Identification and purification of the reconstitutively active glutamine carrier from rat kidney mitochondria

The glutamine carrier from rat kidney mitochondria, solubilized in dodecyl octaoxyethylene ether (C12E8) and partly purified on hydroxyapatite, was identified and completely purified by Celite chromatography. On SDS/PAGE, the purified glutamine carrier consisted of a single protein band with an apparent molecular mass of 41.5 kDa. When reconstituted into liposomes, the glutamine carrier catalysed both the unidirectional flux of glutamine and the glutamine/glutamine countertransport, which were completely inhibitable by a mixture of pyridoxal 5´-phosphate and N-ethylmaleimide. The carrier protein was purified 474-fold with a recovery of 58% and a protein yield of 0.12% with respect to the mitochondrial extract. The glutamine carrier-mediated transport is quite specific for l-glutamine. l-Asparagine is the only other amino acid that is efficiently transported by the reconstituted carrier protein. d-Glutamine, l-glutamate and l-aspartate are very poor substrates. The transport activity was inhibited by several thiol-group and amino-group reagents.

Uridine insertion into preedited mRNA by a mitochondrial extract from Leishmania tarentolae: stereochemical evidence for the enzyme cascade model.

An RNA editing-like internal uridine (U) incorporation activity (G. C. Frech, N. Bakalara, L Simpson, and A. M. Simpson, EMBO J. 14:178-187, 1995) and a 3'-terminal U addition activity (N. Bakalara, A. M. Simpson, and L. Simpson, J. Biol. Chem. 264:18679-18686, 1989) have been previously described by using a mitochondrial extract from Leishmania tarentolae. Chiral phosphorothioates were used to investigate the stereoconfiguration requirements and the stereochemical course of these nucleotidyl transfer reactions. The extract utilizes (SP)-alpha-S-UTP for both 3' and internal U incorporation into substrate RNA. The internal as well as the 3' incorporation of (SP)-alpha-S-UTP proceeds via inversion of the stereoconfiguration. Furthermore, internal U incorporation does not occur at sites containing thiophosphodiesters of the RP configuration. Our results are compatible with an enzyme cascade model for this in vitro U insertion activity involving sequential endonuclease and uridylyl transferase directly from UTP and RNA ligase steps and are incompatible with models involving the transfer of U residues from the 3' ends of guide RNAs.

Guide RNA-mRNA chimeras, which are potential RNA editing intermediates, are formed by endonuclease and RNA ligase in a trypanosome mitochondrial extract.

RNA editing in kinetoplast mitochondrial transcripts involves the insertion and/or deletion of uridine residues and is directed by guide RNAs (gRNAs). It is thought to occur through a chimeric intermediate in which the 3' oligo(U) tail of the gRNA is covalently joined to the 3' portion of the mRNA at the site being edited. Chimeras have been proposed to be formed by a transesterification reaction but could also be formed by the known mitochondrial site-specific nuclease and RNA ligase. To distinguish between these models, we studied chimera formation in vitro directed by a trypanosome mitochondrial extract. This reaction was found to occur in two steps. First, the mRNA is cleaved in the 3' portion of the editing domain, and then the 3' fragment derived from this cleavage is ligated to the gRNA. The isolated mRNA 3' cleavage product is a more efficient substrate for chimera formation than is the intact mRNA, inconsistent with a transesterification mechanism but supporting a nuclease-ligase mechanism. Also, when normal mRNA cleavage is inhibited by the presence of a phosphorothioate, normal chimera formation no longer occurs. Rather, this phosphorothioate induces both cleavage and chimera formation at a novel site within the editing domain. Finally, levels of chimera-forming activity correlate with levels of mitochondrial RNA ligase activity when reactions are conducted under conditions which inhibit the ligase, including the lack of ATP containing a cleavable alpha-beta bond. These data show that chimera formation in the mitochondrial extract occurs by a nuclease-ligase mechanism rather than by transesterification.

Accurate transcription of a plant mitochondrial gene in vitro

To investigate transcriptional mechanisms in plant mitochondria, we have developed an accurate and efficient in vitro transcription system consisting of a partially purified wheat mitochondrial extract programmed with cloned DNA templates containing the promoter for the wheat mitochondrial cytochrome oxidase subunit II gene (coxII). Using this system, we localize the coxII promoter to a 372-bp region spanning positions -56 to -427 relative to the coxII translation initiation codon. We show that in vitro transcription of coxII is initiated at position -170, precisely the same site at which transcription is initiated in vivo. Transcription begins within the sequence GTATAGTAAGTA (the initiating nucleotide is underlined), which is similar to the consensus yeast mitochondrial promoter motif, (A/T)TATAAGTA. This is the first in vitro system that faithfully reproduces in vivo transcription of a plant mitochondrial gene.