MetRS activities from mitochondria and chloroplasts of pea showed that only one MetRS activity exists in each organelle and that both are indistinguishable by their behavior on ion exchange and hydrophobic chromatographies. The high degree of sequence similarity between A. thaliana and Synechocystis MetRS strongly suggests that the A. thaliana MetRS gene described here is of chloroplast origin.

Developmental regulation of the plant mitochondrial matrix located HSP70 chaperone and its role in protein import

Changes in the level of the mitochondrial chaperone mtHSP70 have been investigated in pea (Pisum sativum) leaf mitochondria by Western blot analysis and quantified by scanning densitometry. As pea leaves develop (from 6 days to 30 days of age) the levels of mtHSP70 decrease. Analysis of the levels of the alpha subunit of the F1ATPase show that the levels of this protein remain constant throughout the same developmental period, whereas the levels of the alternative oxidase increase. In vitro import of the alternative oxidase precursor protein into pea leaf mitochondria from day 6 to day 30 leaves and quantification by scanning densitometry indicates that protein import efficiency decreases with increasing maturity of the plant cell. Results are discussed in terms of how changing levels of the mtHSP70 chaperone, as a result of plant cell development, influence the efficiency of protein import.

Temporal regulation of in vitro import of precursor proteins into tobacco mitochondria

Protein import into isolated tobacco mitochondria was investigated using mitochondria from leaves harvested at different times of the day and night. Efficient import was only detected with mitochondria isolated from leaves harvested during the dark period of the growth cycle, only low levels of import were detected from leaves harvested during the light period. However, this temporal difference seen in import did not appear to be circadian in nature. This implies that the protein import process in mitochondria isolated from leaves is not constitutive. This has important implications for targeting specificity studies performed in transgenic plants, as unless the plants are tested at the time when import is occurring, the true in vivo targeting abilities of chimeric constructs will not be measured.

Different in vitro and in vivo targeting properties of the transit peptide of a chloroplast envelope inner membrane protein

The triose phosphate 3-phosphoglycerate phosphate translocator (TPT) is a chloroplast envelope inner membrane protein whose transit peptide has structural properties typical of a mitochondrial presequence. To study the TPT transit peptide in more detail, we constructed two chimeric genes encompassing the TPT transit peptide and either 5 or 23 amino-terminal residues of the mature TPT, both linked to the reporter chloramphenicol acetyltransferase (cat) gene. The precursors were synthesized in vitro and translocated to and processed in purified plant mitochondria. However, this import was not specific since both precursors were also imported into isolated chloroplasts. To extend this analysis in vivo, the chimeric genes were introduced into tobacco by genetic transformation. Analysis of CAT distribution in subcellular fractions of transgenic plants did not confirm the data obtained in vitro. With the construct retaining only 5 residues of the mature TPT, CAT was found in the cytosolic fraction. Extension of the TPT transit peptide to 23 residues of the mature TPT allowed specific import and processing of CAT into chloroplasts. These results indicate that, despite its unusual structure, the TPT transit peptide is able to target a passenger protein specifically into chloroplasts, provided that NH2-terminal residues of the mature TPT are still present. The discrepancy between the in vitro and in vivo data suggests that the translocation machinery is more stringent in the latter case and that sorting of proteins might not be addressed adequately by in vitro experiments.

Cloning of a cDNA that encodes farnesyl diphosphate synthase and the blue-light-induced expression of the corresponding gene in the leaves of rice plants

A cDNA encoding farnesyl diphosphate synthase (FPPS), a key enzyme in isoprenoid biosynthesis, was isolated from a cDNA library constructed from mRNA that had been prepared from etiolated rice (Oriza sativa L. variety Nipponbare) seedlings after three hours of illumination by a subtraction method. The putative polypeptide deduced from the 1289 bp nucleotide sequence consisted of 353 amino acids and had a molecular mass of 40 676 Da. The predicted amino acid sequence exhibited high homology to those of FPPS from Arabidopsis (73% to type 1, 72% to type 2) and white lupin (74%). Southern blot analysis showed that the rice genome might contain only one gene for FPPS. The highest level of expression of the gene was demonstrated in leaves by RNA blot analysis. Moreover, light, in particular blue light, effectively enhanced expression of the gene.

Transport of proteins in eukaryotic cells: more questions ahead

Some newly synthesized proteins contain signals that direct their transport to their final location within or outside of the cell. Targeting signals are recognized by specific protein receptors located either in the cytoplasm or in the membrane of the target organelle. Specific membrane protein complexes are involved in insertion and translocation of polypeptides across the membranes. Often, additional targeting signals are required for a polypeptide to be further transported to its site of function. In this review, we will describe the trafficking of proteins to various cellular organelles (nucleus, chloroplasts, mitochondria, peroxisomes) with emphasis on transport to and through the secretory pathway.

Isolation and characterization of the mitochondrial ATP synthase from Chlamydomonas reinhardtii. cDNA sequence and deduced protein sequence of the alpha subunit

We have isolated the F0F1-ATP synthase complex from oligomycin-sensitive mitochondria of the green alga Chlamydomonas reinhardtii. A pure and active ATP synthase was obtained by means of sonication, extraction with dodecyl maltoside and ion exchange and gel permeation chromatography in the presence of glycerol, DTT, ATP and PMSF [corrected]. The enzyme consists of 14 subunits as judged by SDS-PAGE. A cDNA clone encoding the ATP synthase alpha subunit has been sequenced. The deduced protein sequence contains a presequence of 45 amino acids which is not present in the mature protein. The mature protein is 58-70% identical to corresponding mitochondrial proteins from other organisms. In contrast to the ATP synthase beta subunit from C. reinhardtii (Franzen and Falk, Plant Mol Biol 19 (1992) 771-780), the protein does not have a C-terminal extension. However, the N-terminal domain of the mature protein is 15-18 residues longer than in ATP synthase alpha subunits from other organisms. Southern blot analysis indicates that the protein is encoded by a single-copy gene.

Isolation and characterization of a cDNA encoding a pea ornithine transcarbamoylase (argF) and comparison with other transcarbamoylases

We used a PCR-based library screening method to isolate a 1.4 kb pea leaf cDNA encoding ornithine transcarbamoylase (OTCase). The cDNA contains a single major ORF of 375 amino acids whose deduced sequence exhibits a high degree of homology with other OTCases. The predicted molecular mass of 41361 Da for this protein is approximately the 40 kDa size of the polypeptide that is immunoprecipitated with OTCase antibody after in vitro translation of pea leaf mRNA. In vivo, OTCase occurs as a trimer of identical 36.5 kDa polypeptides, suggesting that this enzyme is synthesized as a cytosolic precursor protein. Southern blot analysis indicates that multiple OTCase genes occur in pea. An abundant 1.4 kb transcript is seen in northern blots of total RNA isolated from the leaves and roots of light- and dark-grown pea seedlings.

Targeting the plant alternative oxidase protein to Schizosaccharomyces pombe mitochondria confers cyanide-insensitive respiration

The Sauromatum guttatum alternative oxidase has been expressed in Schizosaccharomyces pombe under the control of the thiamine-repressible nmt1 promoter. Alternative oxidase protein and activity were detected both in spheroplasts and isolated mitochondria, indicating that the enzyme is expressed in a functional form and confers cyanide-resistant respiration to S. pombe, which is sensitive to inhibition by octyl-gallate. Protein import studies revealed that the precursor form of the alternative oxidase protein is efficiently imported into isolated mitochondria and processed to its mature form comparable to that observed with potato mitochondria. Western blot analysis and respiratory studies revealed that the alternative oxidase protein is expressed in the inner mitochondrial membrane in its reduced (active) form. Treatment of mitochondria with diamide and dithiothreitol resulted in interconversion of the reduced and oxidized species and modulation of respiratory activity. The addition of pyruvate did not effect either the respiratory rate or expression of the reduced species of the protein. To our knowledge this is the first time that the alternative oxidase has been effectively targeted to and integrated into the inner mitochondrial membrane of S. pombe, and we conclude that the expression of a single polypeptide is sufficient for alternative oxidase activity.

Functional analysis of a recently originating, atypical presequence: mitochondrial import and processing of GUS fusion proteins in transgenic tobacco and yeast

A gene family of at least five members encodes the tobacco mitochondrial Rieske Fe-S protein (RISP). To determine whether all five RISPs are translocated to mitochondria, fusion proteins containing the putative presequences of tobacco RISPs and Escherichia coli beta-glucuronidase (GUS) were expressed in transgenic tobacco, and the resultant GUS proteins were localized by cell fractionation. The amino-terminal 75 and 71 residues of RISP2 and RISP3, respectively, directed GUS import into mitochondria, where fusion protein processing occurred. The amino-terminal sequence of RISP4, which contains an atypical mitochondrial presequence, can translocate the GUS protein specifically into tobacco mitochondria with apparently low efficiency. Consistent with the proposal of a conserved mechanism for protein import in plants and fungi, the tobacco RISP3 and RISP4 presequences can direct import and processing of a GUS fusion protein in yeast mitochondria. Plant presequences, however, direct mitochondrial import in yeast less efficiently than the yeast presequence, indicating subtle differences between the plant and yeast mitochondrial import machineries. Our studies show that import of RISP4 may not require positively charged amino acid residues and an amphipathic secondary structure; however, these structural properties may improve the efficiency of mitochondrial import.