Production, in Pichia pastoris, of a recombinant monomeric mapacalcine, a protein with anti-ischemic properties.

Mapacalcine is a small homodimeric protein of 19 kDa with 9 disulfide bridges extracted from the Cliona vastifica sponge (Red Sea). It selectively blocks a calcium current insensitive to most calcium blockers. Specific receptors for mapacalcine have been described in a variety of tissues such as brain, smooth muscle, liver, and kidney. Previous works achieved on hepatocytes and nervous cells demonstrated that this protein selectively blocks a calcium influx triggered by an ischemia/reperfusion (I/R) shock and efficiently protects cells from death after I/R. The aim of this work was to produce the recombinant mapacalcine in the yeast Pichia pastoris. Mass spectrometry, light scattering analysis and biological characterization demonstrated that the recombinant mapacalcine obtained was a monomeric form with 4 disulfide bridges which retains the biological activity of the natural protein.

Cellular localization of isoprenoid biosynthetic enzymes in Marchantia polymorpha. Uncovering a new role of oil bodies.

Like seed plants, liverworts synthesize and accumulate a myriad of isoprenoid compounds. Using antibodies raised against several isoprenoid biosynthetic enzymes, we investigated their intracellular compartmentation by in situ immunolocalization from Marchantia polymorpha. The enzymes examined were deoxy-xylulose phosphate synthase, geranyl diphosphate synthase, farnesyl diphosphate synthase, geranylgeranyl diphosphate synthase, monoterpene synthase, geranylgeranyl diphosphate reductase, phytoene synthase, and phytoene desaturase. Our results show that liverwort oil bodies, which are organelles bound by a single unit membrane, possess isoprenoid biosynthetic enzymes similar to those found in plastids and the cytosol. We postulate that oil bodies play a dynamic role in cell metabolism in addition to their role as sites of essential oil accumulation and sequestration. The occurrence of such enzymes in different cellular compartments might be due to multiple targeting of gene products to various organelles.

Editing status of mat-r transcripts in mitochondria from two plant species: C-to-U changes occur in putative functional RT and maturase domains.

The intronic mat-r ORF encodes a protein with significant homology to retroviral reverse transcriptases. Here, we describe the nucleotide sequence of potato mat-r and study the editing status of mat-r transcripts in two systems, potato and wheat, where the mat-r ORF is part of the trans-introns but in two different configurations relative to nad1 exons d and e. In potato and wheat, 13 and 15 C-to-U transitions respectively were observed. Most transcripts were partially edited, but potato transcripts were edited more efficiently than wheat transcripts. As in functional mitochondrial genes, RNA editing increased the similarity between plant mat-r proteins and their homologous non-plant counterparts. Interestingly, editing of mat-r was clustered in the reverse-transcriptase (RT) and the maturase (X) domains, two well defined regions having known functions in other systems. These results, together with the integrity and sequence conservation of mat-r, strongly suggest that the encoded protein plays a functional role in plant mitochondria.

A reverse transcriptase activity in potato mitochondria.

A reverse transcriptase activity has been detected in potato mitochondria using special RNAs as templates: a bacterial RNA coding for neomycin phosphotransferase (neo pa RNA) and a Neurospora crassa mitochondrial RNA (184 nt RNA). Surprisingly, no exogenous primer addition was required. These RNA templates share a primary and secondary structure similar to the T psi CG loop of tRNAs that could constitute the recognition site for the enzyme. Reverse transcriptase activity was inhibited by ddTTP, ethidium bromide and aphidicolin, while potato mitochondrial DNA polymerase was not inhibited by aphidicolin indicating that these activities correspond to distinct enzymes. A conserved sequence of reverse transcriptases was detected in potato mitochondrial DNA suggesting that this enzyme could be mitochondrially encoded.

RNA editing in wheat mitochondria.

C to U transitions in plant mitochondrial mRNA (RNA editing) lead to amino acid changes as well as to the creation of new initiation or termination codons. We established an in vitro system to assay and to dissect the process of wheat mitochondrial mRNA editing. A deamination mechanism explains most easily the observed C to U transitions. Several fractions of organellar protein participate in the editing machinery. Some of these proteins presumably carry the catalytic activity while others are typical RNA binding proteins and may confer specificity to the 'editosome' complex. To investigate the functional properties of protein products synthesized from unedited mRNAs, we constructed transgenic tobacco plants carrying an unedited gene coding for subunit 9 (ATP9) of the ATP synthase complex. The nuclear encoded 'unedited' protein product is targeted to the mitochondria with a heterologous presequence. A significant number of male sterile tobacco plants were obtained suggesting that at least the functional ATP9 protein requires RNA editing. This result suggests a novel approach to obtain artificial male sterile plants by using a physiological effect resulting in CMS which mimics the situation found in many natural populations.

RNA editing of apocytochrome b (cob) transcripts in mitochondria from two genera of plants.

Editing of the complete coding region of cob transcripts from two genera of plants has been studied by cDNA sequence analysis. Eighteen and nine C residues are edited into U in the mitochondrial transcripts from wheat and potato respectively. Both systems share eight common editing sites; ten codons edited in wheat are "pre-edited" at the genomic level in potato, and one codon edited in potato is "pre-edited" in wheat. Most amino-acid modifications lead to hydrophobic residues and increase the homology between the COB polypeptides and the corresponding protein of other species. In two out of the nine potato cDNA clones, an additional C-to-T modification, which also leads to a change in the encoded amino acid, was identified. Heterogeneity observed at the carboxy-terminus of the COB open reading frame in Triticum aestivum and Triticum timopheevi is not corrected by editing.

An in vitro system for the editing of ATP synthase subunit 9 mRNA using wheat mitochondrial extracts.

A posttranscriptional modification (C-to-U) at specific positions of plant mitochondrial mRNA leads to changes in the amino acid sequence as well as to the emergence of novel initiation or termination sites. This phenomenon, named RNA editing, has been described for several mitochondrial genes from different plant sources. We have found recently that RNA editing of the ATP synthase subunit 9 (atp9) mRNA involves eight changes including the creation of a new stop codon. In this article, we describe an in vitro system devised to follow the editing of wheat mitochondrial atp9 mRNA. Nonedited mRNA was obtained to serve as substrate for this reaction by in vitro transcription of the corresponding gene with T7 RNA polymerase. The source of conversion factor(s) was a soluble fraction obtained from purified wheat mitochondria lysed with salt and detergent. Edited RNA molecules were detected by hybridization with an end-labeled synthetic oligodeoxynucleotide probe complementary to a short region containing four editing events. Optimal conditions for the in vitro RNA editing reaction were determined. The reaction is sensitive to high temperature and protease digestion. Pretreatment with micrococcal nuclease decreased RNA editing activity in the mitochondrial extract, suggesting that a nucleic acid is necessary for the enzymatic reactions. Analysis of the edited mRNA showed that the in vitro reaction led to the same products as those observed in vivo.

RNA editing of wheat mitochondrial ATP synthase subunit 9: direct protein and cDNA sequencing.

RNA editing of subunit 9 of the wheat mitochondrial ATP synthase has been studied by cDNA and protein sequence analysis. Most of the cDNA clones sequenced (95%) showed that editing by C-to-U transitions occurred at eight positions in the coding region. Consequently, 5 amino acids were changed in the protein when compared with the sequence predicted from the gene. Two edited codons gave no changes (silent editing). One of the C-to-U transitions generated a stop codon by modifying the arginine codon CGA to UGA. Thus, the protein produced is 6 amino acids shorter than that deduced from the genomic sequence. Minor forms of cDNA with partial or overedited sequences were also found. Protein sequence and amino acid composition analyses confirmed the results obtained by cDNA sequencing and showed that the major form of edited atp9 mRNA is translated.

Direct protein sequencing of wheat mitochondrial ATP synthase subunit 9 confirms RNA editing in plants.

RNA editing, a process that results in the production of RNA molecules having a nucleotide sequence different from that of the initial DNA template, has been demonstrated in several organisms using different biochemical pathways. Very recently RNA editing was described in plant mitochondria following the discovery that the sequence of certain wheat and Oenothera cDNAs is different from the nucleotide sequence of the corresponding genes. The main conversion observed was C to U, leading to amino acid changes in the deduced protein sequence when these modifications occurred in an open reading frame. In this communication we show the first attempt to isolate and sequence a protein encoded by a plant mitochondrial gene. Subunit 9 of the wheat mitochondrial ATP synthase complex was purified to apparent homogeneity and the sequence of the first 32 amino acid residues was determined. We have observed that at position 7 leucine was obtained by protein sequencing, instead of the serine predicted from the previously determined genomic sequence. Also we found phenylalanine at position 28 instead of a leucine residue. Both amino acid conversions, UCA (serine) to UUA (leucine) and CUC (leucine) to UUC (phenylalanine), imply a C to U change. Thus our results seem to confirm, at the protein level, the RNA editing process in plant mitochondria.

[Supplementary concepts in the physiopathology of the vitreous]. / Adaosuri conceptuale în fiziopathologia vitrosului.

The normal vitreous defends the posterior pole damping the traumatic and tension shocks coming from the anterior pole reducing their intensity according to formula P = F/S The buffering function decreases in direct proportion to the degree of fluidity of the vitreous, fluidity that enlarges the volume of the vitreous whereas the mass does not change according to the density formula p = m/v, the density of the liquefied vitreous being greatly diminished. The liquefied vitreous may lead to degenerative lesions of the retina due to prolonged tension of the retina resulting in ruptures and detachment. An anterior pole pressure of 15-16 mmHg transmitted non-modified to the posterior pole through the liquefied vitreous, exceeding by far the pressure of the opticoretinal tissular fluid pressure which in 9 mmHg leads to papillary excavation and glaucoma without tension; hence the liquefied vitreous must be replaced by a normal one or its density built up again.