Two overlapping genes in bovine mitochondrial DNA encode membrane components of ATP synthase.

Two hydrophobic proteins have been purified to homogeneity from a mixture of about 13 proteins that are extracted from bovine mitochondria with a chloroform:methanol mixture. Sequence analysis shows that the smaller is a protein of 66 amino acids and is the product of a mitochondrial gene, A6L. The larger, a protein of 226 amino acids, is ATPase-6, a membrane component of ATP synthase, also encoded in mitochondrial DNA. The protein sequences determined establish that the genes for the two proteins overlap by 40 bases and indicate that translation of the second gene, ATPase-6, is initiated within the coding region of A6L. The A6L and the ATPase-6 proteins have also been isolated from the ATP synthase complex and so appear to be bona fide components of the enzyme. The function of A6L is unknown. However, weak structural homology suggests a functional similarity to the yeast mitochondrial protein, aapI, which is required for assembly of the fungal ATP synthase complex. Homologies between ATPase-6 and subunit a of the Escherichia coli ATP synthase complex indicate that the ATPase-6 protein has a similar role in the mitochondrial complex to its bacterial counterpart, being essential for the formation of an active proton channel.     

Two bovine genes for mitochondrial ADP/ATP translocase expressed differences in various tissues

Two different bovine cDNAs have been characterized that encode closely related homologues of the mitochondrial membrane carrier protein ADP/ATP translocase. One of them codes for the protein that has been characterized previously from bovine heart mitochondria, and the other codes for a protein that differs from it in 33 amino acids out of 297. Including the base substitutions required to bring about these changes in amino acid sequence, the coding regions of the cDNAs differ at 184 positions. In addition, they are extensively diverged in their 3' noncoding sequences, which differ greatly in both length and sequence, and these segments of the cDNAs have been used as hybridization probes to demonstrate that the expression of the two genes giving rise to the two proteins is very different in various bovine tissues. Expression of one gene predominates in heart muscle and that of the other in intestine. Hybridization experiments with digests of genomic DNA have shown the presence of numerous sequences related to the two cDNAs in both the bovine and human genomes. Some of these probably arise from pseudogenes, but three expressed genes have been detected in the human genome. The study of the regulation of the expression of these genes may help to illuminate the basis of tissue-specific human mitochondrial diseases which arise because of defects in mitochondrial enzymes only in the affected tissue and not in other tissues of the same individual.     

Aberrant mitochondrial processing of chimaeric import precursors containing subunits 8 and 9 of yeast mitochondrial ATP synthase

A set of chimaeric precursors which contain the same leader sequences but different passenger proteins has been analyzed for the site of protease cleavage following import into yeast mitochondria. Each precursor comprises the leader of Neurospora crassa subunit 9 of mitochondrial ATP synthase fused to subunit 8 or 9 of the corresponding yeast enzyme. Precursors containing the first five residues of mature N. crassa subunit 9 interposed between the leader and the yeast passenger protein were cleaved at the natural site of the N. crassa subunit 9 precursor. Direct fusions without interposed sequences were cleaved at novel sites. Cleavage occurred between the 3rd and 4th residues of yeast subunit 8, but for yeast subunit 9, cleavage occurred within the leader, 8 residues upstream of the passenger protein.     

Structures of the genes encoding the alpha and beta subunits of the Neurospora crassa mitochondrial ATP synthase.

We have isolated and sequenced cDNA and genomic clones encoding the alpha and beta subunits of the Neurospora crassa ATP synthase. The genes are not linked to each other: atp-1(alpha) maps to either linkage group I or V, and atp-2(beta) lies on linkage group II. The two genes resemble each other in having a large number of introns, five in atp-1 and seven in atp-2, mostly positioned near their 5' ends and varying in length from 60-332 bp. The coding regions of both genes have a high G+C content (59%) and use a low number of codons, 46 (atp-1) and 44 (atp-2), a feature associated with highly expressed genes. Northern-blot analysis shows both genes are expressed at high levels during mycelial growth. Comparison of the exon-intron structures of the beta-subunit-encoding gene with those from human and tobacco showed a similar number of introns, several closely positioned, but no exact conservation in position, size or sequence of introns.     

Two different B-type creatine kinase subunits dimerize in a tissue-specific manner

Brain-type creatine kinase B-CK (EC 2.7.3.2) was purified from several chicken tissues, e.g. cardiac muscle, brain, gizzard and retina. Two major monomeric chicken B-CK subunits, designated Bb (basic) and Ba (acidic), which differ in isoelectric point, were separated by chromatofocusing in the presence of 8 M urea on a MonoP column. The two subunits were shown by peptide mapping, amino acid analysis and partial sequencing, as well as by immunological criteria, to be distinct B-CK polypeptides. The N-terminal sequence of 30 amino acid residues of Bb correspond entirely to data derived from a B-CK c-DNA clone termed H4 [(1986) Nucleic Acids Res. 14, 1449-1463], whereas the N-terminus of the acidic Ba species was blocked. Native dimeric B-CK isoenzymes obtained from these tissues were separated by ion exchange chromatography on a MonoQ column yielding two B-CK dimer populations, type-I and type-II B-CK, varying in relative proportions. Quantitation of the CK activity peak ratios of these two populations revealed the existence of a tissue-specific, post-translational mechanism regulating B-CK dimerization in neural tissues. Tissue-specific dimerization of the two distinct B-CK monomer species may represent a means of specifying the intracellular distribution of the dimeric B-CK subspecies.     

Two streptokinase genes are expressed with different solubility in Escherichia coli W3110

The streptokinase (SK) gene from S. equisimilis H46A (ATCC 12449) was cloned in E. coli W3110 under the control of the tryptophan promoter. The recombinant SK, which represented 15% of total cell protein content, was found in the soluble fraction of disrupted cells. The solubility of this SK notably differed from that of the product of the SK gene from S. equisimilis (ATCC 9542) which had been cloned in E. coli W3110 by using similar expression vector and cell growth conditions, and occurred in the form of inclusion bodies.     

A nuclear gene encoding the beta subunit of the mitochondrial ATP synthase in Nicotiana plumbaginifolia.

The beta subunit of the mitochondrial ATP synthase in Nicotiana plumbaginifolia is encoded by two nuclear genes, atp2-1 and atp2-2, which are both expressed. The complete nucleotide sequence of atp2-1 has been determined. It contains eight introns ranging from 88 to 1453 bp. The last intron contains a putative insertion element (Inp), of 812 bp bordered by 35-bp inverted repeats which share an 11-bp homology with Agrobacterium tumefaciens T-DNA borders. Sequences homologous to Inp are present in multiple copies in the N. plumbaginifolia and the N. tabacum genome but not in more distant species. The atp2-1 encoded polypeptide is highly homologous to beta subunits from other ATP synthases but it contains an extension at the N terminus which is probably involved in mitochondrial targeting. A sequence homology between exon 4 of atp2-1 and exon 1 of the human ras genes suggests a common ancestral origin for these exons.     

Two distinct families of human and bovine interferon-alpha genes are coordinately expressed and encode functional polypeptides.

The classical human interferon-alpha (HuIFN-alpha) gene family is estimated to consist of 15 or more nonallelic members which encode proteins sharing greater than 77% amino acid sequence homology. Low-stringency hybridization with a HuIFN-alpha cDNA probe permitted the isolation of two distinct classes of bovine IFN-alpha genes. The first subfamily (class I) is more closely related to the known HuIFN-alpha genes than to the second subfamily (class II) of bovine IFN-alpha genes. Extensive analysis of the human genome has revealed a HuIFN-alpha gene subfamily corresponding to the class II bovine IFN-alpha genes. The class I human and bovine IFN-alpha genes encode mature IFN polypeptides of 165 to 166 amino acids, whereas the class II IFN-alpha genes encode 172 amino acid proteins. Expression in Escherichia coli of members of both gene subfamilies results in polypeptides having potent antiviral activity. In contrast to previous studies which found no evidence of class II IFN-alpha protein or mRNA expression, we demonstrate that the class I and class II IFN-alpha genes are coordinately induced in response to viral infection.     

Two nuclear life cycle-regulated genes encode interchangeable subunits c of mitochondrial ATP synthase in Podospora anserina

An F(1)F(O) ATP synthase in the inner mitochondrial membrane catalyzes the late steps of ATP production via the process of oxidative phosphorylation. A small protein subunit (subunit c or ATP9) of this enzyme shows a substantial genetic diversity, and its gene can be found in both the mitochondrion and/or nucleus. In a representative set of 26 species of fungi for which the genomes have been entirely sequenced, we found five Atp9 gene repartitions. The phylogenetic distribution of nuclear and mitochondrial Atp9 genes suggests that their evolution has included two independent transfers to the nucleus followed by several independent episodes of the loss of the mitochondrial and/or nuclear gene. Interestingly, we found that in Podospora anserina, subunit c is exclusively produced from two nuclear genes (PaAtp9-5 and PaAtp9-7), which display different expression profiles through the life cycle of the fungus. The PaAtp9-5 gene is specifically and strongly expressed in germinating ascospores, whereas PaAtp9-7 is mostly transcribed during sexual reproduction. Consistent with these observations, deletion of PaAtp9-5 is lethal, whereas PaAtp9-7 deletion strongly impairs ascospore production. The P. anserina PaAtp9-5 and PaAtp9-7 genes are therefore nonredundant. By swapping the 5' and 3' flanking regions between genes we demonstrated, however, that the PaAtp9 coding sequences are functionally interchangeable. These findings show that after transfer to the nucleus, the subunit c gene in Podospora became a key target for the modulation of cellular energy metabolism according to the requirements of the life cycle.